JP2019194468A - Control valve assembly - Google Patents

Abstract

To provide a control valve assembly capable of selecting a direction and the like of a passage connected with a control valve in an evaporated fuel passage.SOLUTION: A control valve assembly 8 is disposed in an evaporated fuel passage in which an evaporated fuel desorbed from a canister is circulated toward an engine. The control valve assembly 8 includes a housing 40 having an electromagnetic coil portion 42 for driving a valve element 43 to open and close a housing internal passage, and an inflow/outflow member 6 connected with the housing 40. The inflow/outflow member 6 includes an inflow portion 63 provided with an inflow passage in which an evaporated fuel to the housing internal passage is circulated, and outflow portions 61, 62 provided with outflow passages in which an evaporated fuel flowing out from the housing internal passage is circulated. The outflow passages of the outflow portions 61, 62 and the inflow passage of the inflow portion 63 are defined and formed by a partitioning portion 60d to be communicated through the housing internal passage.SELECTED DRAWING: Figure 3

Description

  The disclosure in this specification relates to a control valve assembly provided in an evaporative fuel passage through which evaporative fuel flows toward an engine.

  Patent Document 1 describes that a flow control electromagnetic valve is installed in an evaporative fuel passage extending from a fuel tank to an engine intake pipe via a canister. The electromagnetic valve for flow control includes a first housing that incorporates an electromagnetic drive unit that drives a valve element. The first housing is integrally provided with a fuel inflow pipe extending in a direction orthogonal to the housing axial direction.

Japanese Patent Laying-Open No. 2015-7455

  If it is desired to mount a flow control solenoid valve with a different direction and shape of the fuel inflow pipe in the evaporative fuel passage, a new housing that meets the specifications must be prepared.

  Further, since there are various requirements and specifications on the vehicle side, the types and quantities of parts to be connected to the purge control valve, the shape and direction of the connection port, and the like vary. For this reason, there is a problem that the housing of the purge control valve must be individually designed to meet each specification.

  An object of the disclosure in this specification is to provide a control valve assembly that enables selection of the direction of the passage connected to the control valve in the evaporated fuel passage.

  A plurality of aspects disclosed in this specification adopt different technical means to achieve each purpose. Further, the reference numerals in parentheses described in the claims and in this section are examples showing the correspondence with specific means described in the embodiments described later as one aspect, and limit the technical scope. is not.

One of the disclosed control valve assemblies is a control valve assembly (8; 108; 208; 308) installed in an evaporative fuel passage through which evaporative fuel desorbed from the canister (16) flows towards the engine (22). 408; 508; 608; 708; 808; 908; 1008);
A housing (40) having a built-in electromagnetic coil portion (42) for driving a valve body (43) for opening and closing a passage in the housing;
An inflow portion (63; 163; 406a; 506a; 606a) formed with an inflow passage through which evaporated fuel flows toward the in-housing passage and an outflow portion with an outflow passage through which evaporated fuel flowing out from the in-housing passage (see FIG. 61, 62; 406e), and an inflow member (6; 106; 206; 306; 406; 506; 606; 706; 806) connected to the housing,
The outflow passage in the outflow portion and the inflow passage in the inflow portion are partitioned so as to communicate with each other via the in-housing passage.

  The control valve assembly includes a housing having a built-in electromagnetic coil portion for driving a valve body and an inflow / outflow portion for evaporated fuel, and an inflow / outflow member which is a separate part from the housing. ing. According to this configuration, it is possible to provide a control valve assembly that conforms to the vehicle-side specifications and the like only by preparing an inflow / outflow member in which the orientation of the inflow portion and the outflow portion is changed. As described above, according to this disclosure, it is possible to obtain a control valve assembly that can select the direction of the passage connected to the control valve in the evaporated fuel passage.

It is the schematic which showed the evaporated fuel processing system which can mount the purge control valve of 1st Embodiment. It is the perspective view which showed the control valve assembly of 1st Embodiment. It is sectional drawing which showed the control valve assembly of 1st Embodiment. It is the figure which looked at the intermediate member in the passage axial direction. It is the figure which looked at the member for inflow / outflow in the channel | axis axial direction. It is sectional drawing which showed the control valve assembly of 2nd Embodiment. It is the perspective view which showed the control valve assembly of 3rd Embodiment. It is the perspective view which showed the control valve assembly of 4th Embodiment. It is the perspective view which showed the control valve assembly of 5th Embodiment. It is sectional drawing which showed the control valve assembly of 5th Embodiment. It is the exploded view which showed the control valve assembly of 6th Embodiment. It is the perspective view which showed the control valve assembly of 6th Embodiment. It is the perspective view which showed the control valve assembly of 7th Embodiment. It is the perspective view which showed the control valve assembly of 8th Embodiment. It is the perspective view which showed the control valve assembly of 9th Embodiment. It is sectional drawing which showed the control valve assembly of 9th Embodiment. It is the perspective view which showed the control valve assembly of 10th Embodiment. It is the schematic which showed the evaporated fuel processing system which can mount the purge control valve of 11th Embodiment. It is the perspective view which showed the control valve assembly of 11th Embodiment. It is sectional drawing which showed the control valve assembly of 12th Embodiment. It is sectional drawing which showed the control valve assembly of 13th Embodiment. It is the schematic which showed the evaporated fuel processing system which can mount the purge control valve of 14th Embodiment. It is the perspective view which showed the control valve assembly of 14th Embodiment.

  Hereinafter, a plurality of modes for carrying out the present disclosure will be described with reference to the drawings. In each embodiment, parts corresponding to the matters described in the preceding embodiment may be denoted by the same reference numerals, and redundant description may be omitted. When only a part of the configuration is described in each mode, the other modes described above can be applied to the other parts of the configuration. Not only combinations of parts that clearly show that combinations are possible in each embodiment, but also combinations of the embodiments even if they are not specified, unless there is a particular problem with the combination. Is also possible.

(First embodiment)
A first embodiment will be described with reference to FIGS. The evaporative fuel processing system shown in FIG. 1 supplies HC gas or the like in the fuel adsorbed by the canister 16 to the intake passage of the engine 22 and prevents the evaporative fuel from the fuel tank 14 from being released into the atmosphere. It is also a system to do. This evaporative fuel processing system includes a control valve assembly 8 that connects various components that form an evaporative fuel passage. The control valve assembly 8 has at least a purge control valve 4. Various components include functional parts such as a check valve, pipes forming a passage, joints, lid members, and other passage wall members installed in the evaporated fuel passage. The control valve assembly 8 includes at least a housing 40 constituting the purge control valve 4, an intermediate member 41 coupled to the housing 40, and an inflow / outflow member 6 coupled to the intermediate member 41. Each of the housing 40, the intermediate member 41, and the inflow / outflow member 6 is made of resin.

  The evaporated fuel introduced into the intake system 1 of the engine 22 is mixed with combustion fuel supplied to the engine 22 from an injector or the like and burned in a cylinder of the engine 22. In the intake system 1 of the engine 22, one end side of the intake pipe 10 is connected to an intake manifold 20 of the engine 22 via a throttle valve 21, and a filter 13, a supercharger 12, an intercooler 11, and the like are further provided in the intake pipe 10. It is provided and configured. The evaporative fuel purge system 2 is formed by connecting a fuel tank 14 and a canister 16 to an intake manifold 20 via a pipe 15, a pipe 17, a relay pipe 19 and a pipe 18.

  The filter 13 is provided at the most upstream part of the intake pipe 10 and captures dust, dust, and the like in the intake air. The supercharger 12 is composed of an intake compressor for increasing intake charging efficiency, and is provided on the intake manifold 20 side, which is downstream of the filter 13. The supercharger 12 includes a compressor that is linked to a turbine that is operated by the exhaust energy of the engine 22. The compressor of the supercharger 12 pressurizes the intake air that has passed through the filter 13 and supplies it to the intake manifold 20.

  The intercooler 11 is a heat exchanger for cooling. The intercooler 11 is provided downstream of the supercharger 12. In the intercooler 11, heat exchange is performed between the intake air pressurized by the supercharger 12 and the outside air to cool the intake air. The throttle valve 21 is an intake air amount adjustment valve that adjusts the amount of intake air flowing into the intake manifold 20 by adjusting the opening at the inlet of the intake manifold 20 in conjunction with the accelerator pedal. The intake air sequentially passes through the filter 13, the supercharger 12, the intercooler 11, and the throttle valve 21, flows into the intake manifold 20, and is mixed with the combustion fuel injected from the injector or the like so as to have a predetermined air-fuel ratio. And burned in the cylinder.

  The fuel tank 14 is a container for storing fuel such as gasoline. The fuel tank 14 is connected to the inflow portion 16 a of the canister 16 by a pipe 15. The canister 16 is a container in which an adsorbent such as activated carbon is enclosed. The canister 16 takes in evaporated fuel generated in the fuel tank 14 from the inflow portion 16a via the pipe 15 and temporarily adsorbs the adsorbent on the adsorbent. The canister 16 is provided with a suction portion 16b for sucking fresh fresh air. By providing the canister 16 with the suction portion 16 b, atmospheric pressure acts in the canister 16. The canister 16 can easily remove the evaporated fuel adsorbed on the adsorbent by the freshly sucked air.

  For example, a valve module is integrally provided in the suction portion 16b. The valve module incorporates a canister close valve that opens and closes the intake section for inhaling fresh outside air, and an internal pump that can release gas to the atmosphere and inhale the atmosphere is doing. When the canister 16 includes the canister close valve, atmospheric pressure can be applied to the canister 16. The canister 16 can easily desorb, that is, purge, the evaporated fuel adsorbed on the adsorbent by the freshly sucked air.

  The canister 16 is provided with an outflow portion 16c through which the evaporated fuel separated from the adsorbent flows out. One end side of the pipe 17 is connected to the outflow part 16c. The other end side of the pipe 17 is connected to the inflow portion of the purge control valve 4. Here, the passage in the pipe 17 is also referred to as a fuel inflow passage through which fuel flows into the purge control valve 4. The purge control valve 4 and the first check valve device 3 communicate with each other by a configuration connected by a relay pipe 19. The outflow side of the first check valve device 3 is connected to one end side of the pipe 18. Here, the passage in the pipe 18 is also referred to as a fuel outflow passage through which the fuel flowing out from the purge control valve 4 passes. The other end side of the pipe 18 is connected to the inflow portion of the intake manifold 20.

  The purge control valve 4 is an opening / closing means for opening and closing the evaporated fuel passage, and can permit and block the supply of the evaporated fuel flowing out from the canister 16 to the engine 22. As shown in FIG. 3, the purge control valve 4 includes a valve body 43 and an electromagnetic coil portion 42 including a coil portion, a spring 44, and the like. The purge control valve 4 opens and closes the evaporated fuel passage by driving the valve body 43 in accordance with the balance between the electromagnetic force generated when the coil portion is energized and the urging force of the spring 44.

  The purge control valve 4 includes a housing 40 that forms a passage in the housing. The purge control valve 4 normally maintains a state in which the housing passage forming the evaporated fuel passage is closed, and when the coil portion is energized, the electromagnetic force overcomes the elastic force of the spring 44 and the valve body 43 The housing passage is opened away from the seat 41b. The control device controls the ratio of the on time to the time of one cycle formed by the on time and off time of energization, that is, the duty ratio, and energizes the coil unit. The purge control valve 4 is also called a duty control valve. By this energization control, the flow rate of the evaporated fuel flowing through the passage in the housing is adjusted.

  The first check valve device 3 is an evaporated fuel passage from the canister 16 to the intake pipe 10 and is a valve installed between the purge control valve 4 and the intake manifold 20. In the evaporated fuel passage, the first check valve device 3 allows the original flow of the evaporated fuel from the fuel inflow passage (passage in the relay pipe 19) to the fuel outflow passage (passage in the pipe 18). The reverse flow of the evaporated fuel from the outflow passage to the fuel inflow passage is prevented. The first check valve device 3 includes a valve body 30 that operates so as to open the flow path with the original flow of the evaporated fuel and close the flow path with the reverse flow of the evaporated fuel.

  The branch passage formed inside the branch pipe 19 a is a relay passage, that is, a passage that branches from a passage portion between the purge control valve 4 and the first check valve device 3. The first check valve device 3 is a backflow prevention valve installed between a branch point branching to the branch passage and the fuel outflow passage. The downstream end of the branch passage is connected to a pipe located upstream from the supercharger 12. The evaporative fuel processing system includes the branch pipe 19 a, whereby the evaporative fuel that has passed through the purge control valve 4 can be introduced into the passage upstream of the supercharger 12.

  The second check valve device 5 is a backflow prevention valve installed in the branch passage. The second check valve device 5 allows the original flow of the evaporated fuel from the relay passage to the passage upstream of the supercharger 12 in the branch passage, and prevents the reverse flow of the evaporated fuel to the relay passage. be able to. The second check valve device 5 includes a valve body 50 that operates to open the flow path in the branch passage and close the flow path with the backflow of the evaporated fuel.

  When the supercharger 12 is not operating when the vehicle is running (normal purge), when the purge control valve 4 is opened by the control device, the negative pressure in the intake manifold 20 generated by the intake action of the piston and the canister 16 are reduced. A difference from such atmospheric pressure occurs. Due to this pressure difference, the vapor fuel adsorbed in the canister 16 flows through the fuel inflow passage, the purge control valve 4, the relay passage, the first check valve device 3, and the fuel outflow passage, and is sucked into the intake manifold 20. The

  The evaporated fuel sucked into the intake manifold 20 is mixed with the original combustion fuel supplied from the injector or the like to the engine 22 and burned in the cylinder of the engine 22. Further, in the cylinder of the engine 22, the air-fuel ratio, which is the mixing ratio of the combustion fuel and the intake air, is controlled so as to become a predetermined air-fuel ratio. The control device performs duty control on the opening / closing time of the purge control valve 4 to adjust the purge amount of the evaporated fuel so that the predetermined air-fuel ratio is maintained even if the evaporated fuel is purged.

  When the supercharger 12 is in operation when the vehicle is running (supercharging purge), the intake manifold 20 becomes positive pressure due to the pressurized intake air. For this reason, the amount of evaporated fuel cannot be supplied to the engine 22 through the purge control valve 4. Further, at this positive pressure, the evaporated fuel may flow backward and the evaporated fuel may be released into the atmosphere. In order to prevent this backflow, a first check valve device 3 is provided.

  Further, when the purge control valve 4 is opened during the supercharging purge, the vapor fuel adsorbed in the canister 16 flows through the fuel inflow passage and the purge control valve 4, and passes through the second check valve device 5 from the relay passage. It passes through the branch passage and is supplied to the passage upstream of the supercharger 12. Thus, the evaporated fuel supplied to the upstream side of the supercharger 12 reaches the intake manifold 20 via the intake pipe 10 and is mixed with the original combustion fuel supplied to the engine 22 from the injector or the like. It is burned in the cylinder of the engine 22.

  The housing 40 is a cup-shaped body having a bottom portion on one end side and an opening 40c on the other end side opposite to the one end side. The opening 40c has a track shape. The housing 40 accommodates a valve body 43 for opening and closing the passage in the housing and an electromagnetic coil portion 42 for driving the valve body 43. The housing 40 forms a housing-side chamber chamber 45a at the bottom of the housing 40 on the side opposite to the one side where the electromagnetic coil portion 42 is installed. Inside the housing 40, a filter 46 is provided closer to the housing-side chamber chamber 45a than the electromagnetic coil portion 42 in the passage in the housing. The housing side chamber chamber 45a is a part of the in-housing passage formed between the filter 46 and the opening 40c. The housing side chamber chamber 45a is an internal space of the chamber forming portion 45 that is a part of the housing 40 on the side opposite to the portion that accommodates the electromagnetic coil portion.

  The housing 40 includes a connector 40b extending outward on one side where the electromagnetic coil portion 42 is installed. The connector 40b is a resin molded part that incorporates a terminal 40b1 for energizing the coil part, and the terminal 40b1 protrudes from the inside to the outside. The terminal 40b1 is a current-carrying terminal that is electrically connected to the coil portion. A power supply side connector for supplying power from the power supply unit and the current control device is connected to the connector 40b. When the connector 40b and the power supply side connector are connected and the terminal 40b1 is electrically connected to a current control device or the like, the purge control valve 4 can control the current supplied to the coil portion.

  The housing 40 has a flange portion 40a that protrudes radially outward in the entire circumference of the opening 40c. The flange portion 40 a is a portion joined to the flange portion 41 c corresponding to the outer peripheral edge portion of the intermediate member 41. The intermediate member 41 is a member that is interposed between the housing 40 and the inflow / outflow member 6 and is coupled to the housing 40 and the inflow / outflow member 6. The flange portion 40a is integrally joined in a state where the flange portion 40a is overlapped with the flange portion 41c.

  The intermediate member 41 has an outer peripheral edge having a track shape similar to that of the flange portion 40a and a flange portion 41c. The intermediate member 41 includes an annular projecting portion 41d and a tubular portion 41a that project from one surface in the thickness direction of the flange portion 41c.

  The annular protrusion 41d is a part that fits with the inner peripheral wall surface of the housing 40 that forms the opening 40c. As shown in FIGS. 3 and 4, a first passage 41 e and a second passage 410 that penetrate the intermediate member 41 in the thickness direction are provided inside the annular protrusion 41 d so as to be separated from each other by a predetermined size. . The first passage 41e communicates with the second passage 410 via the housing side chamber chamber 45a. The cylindrical part 41a has a valve seat 41b with which the valve body 43 comes into contact at the distal end side. The tubular portion 41a has a shape protruding inside the housing 40, and has a second passage 410 in which evaporated fuel flows from the housing-side chamber chamber 45a side when the valve body 43 is in the open state.

  The inflow / outflow member 6 is connected to the housing 40 via the intermediate member 41. The inflow / outflow member 6 has an inflow portion 63 into which the evaporated fuel from the canister 16 side flows, and an outflow portion 61 and an outflow portion 62 from which the evaporated fuel from the purge control valve 4 flows out to the engine 22 side. . Inside the inflow portion 63, an inflow passage through which the evaporated fuel flows toward the in-housing passage of the housing 40 is formed. The inflow portion 63 is a tubular portion that protrudes from the surface opposite to the intermediate member 41 in the inflow / outflow member 6. The outflow part 61 and the outflow part 62 form an outflow passage that branches into two downstream from the purge control valve 4.

  The inflow / outflow member 6 includes a flange portion 60 including an annular protrusion that protrudes in the thickness direction from the outer peripheral edge of the surface on the side facing the intermediate member 41. The flange part 60 is a part joined to the flange part 41 c of the intermediate member 41. The flange portion 60 is integrally joined in a state where the flange portion 60 is overlapped with the flange portion 41c.

  As shown in FIG. 5, the inflow / outflow member 6 includes a partition portion 60d that partitions the first chamber 60b in which the outlet portion of the inflow passage opens and the second chamber 60c in which the inlet portion of the outflow passage opens. The first chamber 60 b is a flat space surrounded by the partition portion 60 d and the annular projecting portion of the flange portion 60. The second chamber 60c is a flat space surrounded by the partition portion 60d and the annular projecting portion of the flange portion 60 on the opposite side of the partition portion 60d from the first chamber 60b. The partition portion 60d is in contact with the end surface of the intermediate member 41 in a state where the flange portion 60 and the flange portion 41c are joined, thereby defining the first chamber 60b and the second chamber 60c. As described above, the outflow passages in the outflow portion 61 and the outflow portion 62 and the inflow passage in the inflow portion 63 are defined so as to communicate with each other via the in-housing passage in the housing 40.

  When the inflow / outflow member 6 is coupled to the intermediate member 41 so that the outflow portion 61 and the outflow portion 62 are positioned in the vicinity of the passage shaft 410cL1 of the second passage 410 as shown in FIG. Only the first chamber 60b is connected, and the second passage 410 is connected only to the second chamber 60c. This case is indicated by a two-dot chain line in FIG. Further, when the inflow / outflow member 6 is connected to a position rotated 180 degrees from the direction shown in FIG. 3 with respect to the intermediate member 41 so that the inflow portion 63 is located in the vicinity of the passage shaft 410cL1, the first passage 41e is connected only to the second chamber 60c, and the second passage 410 is connected only to the first chamber 60b. This case is indicated by a broken line in FIG. 2-5, the virtual line shown with the dashed-two dotted line is a line set on the end surface of the flange part 40a of the housing 40. As shown in FIG. According to such a configuration, since the inflow / outflow member 6 can be connected to the housing 40 at a position reversed with respect to the connection position shown in FIG. A device that can be mounted can be provided. Moreover, the control valve assembly 8 which can respond to the dimensional variation at the time of manufacture can be provided.

  The imaginary line 41cL1 is a line that intersects with both the passage axis of the first passage 41e and the passage axis of the second passage 410. The virtual line 41cL2 is a line orthogonal to both the virtual line 41cL1 and the passage axis 410cL. The passage shaft 410cL is also the central axis of the electromagnetic coil unit 42. The inflow portion 63 has an inflow passage extending in a direction along the passage shaft 410cL. Since air exists in the second chamber 60c when the valve body 43 is closed, the second chamber 60c corresponds to an air layer and has a heat insulating performance.

  The joining of the flange portions such as the flange portion 40a, the flange portion 41c, and the flange portion 60 can be performed by melting the resin by laser irradiation and bonding them together. The integral joining of the flange portions may be formed by a joining means using an adhesive. In this way, the flange portions are integrally joined, so that the control valve assembly 8 can be formed so that the fluid flowing through the evaporated fuel passage does not leak to the outside.

  The inflow / outflow member 6 includes an outflow side housing 6a having an internal passage 6a1 that communicates the outflow portion 61 and the outflow portion 62 with the second chamber 60c. The outflow side housing 6a is integrally provided with an outflow portion 61 and an outflow portion 62 branched from the internal passage 6a1. The outflow part 61 and the outflow part 62 are in a positional relationship facing each other. The outflow part 61 and the outflow part 62 each have the same shape part which can mount | wear with various components. This identically shaped portion is preferably shaped so that it can be mounted at a position where the component is rotationally displaced about its axis. The identically shaped portion has, for example, a circular shape that allows the component parts to rotate and displace around its axis, and a regular polygon shape that can be mounted in a state where it is angularly displaced at a predetermined angle.

  The outflow portion 61 has a flange portion 610 and a cylindrical portion to which components can be attached. The flange portion 610 is located on the distal end side in the outflow portion 61, and is provided integrally with a cylindrical portion that connects the opening formed inside and the internal passage 6a1. That is, the cylindrical portion is a portion that is integrally provided on the outflow side housing 6 a on the base side of the outflow portion 61 and integrally connects the outflow side housing 6 a and the flange portion 610.

  The outflow portion 62 forms an outflow passage extending in the opposite direction to the outflow portion 61 in the inflow / outflow member 6, and the passage axis is oriented along the outflow portion 61. The outflow part 62 has a flange part 620 and a cylindrical part to which components can be attached. The flange portion 620 is located on the distal end side in the outflow portion 62 and is provided integrally with a cylindrical portion connecting the opening formed inside and the internal passage 6a1. That is, the cylindrical portion is a portion that is integrally provided on the outflow side housing 6a on the base side of the outflow portion 62, and integrally connects the outflow side housing 6a and the flange portion 620.

  The inflow portion 63 is provided in the inflow / outflow member 6 such that the passage axis intersects or is orthogonal to the outflow portion 61 and the outflow portion 62. The outflow part 61 and the outflow part 62 have an opening that opens in different directions. The opening of the outflow portion 61 opens in the opposite direction to the opening of the outflow portion 62.

  An umbrella-shaped valve body 30 constituting the first check valve device 3 is installed inside the cylindrical portion in the outflow portion 61. Inside the cylindrical portion, a passage crossing wall portion that bisects the inside of the cylindrical portion in the outflow portion 61 in the fluid flow direction is provided. The passage transverse wall portion is provided with a central hole portion that penetrates the center and a plurality of peripheral hole portions that are through-holes that penetrate the periphery of the central hole portion. The passage transverse wall portion supports the shaft portion of the valve body 30 in a state of being inserted into the center hole portion. The plurality of peripheral holes are passages that communicate the internal passage 6a1 in the outflow side housing 6a with the outflow passage in the outflow portion 61.

  An umbrella-shaped valve body 50 constituting the second check valve device 5 is installed inside the cylindrical portion of the outflow portion 62. Inside the cylindrical part, a passage crossing wall part that bisects the inside of the cylindrical part in the outflow part 62 in the fluid flow direction is provided. The passage transverse wall portion is provided with a central hole portion similar to the outflow portion 61 and a plurality of peripheral hole portions. The passage transverse wall portion supports the shaft portion of the valve body 50 in a state of being inserted into the center hole portion. The first check valve device 3 and the second check valve device 5 are in a positional relationship facing the internal passage 6a1 therebetween.

  The valve body of each check valve has a shaft portion supported by the passage crossing wall portion and an umbrella portion provided integrally on the base side of the shaft portion. The umbrella portion is an elastically deformable portion, covers the peripheral hole portion in the outflow passage of each outflow portion 61, 62, and is in contact with the outer diameter side of the peripheral hole portion in the passage transverse wall portion. Each check valve prevents the backflow of the evaporated fuel in the internal passage 6a1 from the outflow passage when the pressure acts on the internal passage 6a1 side with respect to the umbrella portion so that the umbrella portion comes into close contact with the passage transverse wall portion. When the pressure from the internal passage 6a1 side acts on the umbrella portion, each check valve elastically deforms the umbrella portion and moves away from the passage transverse wall portion, so that the outflow passage from the internal passage 6a1 through the peripheral hole portion. Allow evaporative fuel to flow down.

  Since the inflow / outflow member 6 includes a check valve device, a control valve assembly 8 on which the check valve device can be mounted is obtained. Further, since the control valve assembly 8 accommodates the check valve device, it is possible to provide the control valve assembly 8 that contributes to suppressing the physique of the entire assembly and can effectively use the installation space.

  Each of the outflow part 61 and the outflow part 62 is fitted with a tubular member 7 which is one of the components. The tubular member 7 includes a flange portion 70 that is fixed to the outflow portions 61 and 62 by welding or adhesion, and a tubular portion 71 that extends from the flange portion 70. The tubular part 71 has a passage communicating with the internal space of the outflow part. The tubular portion 71 is connected to a pipe that forms an evaporated fuel passage in the evaporated fuel processing system. As described above, the control valve assembly 8 includes the housing 40 including the electromagnetic coil section 42, the intermediate member 41, the inflow / outflow member 6, and the two tubular members 7 connected to the inflow / outflow member 6. A first check valve device 3 and a second check valve device 5 housed in the inflow / outflow member 6 are provided.

  The tubular member 7 connected to the outflow portion 61 is connected to the pipe 18 and communicates with the throttle valve 21 via the pipe 18. The tubular member 7 connected to the outflow portion 62 is connected to the branch pipe 19a and communicates with a passage on the upstream side of the supercharger 12 through the branch pipe 19a.

  Next, the effect which the control valve assembly 8 of 1st Embodiment brings is demonstrated. The control valve assembly 8 is installed in an evaporated fuel passage through which evaporated fuel desorbed from the canister 16 flows toward the engine 22. The control valve assembly 8 includes a housing 40 having a built-in electromagnetic coil portion 42 that drives a valve body 43 for opening and closing a passage in the housing, and an inflow / outflow member 6 connected to the housing 40. The inflow / outflow member 6 includes an inflow portion 63 in which an inflow passage through which evaporated fuel flows toward the in-housing passage is formed, and outflow portions 61 and 62 in which outflow passages in which the evaporative fuel that has flowed out from the in-housing passage flows are formed. Have The outflow passage in the outflow portion 61 and the inflow passage in the inflow portion 63 are partitioned so as to communicate with each other through the in-housing passage.

  The control valve assembly 8 includes a housing 40 having a built-in electromagnetic coil portion 42 that drives the valve body 43, an evaporative fuel inflow portion 63, and an outflow portion 61. 6 is connected. According to this configuration, the control valve assembly 8 that conforms to the vehicle-side specifications and the like can be newly provided only by preparing the inflow / outflow member 6 in which the orientation of the inflow portion 63 and the outflow portion 61 is changed. Thereby, various components can be installed in various positions and orientations according to the positions and orientations of the inflow portion 63 and the outflow portion 61. According to the control valve assembly 8, the direction of the passage connected to the control valve in the evaporated fuel passage can be selected widely. The components include a check valve device, a tubular member 7, a lid member 9, and the like.

  According to the control valve assembly 8 as described above, it is possible to implement various components in a place where the influence of vibration can be suppressed as much as possible in a place where the vibration part such as the engine 22 exists. Further, the control valve assembly 8 can be applied to an evaporative fuel processing system that can cope with product specifications of various vehicles, and can contribute to reducing the number of parts management man-hours related to component connection in the evaporative fuel processing system.

  The components included in the control valve assembly 8 are various components provided in the evaporated fuel processing system. The control valve assembly 8 is an assembly in which a plurality of components are connected to the purge control valve 4 and constitutes a specific portion of the evaporated fuel passage. By connecting a plurality of components through the housing 40 containing the electromagnetic coil portion 42, the number of components to be connected, the direction in which each of the plurality of passages extends, and the positional relationship and the direction relationship with respect to the plurality of passages are various. The configuration can be selected.

  The control valve assembly 8 contributes to efficiently and rationally installing various components, piping, and the like in a narrow space such as an engine compartment, or to a desired installation state.

  The intermediate member 41 has a valve seat 41b on which the valve body 43 is seated, a first passage 41e communicating with the inflow passage, and a second passage 410 communicating with the outflow passage. The intermediate member 41 and the inflow / outflow member 6 The housing 40 and the inflow / outflow member 6 are coupled to each other. According to this configuration, the housing 40 incorporating the electromagnetic coil portion 42 and the valve seat 41b are configured as separate components, whereby the housing 40 can be formed in a small size, and the configuration as a common component can be simplified.

  The inflow / outflow member 6 is provided with a first chamber 60b and a second chamber 60c formed on both sides of the partition portion 60d. The first chamber 60b has an inflow passage outlet, and the second chamber 60c has an outflow passage entrance. Accordingly, it is possible to realize an evaporative fuel passage in which the inflow passage and the outflow passage communicating with each other via the in-housing passage can be installed on the same side of the housing 40. Thereby, it is possible to provide the control valve assembly 8 that can contribute to improving the workability of the piping and the like extending from the control valve assembly 8.

  The control valve assembly 8 includes a tubular member 7 that is a separate component from the inflow / outflow member 6 and is attached to the outflow portions 61 and 62. According to this configuration, since the tubular member 7 suitable for the shape and size of the piping constituting the system can be attached to the inflow / outflow member 6, piping that is not limited to the shape of the inflow portion or the outflow portion is connected to the control valve assembly 8. It becomes possible to do.

  The inflow / outflow member 6 has a first outflow portion 61 and a second outflow portion 62 as an outflow portion. The control valve assembly 8 includes a first check valve device 3 installed inside the first outflow portion 61, a second check valve device 5 installed inside the second outflow portion 62, and Is further provided. According to this configuration, the control valve assembly 8 that can be mounted in the evaporated fuel processing system of the first embodiment can be provided. The control valve assembly 8 can further provide a passage where the evaporated fuel branches into two on the upstream side of the check valve in the passage from the purge control valve 4 side to the intake manifold 20. According to the control valve assembly 8 that forms the branch passage in this way, piping can be installed so as to avoid surrounding parts, vibration transmission from surrounding parts can be suppressed, and effective use of the installation space can be achieved. Contributes to planning.

  The outflow part 61, the outflow part 62, and the inflow part 63 have openings that open in different directions. According to this, since the component connected to the purge control valve 4 can be installed so as to extend in a different direction with respect to the other components, it is possible to provide the control valve assembly 8 capable of effectively utilizing the installation space.

  In the inflow / outflow member 6, the first outflow portion 61 and the second outflow portion 62 are opposed to each other. The inflow portion 63 extends in a direction that intersects the opposing direction in which the first outflow portion 61 and the second outflow portion 62 face each other. According to this, it is possible to provide the control valve assembly 8 applicable to a system having a passage for branching the evaporated fuel passing through the internal passage 6a1 in the outflow side housing 6a into a reverse flow.

(Second Embodiment)
A second embodiment will be described with reference to FIG. The configuration, operation, and effects not particularly described in the second embodiment are the same as those in the first embodiment, and only differences from the first embodiment will be described below.

  The second embodiment differs from the first embodiment in the inflow / outflow member 106. Therefore, in the second embodiment, the configuration relating to the control valve assembly 108 is different from that of the first embodiment.

  As shown in FIG. 6, the inflow / outflow member 106 included in the control valve assembly 108 includes a flange portion 160 having a different configuration from the flange portion 60 of the inflow / outflow member 6. The surface of the flange portion 160 that faces the intermediate member 41 forms a flat surface as a whole. That is, the first chamber 60 b and the second chamber 60 c are not formed in the inflow / outflow member 106. Also in the inflow / outflow member 106, the outflow passages of the outflow portion 61 and the outflow portion 62 and the inflow passage of the inflow portion 63 are partitioned so as to communicate with each other via the in-housing passage.

  The inflow / outflow member 106 has a first seal portion 106 a and a second seal portion 106 b on the inner side of the flange portion 160. The first seal portion 106 a is an O-ring member that hermetically seals between the intermediate member 41 and the inflow / outflow member 106 around the first passage 41 e of the intermediate member 41. The second seal portion 106 b is an O-ring member that hermetically seals between the intermediate member 41 and the inflow / outflow member 106 around the second passage 410 of the intermediate member 41. The flange portion 160 is a portion joined to the flange portion 41 c of the intermediate member 41. The flange portion 160 is integrally joined to the flange portion 41c in a state of being overlapped.

(Third embodiment)
A third embodiment will be described with reference to FIG. The configuration, operation, and effects not particularly described in the third embodiment are the same as those in the first embodiment, and only differences from the first embodiment will be described below.

  The third embodiment differs from the first embodiment in the control valve assembly 208. As shown in FIG. 7, the control valve assembly 208 includes a tubular member 630 connected to the inflow portion 63 of the inflow / outflow member 206. The tubular member 630 is connected to the pipe 18 and communicates with the throttle valve 21 via the pipe 18.

(Fourth embodiment)
A fourth embodiment will be described with reference to FIG. The configuration, operation, and effects not specifically described in the fourth embodiment are the same as those in the first embodiment, and only differences from the first embodiment will be described below.

  The fourth embodiment is different from the first embodiment in the inflow / outflow member 306. Therefore, in the fourth embodiment, the configuration relating to the control valve assembly 308 is different from that in the first embodiment.

  As shown in FIG. 8, the inflow / outflow member 306 included in the control valve assembly 308 includes an outflow side housing 206a having an internal passage 6a1 that communicates the outflow portion 61 and the outflow portion 62 with the second chamber 60c. The outflow side housing 206a is integrally provided with an outflow part 61 and an outflow part 62 branched from the internal passage 6a1. The outflow portion 61 and the outflow portion 62 have an outflow passage extending in a direction intersecting with each other. The outflow part 62 is provided in a direction in which the passage axis is along the inflow part 63.

  According to the fourth embodiment, the inflow / outflow member 306 has the first outflow portion 61 and the second outflow portion 62 as the outflow portion. The 1st outflow part 61 and the 2nd outflow part 62 have the crossing relationship extended in the direction which mutually cross | intersects. The inflow portion 63 extends along either the first outflow portion 61 or the second outflow portion 62. According to this, it is possible to provide the control valve assembly 308 applicable to a system having a passage that divides the evaporated fuel passing through the internal passage 6a1 in the outflow side housing 206a into a flow that flows straight and a flow that branches.

(Fifth embodiment)
A fifth embodiment will be described with reference to FIGS. 9 and 10. The configuration, operation, and effect not particularly described in the fifth embodiment are the same as those in the first embodiment, and only differences from the first embodiment will be described below.

  The fifth embodiment differs from the first embodiment in the circumferential position around the axis of the inflow / outflow member 6 relative to the housing 40 or the connection position around the axis of the inflow / outflow member 6 relative to the housing 40. ing. As shown in FIGS. 9 and 10, the control valve assembly 408 of the fifth embodiment is provided in the housing 40 so that the inflow portion 63 corresponds to the second passage 410 and the internal passage 6a1 corresponds to the first passage 41e. The inflow / outflow member 6 is connected. That is, the control valve assembly 408 is configured to be connected to the intermediate member 41 at a position where the inflow / outflow member 6 is rotated 180 degrees around the axis with respect to the inflow / outflow member 6 of the control valve assembly 8.

  Due to the positional relationship between the inflow / outflow member 6 and the housing 40, the first passage 41 e communicates with the internal passage 6 a 1 and the second passage 410 communicates with the inflow passage of the inflow portion 63. According to the control valve assembly 408, the evaporated fuel flows from the inflow portion 63 to the first chamber 60 b, the second passage 410, the filter 46, the housing side chamber chamber 45 a, the first passage 41 e, the second chamber 60 c, The outflow parts 61 and 62 are distributed in order.

  According to the fifth embodiment, according to the connection position around the axial center of the inflow / outflow member 6 with respect to the housing 40, both the first connection state and the second connection state can be implemented. The partition 60d is provided on the inflow / outflow member 6. The first connection state is a state in which the outlet portion of the inflow passage is connected to one end side of the in-housing passage and the inlet portion of the outflow passage is connected to the other end of the in-housing passage. The second connection state is a state in which the outlet portion of the inflow passage is connected to the other end side of the in-housing passage, and the inlet portion of the outflow passage is connected to one end side of the in-housing passage. Accordingly, it is possible to provide the control valve assembly 408 that can be mounted on a system that reverses the direction in which the evaporated fuel flows in the passage in the housing 40.

(Sixth embodiment)
A sixth embodiment will be described with reference to FIGS. 11 and 12. The configuration, operation, and effects not particularly described in the sixth embodiment are the same as those in the first embodiment, and only differences from the first embodiment will be described below.

  The sixth embodiment differs from the first embodiment in the configuration of the control valve assembly 508. As shown in FIGS. 11 and 12, the control valve assembly 508 includes a canister-side connecting member 406d and an engine-side connecting member 406h that can be attached to and detached from the inflow / outlet member 406.

  The canister side connecting member 406d includes an inflow portion 63 that is a tubular portion, a tubular portion 406d1 that is integral with the tubular portion, and a plurality of engaging portions 64 that are provided in the tubular portion 406d1. For example, the engaging portion 64 has a free end on the tip side, and a plurality of engaging portions 64 are provided over the entire circumference of the tubular portion 406d1. The engaging part 64 engages with the front end side flange part 406b in a state of being fitted on the front end side flange part 406b of the first tubular part 406a. The engaging portion 64 is supported so as to hold the outer periphery of the distal end side flange portion 406b by deforming the distal end portion so as to expand in the radially outward direction and then returning to the radially inward direction by a restoring force. With this configuration, the engaging portion 64 can be attached to and detached from the first tubular portion 406a. The first tubular portion 406a constitutes an inflow portion in which an inflow passage through which evaporated fuel flows toward the in-housing passage is formed. An O-ring member 406c is sandwiched and sealed between the canister side connecting member 406d and the front end flange portion 406b, and the inflow passage is blocked from the outside.

  The engine-side connecting member 406h includes a tubular portion 406h2 and a tubular portion 406h3 that are in an opposing positional relationship, a tubular portion 406h1 in which these tubular portions are integrally formed, and a plurality of engagements provided in the tubular portion 406h1. Part 64. For example, the engaging portion 64 has a free end on the tip side, and a plurality of engaging portions 64 are provided over the entire circumference of the tubular portion 406h1. The engaging portion 64 engages with the distal end side flange portion 406f in a state of being fitted on the distal end side flange portion 406f of the second cylindrical portion 406e. The engaging portion 64 is supported so as to hold the outer periphery of the front end side flange portion 406f by deforming the front end portion so as to spread outward in the radial direction and then returning in the radial inner direction by a restoring force. With this configuration, the engaging portion 64 can be attached to and detached from the second tubular portion 406e. An O-ring member 406g is sandwiched between the engine-side connecting member 406h and the tip-side flange portion 406f and is airtight, and the outflow passage is blocked from the outside.

  According to the sixth embodiment, the inflow / outflow member 406 is a separate part having an engaging portion 64 that is attachable / detachable to / from the inflow / outflow member 406 and can be connected to a pipe. 406d and the engine side connecting member 406h are connected. According to this configuration, the canister side connecting member 406d and the engine side connecting member 406h can be attached to and detached from the inflow / outlet member 406. Therefore, the canister side connecting member 406d and the engine side connecting member 406h are interchanged. Can be connected to member 406. Accordingly, it is possible to provide the control valve assembly 508 that can be mounted in a system that reverses the direction in which the evaporated fuel flows in the passage in the housing 40.

  The engine side coupling member 406h includes two tubular portions 406h2 and 406h3 to which piping can be connected. The two tubular portions 406h2 and 406h3 are provided at opposing positions in the engine side connecting member 406h. According to this configuration, it is possible to provide the control valve assembly 508 applicable to a system having a passage that divides the evaporated fuel flowing out of the purge control valve 4 into flows that branch in opposite directions.

(Seventh embodiment)
A seventh embodiment will be described with reference to FIG. The configuration, operation, and effects not particularly described in the seventh embodiment are the same as those in the sixth embodiment, and only differences from the sixth embodiment will be described below. As shown in FIG. 13, in the control valve assembly 608 of the seventh embodiment, the engine side connecting member 406h and the first cylindrical portion 406a are connected, and the canister side connecting member 406d and the second cylindrical portion 406e are connected. It is the structure which is done.

(Eighth embodiment)
An eighth embodiment will be described with reference to FIG. The configuration, operation, and effects not particularly described in the eighth embodiment are the same as those in the sixth embodiment, and only differences from the first embodiment will be described below.

  The eighth embodiment is different from the sixth embodiment in the engine side connecting member 406i. Therefore, in the eighth embodiment, the configuration relating to the control valve assembly 708 is different from that in the first embodiment.

  As shown in FIG. 14, the engine side connecting member 406i has an outflow passage extending in a direction in which the tubular portion 406h2 and the tubular portion 406h3 intersect each other. The tubular portion 406 h 3 is provided in a direction in which the passage axis is along the inflow portion 63. According to this, it is possible to provide a control valve assembly 708 applicable to a system having a passage that divides the evaporated fuel passing through the outflow passage in the second cylindrical portion 406e into a flow that flows straight and a flow that branches. .

(Ninth embodiment)
A ninth embodiment will be described with reference to FIGS. 15 and 16. The configuration, operation, and effects not specifically described in the ninth embodiment are the same as those in the first embodiment, and only differences from the first embodiment will be described below.

  The ninth embodiment is different from the first embodiment in the inflow / outflow member 506. As shown in FIGS. 15 and 16, the inflow / outflow member 506 includes an inflow portion 506b and a cylindrical portion 506a into which evaporated fuel from the canister 16 side flows, and evaporated fuel from the purge control valve 4 toward the engine 22 side. It has the outflow part 61 and the outflow part 62 which flow out. An inflow passage through which evaporated fuel flows toward the in-housing passage of the housing 40 is formed inside the cylindrical portion 506a and the inflow portion 506b. The inflow portion 506b is a tubular portion that protrudes from the tubular portion 506a on the side opposite to the intermediate member 41 in the inflow / outflow member 506. The cylindrical portion 506a constitutes an inflow portion in which an inflow passage through which evaporated fuel flows toward the in-housing passage is formed. The cylindrical portion 506a has an upstream chamber chamber 506a1 inside. The passage in the inflow portion 506b and the first passage 41e communicate with each other via the upstream chamber chamber 506a1. The cylindrical portion 506a and the flange portion 60 may be configured such that separate parts are integrally fixed, or may be configured as a single part integrally molded using a mold.

  Inside the inflow / outflow member 506, an upstream chamber chamber 506 a 1 is provided between the inflow passage in the inflow / outflow member 506 and the first passage 41 e in the intermediate member 41. The upstream chamber chamber 506a1 has a passage cross-sectional area larger than each of the inflow passage and the first passage 41e. According to this, it is possible to reduce the pulsation that is likely to occur in the passage on the canister 16 side when the control valve assembly 808 is closed. Since the upstream chamber chamber 506a1 has a passage cross-sectional area larger than each of the inflow passage and the first passage 41e, the inflow passage and the first passage 41e can be used as a pulsation reducing throttle portion.

  Furthermore, a housing side chamber chamber 45a is provided inside the housing 40 so that the first passage 41e exists between the upstream side chamber chamber 506a1. The housing side chamber chamber 45a has a passage cross-sectional area larger than that of the first passage 41e. According to this, the housing side chamber chamber 45a and the upstream side chamber chamber 506a1 can increase the chamber volume that exerts a pulsation reducing effect, and the inflow passage, the upstream side chamber chamber 506a1, the first passage 41e, and the housing side chamber chamber 45a are arranged. A pulsation reducing effect is obtained.

(10th Embodiment)
A tenth embodiment will be described with reference to FIG. The configuration, operation, and effects not particularly described in the tenth embodiment are the same as those in the ninth embodiment, and only differences from the first embodiment will be described below.

  The tenth embodiment is different from the ninth embodiment in that the control valve assembly 908 has a configuration in which a tubular portion 606a and a tubular portion 606c2 which are separate parts are mounted and fixed. The inflow / outflow member 606 includes a cylindrical portion 606a and a tubular member 606c, which are separate parts, as members that form the inflow passage and the upstream chamber chamber 506a1. The cylindrical portion 606 a is a portion that is formed integrally with the flange portion 60. The cylindrical portion 606a constitutes an inflow portion in which an inflow passage through which evaporated fuel flows toward the in-housing passage is formed. The tubular member 606c includes a flange portion 606c1 that is fixed to the flange portion 606b of the tubular portion 606a by welding or adhesion, and a tubular portion 606c2 that extends from the flange portion 606c1. The tubular portion 606c2 is connected to the pipe 17 that forms the evaporated fuel passage in the evaporated fuel processing system.

(Eleventh embodiment)
The eleventh embodiment will be described with reference to FIGS. The configuration, operation, and effects not particularly described in the eleventh embodiment are the same as those in the first embodiment, and only differences from the first embodiment will be described below.

  The eleventh embodiment differs from the first embodiment in an evaporated fuel processing system and a control valve assembly 1008. The evaporated fuel processing system shown in FIG. 18 differs from the evaporated fuel processing system of the first embodiment in that it does not have a branch passage and a second check valve device 5. Therefore, in the eleventh embodiment, the components included in the control valve assembly 1008 are different from those in the first embodiment. In the control valve assembly 1008 of the eleventh embodiment, the lid member 9 is attached to the outflow portion 62. The lid member 9 is a member that closes the opening end of the outflow portion 62 and blocks the passage extending outward from the passage in the outflow portion 62. The control valve assembly 1008 includes a first check valve device 3 installed in an outflow passage formed in the outflow portion. According to this configuration, it is possible to provide the control valve assembly 1008 that can be mounted on the evaporated fuel processing system of the eleventh embodiment.

(Twelfth embodiment)
A twelfth embodiment will be described with reference to FIG. The configuration, operation, and effects not particularly described in the twelfth embodiment are the same as those in the first embodiment, and only differences from the first embodiment will be described below.

  The twelfth embodiment differs from the first embodiment in the inflow passage in the inflow portion 163. As shown in FIG. 20, the inflow portion 163 includes an annular wall portion 631 at the downstream end portion. The annular wall portion 631 is integrally formed with the inflow portion 163. The inflow portion 163 includes a throttle passage 631 a that is a through hole formed in the center of the annular wall portion 631. The throttle passage 631a is a passage that communicates the inflow passage with the first chamber 60b. The throttle passage 631a is a passage having a smaller passage cross-sectional area than the inflow passage and the first chamber 60b, and provides a flow resistance to the fluid. The passage cross-sectional area of the throttle passage 631a is a cross-sectional area when the throttle passage 631a is cut by a plane orthogonal to the central axis of the throttle passage 631a. As described above, the upstream side and the downstream side of the throttle passage 631a are provided with the inflow passage and the first chamber 60b in which the flow resistance is reduced with respect to the throttle passage 631a.

  The inflow / outflow member 706 of the twelfth embodiment has a passage cross-sectional area smaller than each of the inflow passage and the first chamber 60b, and includes a throttle passage 631a that connects the inflow passage and the first chamber 60b. According to this configuration, pressure loss can be applied to the pulsating flow propagating upstream in the valve-closed state by the throttle passage 631a. As a result, the pulsating flow is forced to diffuse, contract, and diffuse toward the upstream, so that the control valve assembly 8 that contributes to effectively attenuating the pulsation can be provided. According to this configuration, the control valve assembly 8 that contributes to effectively attenuating pulsation can be newly provided only by preparing the inflow / outflow member 706 including the inflow portion 163 incorporating the throttle passage 631a. Further, the throttle passage 631a according to the twelfth embodiment is also applicable to the inflow portion in the second embodiment, the third embodiment, the fourth embodiment, the fifth embodiment, and the eleventh embodiment.

(13th Embodiment)
A thirteenth embodiment will be described with reference to FIG. The configuration, operation, and effects not particularly described in the thirteenth embodiment are the same as those in the ninth embodiment, and only differences from the ninth embodiment will be described below.

  The thirteenth embodiment differs from the ninth embodiment in the internal passage of the cylindrical portion 506a. As shown in FIG. 21, the cylindrical portion 506a includes an annular wall portion 632 that bisects the internal upstream chamber chamber 506a1 into an upstream side and a downstream side. The annular wall portion 632 is a separate component from the tubular portion 506a, and is joined to the inner wall of the tubular portion 506a by adhesion, welding, or the like. The tubular portion 506 a includes a throttle passage 632 a that is a through hole formed in the center of the annular wall portion 632. The throttle passage 632a is a passage having a smaller passage cross-sectional area than the upstream chamber chamber 506a1, and provides a flow resistance to the fluid. The passage cross-sectional area of the throttle passage 632a is a cross-sectional area when the throttle passage 632a is cut by a plane orthogonal to the central axis of the throttle passage 632a. As described above, the upstream chamber chamber 506a1 that is bisected is provided on the upstream side and the downstream side of the throttle passage 632a so that the flow resistance is reduced with respect to the throttle passage 632a.

  The inflow / outflow member 806 of the thirteenth embodiment includes a throttle passage 632a that has a smaller passage cross-sectional area than the upstream chamber chamber 506a1 and communicates the upstream side and the downstream side of the upstream chamber chamber 506a1. According to this configuration, a pressure loss can be applied to the pulsating flow propagating upstream in the valve closed state by the throttle passage 632a. As a result, the pulsating flow is forced to diffuse, contract, and diffuse toward the upstream, so that a control valve assembly 808 that contributes to effectively dampening the pulsation can be newly provided. According to this configuration, the control valve assembly 808 that contributes to effectively attenuating the pulsation can be newly provided only by preparing the inflow / outflow member 806 including the cylindrical portion 506a including the throttle passage 632a. Further, the throttle passage 632a according to the thirteenth embodiment is also applicable to the cylindrical portion in the sixth embodiment, the seventh embodiment, the eighth embodiment, the ninth embodiment, and the tenth embodiment.

(14th Embodiment)
A fourteenth embodiment will be described with reference to FIGS. The configuration, operation, and effects not specifically described in the fourteenth embodiment are the same as those in the above-described embodiment, and only differences from the above-described embodiment will be described below.

  The fourteenth embodiment is different from the above-described embodiment in that the control valve assembly includes a pressure detection port for detecting the pressure of the evaporated fuel passage. An example of the pressure detection port is a tubular portion 501. As shown in FIG. 22, the tubular portion 501 is provided in at least one of the first part P1, the second part P2, the third part P3, and the fourth part P4 in the control valve assembly. The first part P1 is a part upstream of the valve body 43 of the purge control valve 4 in the control valve assembly. The second portion P2 is a portion downstream of the valve body 43 and upstream of the check valve in the control valve assembly. The third portion P3 is a portion on the downstream side of the first check valve device 3 in the control valve assembly. The fourth portion P4 is a portion on the downstream side of the second check valve device 5 in the control valve assembly.

  The control valve assembly includes a pressure detector 500 that is connected to at least one of the aforementioned P1 to P4 and can detect the pressure in the flow path. For example, the pressure detector 500 can be attached to the control valve assembly via a pipe connected to the tubular portion 501 or a pipe such as a hose. The tubular portion 501 functions as a pressure detection port protruding outward from the control assembly.

  With reference to FIG. 23, an example of the control valve assembly in which the tubular portion 501 is provided in the third portion P3 will be described. The control valve assembly shown in FIG. 23 differs from the eighth embodiment in the configuration of the engine side connecting member 406j. As shown in FIG. 23, the engine side connecting member 406j includes a tubular portion 406h1 having a tubular portion 501. A pipe such as a pipe or a hose can be connected to the tubular portion 501.

  The pressure detector 500 detects the pressure in the pipe connected to the tubular portion 406h1 so as to communicate with the passage in the tubular portion 406h1, and outputs the detected pressure to the control device. The pressure detector 500 is also called a pressure sensor. Moreover, the structure provided so that the pressure detector 500 may detect the pressure in the cylindrical part 406h1 may be sufficient. The tubular portion 501 functions as a pressure detection port that protrudes outward from the tubular portion 406h1. The control device compares the pressure detection value detected by the pressure detector 500 with the normal pressure value stored in advance in the storage unit, and determines whether or not the current state is a failure state. Accordingly, it is possible to provide the control valve assembly 708 that enables determination of a failure state when a pressure fluctuation or pressure value different from that in the normal state is detected.

  Hereinafter, the site | part which provides the tubular part 501 about each embodiment is demonstrated. In the case of the first to fifth embodiments, the tubular portion 501 can be provided in the first part P1, the second part P2, the third part P3, and the fourth part P4. The first portion P1 corresponds to a flat plate-like portion that divides the first chamber 60 b in the inflow / outflow member 6, and the tubular portion 501 can be provided to protrude to the outside in the same manner as the inflow portion 63. The second portion P2 corresponds to the outflow side housing 6a, and the tubular portion 501 can be provided to protrude outward from the outflow side housing 6a. The third part P3 corresponds to a part of the outflow part 61 on the downstream side of the first check valve device 3, and the tubular part 501 can be provided so as to protrude from the outflow part 61 to the outside. The fourth part P4 corresponds to a part of the outflow part 62 on the downstream side of the second check valve device 5, and the tubular part 501 can be provided to protrude from the outflow part 62 to the outside.

  In the case of the sixth embodiment to the eighth embodiment, the tubular portion 501 can be provided in the first part P1 and the second part P2. The first portion P1 corresponds to the first tubular portion 406a, and the tubular portion 501 can be provided to project outside from the first tubular portion 406a. The second portion P2 corresponds to the outflow side housing 6a as in the first embodiment, and the tubular portion 501 can be provided to protrude outward from the outflow side housing 6a.

  In the case of the ninth embodiment, the tubular portion 501 can be provided in the first part P1, the second part P2, the third part P3, and the fourth part P4. The first portion P1 corresponds to the tubular portion 506a, and the tubular portion 501 can be provided so as to protrude outward from the tubular portion 506a. The second part P2, the third part P3, and the fourth part P4 are the same as those in the first embodiment.

  In the case of the tenth embodiment, the tubular portion 501 can be provided in the first part P1, the second part P2, the third part P3, and the fourth part P4. The first portion P1 corresponds to the tubular portion 606a, and the tubular portion 501 can be provided so as to protrude outward from the tubular portion 606a. The second part P2, the third part P3, and the fourth part P4 are the same as those in the first embodiment.

  In the case of the eleventh embodiment, the tubular portion 501 can be provided in the first part P1, the second part P2, and the third part P3. The first part P1, the second part P2, and the third part P3 are the same as those in the first embodiment.

  The control valve assembly disclosed in the fourteenth embodiment includes a pressure detection port for detecting the pressure of the evaporated fuel passage. According to this configuration, the pressure detector can be connected to, for example, the control valve assembly 708, so that the number of parts and assembly man-hours can be reduced as compared with the case where the pressure detector is installed on a member other than the control valve assembly. .

(Other embodiments)
The disclosure of this specification is not limited to the illustrated embodiments. The disclosure encompasses the illustrated embodiments and variations by those skilled in the art based thereon. For example, the disclosure is not limited to the combination of components and elements shown in the embodiments, and various modifications can be made. The disclosure can be implemented in various combinations. The disclosure may have additional parts that can be added to the embodiments. The disclosure includes those in which the components and elements of the embodiment are omitted. The disclosure encompasses parts, element replacements, or combinations between one embodiment and another. The technical scope disclosed is not limited to the description of the embodiments. The technical scope disclosed is indicated by the description of the scope of claims, and should be understood to include all modifications within the meaning and scope equivalent to the description of the scope of claims.

  The control valve assembly that can achieve the object disclosed in the specification is not only a device in which the housing 40, the intermediate member 41, and the inflow / outflow member are integrally coupled, but also the housing 40 and the inflow / outflow member directly. , Including a united configuration. In the case of this configuration, the housing 40 may include a valve seat 41b, or the inflow / outflow member may include a valve seat 41b.

  The control valve assembly that can achieve the object disclosed in the specification is not limited to the examples shown in the foregoing embodiments. Further, the components included in the control valve assembly are not limited to the examples shown in the above-described embodiments.

6, 106, 206, 306, 406, 506, 606, 706, 806 ... Inflow / outflow member 8, 108, 208, 308, 408, 508, 608, 708, 808, 908, 1008 ... Control valve assembly 16 ... Canister 22 ... Engine, 40 ... Housing, 41 ... Intermediate member 41e ... First passage (first opening), 42 ... Electromagnetic coil portion, 43 ... Valve body 45a ... Housing side chamber chamber, 60b ... First chamber (inflow passage) Exit part)
60c ... second chamber (inlet part of outflow passage), 60d ... partition part 63,163 ... inflow part, 61,62 ... outflow part 406a ... first cylindrical part (inflow part), 406e ... second cylindrical part ( Outflow part)
410: second passage (second opening), 506a1: upstream chamber chamber 506a, 606a ... cylindrical portion (inflow portion)

Claims (16)

A control valve assembly (8; 108; 208; 308; 408; 508; 608; 708; 808;) installed in an evaporative fuel passage through which evaporated fuel desorbed from the canister (16) flows toward the engine (22). 908; 1008)
A housing (40) having a built-in electromagnetic coil portion (42) for driving a valve body (43) for opening and closing a passage in the housing;
An inflow portion (63; 163; 406a; 506a; 606a) in which an inflow passage through which evaporated fuel flows toward the housing inner passage is formed, and an outflow passage in which an outflow passage through which the evaporated fuel flowing out from the housing passage flows is formed. An inflow member (6; 106; 206; 306; 406; 506; 606; 706; 806) connected to the housing;
With
The control valve assembly, wherein the outflow passage in the outflow portion and the inflow passage in the inflow portion are partitioned so as to communicate with each other via the in-housing passage.   A valve seat (41b) on which the valve body is seated; a first passage (41e) communicating with the inflow passage; and a second passage (410) communicating with the outflow passage; The control valve assembly according to claim 1, further comprising an intermediate member (41) interposed between the housing member and the housing and the inflow / outflow member. Inside the inflow / outflow member, an upstream chamber chamber (506a1) is provided between the inflow passage in the inflow / outflow member and the first passage in the intermediate member,
The control valve assembly according to claim 2, wherein the upstream chamber chamber has a passage cross-sectional area formed larger than each of the inflow passage and the first passage. Inside the housing, a housing-side chamber chamber (45a) is provided so that the first passage exists between the upstream-side chamber chamber,
The control valve assembly according to claim 3, wherein the housing-side chamber chamber has a passage cross-sectional area formed larger than that of the first passage. The inflow / outflow member includes a partition portion (60d) that partitions an outlet portion (60b) of the inflow passage and an inlet portion (60c) of the outflow passage,
The outlet portion of the inflow passage and one end side of the inner passage of the inflow passage are connected in accordance with the connection position around the axial center of the inflow / outflow member with respect to the housing, and the inlet portion of the outflow passage and the inner passage of the housing A first connection state connecting the other end side of the inflow passage, and the outlet portion of the inflow passage and the other end side of the in-housing passage to connect the inlet portion of the outflow passage and the one end of the in-housing passage. The partition part is provided in the member for inflow / outflow so that both the connection states of the 2nd connection state which connects the side can be implemented. Control valve assembly as described in. The inflow / outflow member is provided with a first chamber and a second chamber formed on both sides of the partition,
The control valve assembly according to claim 5, wherein the outlet portion of the inflow passage is opened in the first chamber, and the inlet portion of the outflow passage is opened in the second chamber.   The control valve assembly according to any one of claims 1 to 6, further comprising a tubular member (7) that is a separate component from the inflow / outflow member and is mounted on the outflow portion.   The inflow / outflow member is a separate part having an engaging portion (64) that can be attached to and detached from the inflow / outflow member and can be connected to a pipe. The canister side coupling member (406d) and the engine side The control valve assembly according to any one of claims 1 to 6, wherein the connecting member (406h; 406i; 406j) is connected. The engine side coupling member includes two tubular portions (406h2, 406h3) to which the pipe can be connected,
The control valve assembly according to claim 8, wherein the two tubular portions are provided at opposing positions. The engine side coupling member includes two tubular portions (406h2, 406h3) to which the pipe can be connected,
The control valve assembly according to claim 8, wherein the two tubular portions are provided so that passage axes intersect with each other.   The control valve assembly according to any one of claims 1 to 6, further comprising a check valve device (3) installed in the outflow passage formed in the outflow portion. The inflow / outflow member has a first outflow portion and a second outflow portion as the outflow portion,
A check valve device (3) installed inside the first outflow section;
A lid member (9) attached to the second outflow portion;
The control valve assembly according to any one of claims 1 to 6, further comprising: The inflow / outflow member has a first outflow portion and a second outflow portion as the outflow portion,
A first check valve device (3) installed inside the first outflow section;
A second check valve device (5) installed inside the second outflow part;
The control valve assembly according to any one of claims 1 to 6, further comprising: The inflow / outflow member has a first outflow portion and a second outflow portion as the outflow portion,
The first outflow portion and the second outflow portion are in an opposing relationship;
The control valve according to any one of claims 1 to 13, wherein the inflow portion extends in a direction intersecting with a facing direction in which the first outflow portion and the second outflow portion face each other. assembly. The inflow / outflow member has a first outflow portion and a second outflow portion as the outflow portion,
The first outflow portion and the second outflow portion are in an intersecting relationship extending in a direction intersecting each other,
The control valve assembly according to any one of claims 1 to 13, wherein the inflow portion extends along one of the first outflow portion and the second outflow portion.   The control valve assembly according to any one of claims 1 to 15, further comprising a pressure detection port (501) for detecting the pressure of the evaporated fuel passage.

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