JP2018204615A - Flow control valve - Google Patents

Abstract

To provide a flow control valve that can restrain unusual noise from occurring.SOLUTION: In an MCV 9, a housing 10 comprises a pair of supporting parts 34 and 34 for rotatably supporting an intermediate gear 31 via a bearing 33. The bearing 33 comprises a disc part 331 in which a cutout part 331a is formed, and a shaft part 332 for supporting the intermediate gear 31. The supporting parts 34 each comprises a rotation regulation part 342 in contact with the cutout part 331a in a direction around a rotation axis of the intermediate gear 31, and a hole part 343 into which the shaft part 332 is inserted.SELECTED DRAWING: Figure 6

Description

  The present invention relates to a flow control valve.

  Patent Document 1 discloses a flow control valve having a speed reduction mechanism that reduces the output of an electric motor and transmits it to a rotor. The speed reduction mechanism has a first gear fixed to the output shaft of the electric motor, a second gear fixed to the rotation shaft of the rotor, and an intermediate gear that transmits the rotation of the first gear to the second gear. The intermediate gear is supported at both ends thereof by a pair of support portions formed on a housing that accommodates the rotor. A washer is sandwiched between the intermediate gear and one support portion.

JP 2016-160872 A

However, in the above-described prior art, there is a problem that an abnormal noise called a “squeal” is generated on the sliding surface between the washer and the support portion when the washer is rotated around the intermediate gear. .
One of the objects of the present invention is to provide a flow control valve capable of suppressing the generation of abnormal noise.

  In the flow control valve according to the embodiment of the present invention, the housing has a pair of support portions that rotatably support the intermediate gear via the bearing, and the bearing includes a disc portion in which a notch portion is formed and an intermediate portion. A shaft portion that supports the gear, and the support portion includes a notch portion, a rotation restricting portion that abuts in a direction around the rotation axis of the intermediate gear, and a hole portion into which the shaft portion is inserted.

  Therefore, since the housing does not slide directly with the intermediate gear and the bearing, generation of abnormal noise can be suppressed.

1 is a schematic diagram of a cooling system 1 according to Embodiment 1. FIG. It is a perspective view of MCV9 of Embodiment 1. It is a disassembled perspective view of MCV9 of Embodiment 1. FIG. 3 is a plan view of MCV 9 (excluding the speed reduction mechanism 35 and the gear housing 36) of the first embodiment. It is a bottom view of MCV9 of Embodiment 1. FIG. 3 is a perspective view of a main part showing a support structure for an intermediate gear 31 in the first embodiment. FIG. 5A is a perspective view of an essential part showing a support structure of an intermediate gear 31 in Embodiment 1, and FIG. 5B is a sectional view of the essential part taken along line AA in FIG. FIG. 5A is a perspective view of a main part showing a support structure of an intermediate gear 31 in Embodiment 2, and FIG. 5B is a cross-sectional view of the main part taken along line AA in FIG. FIG. 5A is a perspective view of a main part showing a support structure of an intermediate gear 31 in Embodiment 3, and FIG. 5B is a cross-sectional view of the main part taken along line AA in FIG. FIG. 5A is a perspective view of a main part showing a support structure of an intermediate gear 31 in Embodiment 4, and FIG. 5B is a cross-sectional view of the main part taken along line AA in FIG.

Embodiment 1
FIG. 1 is a schematic diagram of a cooling system 1 according to the first embodiment.
In the cooling system 1 of the first embodiment, the cooling water (fluid) that has cooled the engine 2 that is a heat source is passed through a plurality of heat exchangers (the radiator 3, the transmission oil warmer 4, and the heater 5), and then the water pump 6 The circuit 7 for returning to the engine 2 through the The engine 2 is, for example, a gasoline engine mounted on a vehicle.
The radiator 3 cools the cooling water by heat exchange between the cooling water and the traveling wind. The transmission oil warmer 4 cools the cooling water by exchanging heat between the cooling water and the transmission oil. The transmission oil warmer 4 increases the temperature of the transmission oil when the engine 2 is cold, and functions as an oil cooler that cools the transmission oil after the engine 2 is warmed up. The heater 5 cools the cooling water by heat exchange between the cooling water and the blown air into the passenger compartment when the passenger compartment is heated.

The water pump 6 is rotationally driven by the driving force of the engine 2 and supplies cooling water from the radiator 3, the transmission oil warmer 4 and the heater 5 to the engine 2.
The circuit 7 includes a normally open channel 7a for bypassing the heat exchangers 3, 4, and 5 to constantly circulate cooling water. A water temperature sensor 8 for detecting the temperature (water temperature) of the cooling water is installed in the constantly open channel 7a.
A mechanical control valve (hereinafter referred to as MCV) 9 is a flow rate control valve that adjusts the flow rate of cooling water supplied from the engine 2 to each of the heat exchangers 3, 4, and 5. Details of MCV9 will be described later.
The engine control unit 101 controls the valve rotation angle of the MCV 9 based on the water temperature detected by the water temperature sensor 8, information from the engine 2 (engine negative pressure, throttle opening, etc.), and the like.

Next, the configuration of MCV9 will be described.
2 is a perspective view of the MCV 9 of the first embodiment, FIG. 3 is an exploded perspective view of the MCV 9, FIG. 4 is a plan view of the MCV 9 (excluding the speed reduction mechanism 35 and the gear housing 36), and FIG. 5 is a bottom view of the MCV 9.
The MCV 9 includes a housing 10, a drive mechanism 11, a rotor (valve element) 12, and a rotating shaft 13. Hereinafter, the x-axis is set in the direction along the rotation axis of the rotation shaft 13, and the direction from the drive mechanism 11 to the rotor 12 in the x-axis is the x-axis positive direction, and the opposite direction is the x-axis negative direction. Further, the radial direction of the x axis is referred to as a radial direction, and the direction around the x axis is referred to as a circumferential direction.

First, the configuration of the housing 10 will be described.
The housing 10 is formed by injection molding using, for example, a synthetic resin material. The housing 10 includes a base portion 14, a peripheral wall 15, a main communication port (introduction port) 16, a plurality of sub communication ports (discharge ports) 17, and a bearing portion 18. The base portion 14 has a substantially disk shape perpendicular to the x-axis direction. At the center of the base 14, the rotating shaft 13 penetrates in the x-axis direction. The peripheral wall 15 has a substantially cylindrical shape extending from the outer periphery of the base portion 14 toward the positive x-axis direction. The peripheral wall 15 has a tapered shape in which the inner diameter increases from the x-axis negative direction side toward the positive direction side. The inner peripheral side of the peripheral wall 15 is a substantially cylindrical space, and is a valve body accommodating portion that accommodates the rotor 12. The main communication port 16 is a circular opening formed at the x-axis positive direction end of the peripheral wall 15 (the x-axis positive direction end of the housing 10), and communicates with the valve body housing portion. The main communication port 16 connects between the water channel from the engine 2 and the valve body housing part. An O-ring 16 a is disposed on the outer periphery of the main communication port 16. The plurality of sub communication ports 17 are circular openings formed in the peripheral wall 15 and communicate with the valve body housing portion. The plurality of sub communication ports 17 are a first sub communication port, a second sub communication port 17b and a third sub communication port 17c which are not shown in the figure.

Outlets 20a, 20b, and 20c are fastened to the housing 10 by screws 19a, 19b, and 19c. O-rings 21a, 21b, and 21c are arranged between the outlets 20a, 20b, and 20c and the housing 10. The first outlet 20a connects between the first sub-communication opening and the water channel toward the heater 5. The second outlet 20b connects between the second sub-communication port 17b and the water channel toward the transmission oil warmer 4. The third outlet 20c connects the third sub-communication port 17c and the water channel toward the radiator 3.
The housing 10 is formed with a fourth sub communication port 17d. The fourth sub communication port 17d always communicates with the main communication port 16 regardless of the rotation angle of the rotor 12. A fourth outlet 20d, which is a pipe joint, is fixed to the outer side in the radial direction of the fourth sub communication port 17d. The fourth outlet 20d is fastened to the housing 10 with an O-ring 21d sandwiched between screws 19d. The fourth outlet 20d connects the fourth sub-communication port 17d and the normally open channel 7a. An O-ring 21d is disposed between the fourth outlet 20d and the housing 10.

The housing 10 is formed with a fifth sub-communication port 17e. The fifth sub-communication port 17e communicates with the fourth sub-communication port 17d and always communicates with the main communication port 16 regardless of the rotation angle of the rotor 12. In the third outlet 20c, a water channel (not shown) for connecting the fifth sub communication port 17e and the third sub communication port 17c is formed. A thermostat valve 22 is accommodated in this water channel. The thermostat valve 22 has a fail-safe function that opens when the water temperature becomes excessively high (for example, 100 degrees or more) and promotes cooling of the water temperature.
At the positive end of the housing 10 in the x-axis direction, there are three mounting holes 23 into which screws are inserted when the MCV 9 is fixed to the engine 2 with screws (not shown).

  The bearing portion 18 supports the rotary shaft 13 so as to be rotatable with respect to the housing 10. The bearing portion 18 is formed in a substantially cylindrical shape along the x-axis direction, and the x-axis negative direction end protrudes more toward the x-axis negative direction side than the x-axis negative direction end of the base portion 14. A through hole 18a through which the rotary shaft 13 passes is formed at the center of the bearing portion 18. The bearing portion 18 includes a radial thrust bearing 24, a dust seal 25, a liquid-tight seal 26, and a thrust bearing 27 in the through hole 18a. The radial thrust bearing 24 is positioned at the x-axis negative direction end of the bearing portion 18 and receives a radial force and a x-axis force from the rotary shaft 13. The dust seal 25 is located between the radial thrust bearing 24 and the liquid-tight seal 26 in the x-axis direction, and suppresses cooling water that has flowed into the bearing portion 18 from entering the drive mechanism 11. The liquid-tight seal 26 is located between the dust seal 25 and the thrust bearing 27 in the x-axis direction, and suppresses the outflow of cooling water from the valve body housing portion. The thrust bearing 27 is positioned at the positive end of the bearing portion 18 in the x-axis direction and receives a force in the x-axis direction from the rotary shaft 13.

Next, the configuration of the rotor 12 will be described.
The rotor 12 is accommodated in the valve body accommodating portion. The rotor 12 is formed using, for example, a synthetic resin material. The rotor 12 includes a bottom portion 38, an outer peripheral portion 39, a main opening portion 40, a plurality of sub-opening portions (opening portions) 41, and an extending portion 42. The bottom 38 is positioned at the x-axis negative direction end of the rotor 12 and is perpendicular to the x-axis direction. When viewed from the x-axis negative direction side, the bottom portion 38 has a shape in which a range of a little over 180 degrees in the donut shape is cut out leaving only the outer peripheral portion. The outer peripheral portion 39 has a substantially cylindrical shape extending from the outer periphery of the bottom portion 38 to the x-axis positive direction side. The outer peripheral portion 39 has a tapered shape in which the inner diameter increases from the x-axis negative direction side toward the positive direction side. A sliding bearing 44 is provided in the vicinity of the x-axis positive direction end of the peripheral wall 15 and closer to the x-axis negative direction side than the flange portion 39a.

  The plain bearing 44 rotatably supports the rotor 12 with respect to the housing 10. The plain bearing 44 receives a radial force from the rotor 12. The main opening 40 is a circular opening formed at the x-axis positive direction end of the outer peripheral portion 39 (the x-axis positive direction end of the rotor 12), and communicates with the main communication port 16. The plurality of sub-openings 41 are openings formed in the outer peripheral portion 39, and overlap each other when viewed from the radial direction with the corresponding sub-communication ports when the rotor 12 is in a predetermined rotation angle range. The corresponding secondary communication port and the main communication port 16 communicate with each other. The plurality of openings 41 are a first sub-opening 41a, a second sub-opening 41b, and a third sub-opening 41c. The first sub opening 41a corresponds to the first sub communication port. The second sub opening 41b corresponds to the second sub communication port 17b. The third sub opening 41c corresponds to the third sub communication port 17c. The second sub-opening 41b is always in communication with the fourth sub-communication port 17d and the fifth sub-communication port 17e regardless of the rotation angle of the rotor 12.

Next, each seal part 45,46,47 is demonstrated.
The first seal portion 45 is provided at the first sub communication port. The first seal portion 45 leaks cooling water from the first sub communication port to the gap between the peripheral wall 15 and the outer peripheral portion 39 in the radial direction when the first sub communication port communicates with the first sub opening 41a. Suppress. The first seal portion 45 includes a rotor seal 45a, an O-ring 45b, and a coil spring 45c. The rotor seal 45a has a cylindrical shape and is inserted into the first auxiliary communication port. The radially inner end of the rotor seal 45a contacts the outer peripheral portion 39. The O-ring 45b seals between the inner peripheral surface of the first sub communication port and the outer peripheral surface of the rotor seal 45a. The coil spring 45c is interposed between the rotor seal 45a and the first outlet 20a in a compressed state, and biases the rotor seal 45a inward in the radial direction.

  The second seal portion 46 is provided in the second sub communication port 17b. The second seal portion 46 is a cooling water that flows from the second sub communication port 17b to the gap between the peripheral wall 15 and the outer peripheral portion 39 in the radial direction when the second sub communication port 17b and the second sub opening 41b communicate. Suppresses leakage. The second seal portion 46 includes a rotor seal 46a, an O-ring 46b, and a coil spring 46c. The rotor seal 46a has a cylindrical shape and is inserted into the second auxiliary communication port 17b. The radially inner end of the rotor seal 46a contacts the outer peripheral portion 39. The O-ring 46b seals between the inner peripheral surface of the second auxiliary communication port 17b and the outer peripheral surface of the rotor seal 46a. The coil spring 46c is interposed in a compressed state between the rotor seal 46a and the second outlet 20b in the radial direction, and biases the rotor seal 46a radially inward.

  The third seal portion 47 is provided in the third sub communication port 17c. The third seal portion 47 is configured to provide cooling water from the third sub communication port 17c to the radial gap between the peripheral wall 15 and the outer peripheral portion 39 during communication between the third sub communication port 17c and the third sub opening 41c. Suppresses leakage. The third seal portion 47 includes a rotor seal 47a, an O-ring 47b, and a coil spring 47c. The rotor seal 47a has a cylindrical shape and is inserted into the third auxiliary communication port 17c. The radially inner end of the rotor seal 47a contacts the outer peripheral portion 39. The O-ring 47b seals between the inner peripheral surface of the third sub communication port 17c and the outer peripheral surface of the rotor seal 47a. The coil spring 47c is interposed between the rotor seal 47a and the third outlet 20c in the radial direction in a compressed state, and biases the rotor seal 47a inward in the radial direction.

Next, the configuration of the drive mechanism 11 will be described.
The drive mechanism 11 is positioned on the x-axis negative direction side of the base portion 14 and rotationally drives the rotary shaft 13. The drive mechanism 11 includes an electric motor (actuator) 29, a first cylindrical worm (first gear) 30, an intermediate gear 31, and a second worm wheel (second gear) 32.
The electric motor 29 is controlled by the engine control unit 101. The electric motor 29 is disposed along the x-axis direction, and is housed in the housing 10 with the distal end side of the output shaft 29a facing the x-axis negative direction side. The electric motor 29 is fastened to the housing 10 by two screws 19e. On the x-axis positive direction side of the electric motor 29, an annular vibration-proof rubber 29b is disposed.
The first cylindrical worm 30 is fixed to the output shaft 29a and rotates integrally with the output shaft 29a.
The intermediate gear 31 transmits the rotation of the first cylindrical worm 30 to the second worm wheel 32. The rotation axis of the intermediate gear 31 is disposed along a direction orthogonal to the x axis. The intermediate gear 31 includes a first worm wheel (third gear) 31a, a second cylindrical worm (fourth gear) 31b, and a pair of pins 31c and 31c on the outer periphery thereof. The first worm wheel 31 a meshes with the first cylindrical worm 30. The second cylindrical worm 31b meshes with the second worm wheel 32. A part of the pin 31c is press-fitted into insertion ports 31d formed at both axial ends of the intermediate gear 31, and rotates together with the intermediate gear 31. The pair of pins 31c, 31c are rotatably supported by a pair of support portions 34, 34 formed on the housing 10 via a pair of bearings 33, 33.

The second worm wheel 32 is fixed to the end of the rotary shaft 13 in the negative x-axis direction and rotates integrally with the rotary shaft 13.
The first cylindrical worm 30, the first worm wheel 31a, the second cylindrical worm 31b, and the second worm wheel 32 constitute a speed reduction mechanism 35 that reduces the rotational speed of the output shaft 29a and transmits it to the rotary shaft 13.
A magnet 13a is fixed to the end of the rotating shaft 13 in the negative x-axis direction. The first cylindrical worm 30, the intermediate gear 31, the second worm wheel 32, and the pair of bearings 33 and 33 are accommodated in a gear housing 36. The gear housing 36 is fastened to the housing 10 by four screws 19f. A seal member 36 a is disposed between the gear housing 36 and the housing 10. The gear housing 36 has an MR sensor (not shown). The MR sensor detects the rotation angle of the rotation shaft 13, that is, the rotation angle of the rotor 12 based on the change in the magnetic field accompanying the rotation of the rotation shaft 13. The rotation angle detected by the MR sensor is transmitted to the engine control unit 101.

Next, the support structure of the intermediate gear 31 by the pair of support portions 34, 34 will be described in detail with reference to FIGS.
6 is a perspective view of a main part showing a support structure of the intermediate gear 31 in the first embodiment, FIG. 7 is a view showing a support structure of the intermediate gear 31 in the first embodiment, and (a) is a perspective view of the main part. b) is a sectional view taken along the line AA in FIG.
The bearing 33 supports the intermediate gear 31 to be rotatable. The bearing 33 has a disk part (plate part) 331 and a shaft part 332. The disk portion 331 has a so-called D-cut shape in which the disk is cut out in a planar shape. The notched portion, that is, the straight portion extending in the direction perpendicular to the x-axis on the outer peripheral surface of the disk portion 331 becomes the notched portion (locking portion) 331a. The cutout portion 331a is located on the x-axis positive direction side with respect to the shaft portion 332. The disk portion 331 is disposed between the intermediate gear 31 and the support portion 34 in the rotation axis direction of the intermediate gear 31 (hereinafter referred to as the intermediate gear axis direction).
The shaft part 332 protrudes from the center of the disk part 331 toward the support part 34 side. The shaft portion 332 is formed in a cylindrical shape, and has a hole 332a passing through the shaft portion 332 and the disk portion 331 at the center thereof. A pin 31c of the intermediate gear 31 is inserted into the hole 332a so as to be rotatable about the rotation axis of the intermediate gear 31. The tip of the pin 31c has a tapered shape that tapers.

  The support portion 34 protrudes from the upper surface 14a, which is the surface of the base portion 14 on the x-axis negative direction side, to the x-axis negative direction side. The support portion 34 includes a flat plate portion 341, a rotation restricting portion 342, and a hole portion 343. The flat plate portion 341 has an inner side surface 34a and is formed in a flat plate shape. The flat plate portion 341 has reinforcing ribs 341a extending in the opposite direction to the intermediate gear 31 side on both sides when viewed from the axial direction of the intermediate gear. The rotation restricting portion 342 restricts the rotation of the bearing 33, and includes two restricting portions 342a and 342a. Both regulating portions 342a and 342a extend from the upper surface 14a to the x-axis negative direction side with a predetermined distance therebetween. Both regulating portions 342a, 342a are connected to the inner side surface 34a. That is, the rotation restricting portion 342 is processed at the same time as the injection molding of the housing 10. Both regulating portions 342a and 342a abut against the notch 331a in the x-axis direction in the vicinity of both ends in the length direction of the notch 331a. The hole portion 343 is a through hole formed in the flat plate portion 341, and the shaft portion 332 of the bearing 33 is inserted therein.

The housing 10 has a temporary placement portion 37 on the upper surface 14a. The temporary placement portion 37 is for placing the intermediate gear 31 when the pin 31c is press-fitted into the insertion port 31d of the intermediate gear 31. The temporary placement portion 37 has three support pieces 37a arranged in a spaced relationship between the pair of support portions 34, 34. Each support piece 37a is formed such that when the intermediate gear 31 is placed, the position of the intermediate gear 31 is slightly shifted (for example, several mm) toward the positive x-axis direction side from the position after assembly.
When the intermediate gear 31 is assembled to the housing 10, the bearing 33 is first attached to the support portion 34 from the inner side surface 34a side. Subsequently, the intermediate gear 31 is placed on the temporary placement portion 37. Next, the pair of pins 31c, 31c are inserted into the holes 332a of the bearings 33, 33. At this time, the outer peripheral surface (tapered surface) of the tip end of the pin 31c contacts the inner peripheral surface of the insertion port 31d of the intermediate gear 31, so that the intermediate gear 31 automatically moves to the position in the x-axis direction after assembly (automatic Alignment). That is, the assembly of the intermediate gear 31 is completed simply by pushing in the pair of pins 31c and 31c from both sides in the axial direction of the intermediate gear 31. Since the intermediate gear 31 is separated from the temporary placement portion 37 after the assembly, they do not interfere with each other.

Next, the effect of Embodiment 1 is demonstrated.
The conventional flow control valve has a structure in which the housing (support part) slides with the intermediate gear or washer. Therefore, when the intermediate gear rotates, so-called “sound noise” or sliding friction of the housing occurs. There was a problem that occurred.
In contrast, the MCV 9 of the first embodiment includes a pair of bearings 33 and 33 that rotatably support the intermediate gear 31 with respect to the pair of support portions 34 and 34. The bearing 33 includes a disk portion 331 in which a notch portion 331a is formed, and a shaft portion 332 that supports the intermediate gear 31. Further, the support portion 34 includes a notch portion 331a, a rotation restricting portion 342 that contacts in a direction around the rotation axis of the intermediate gear 31, and a hole portion 343 into which the shaft portion 332 is inserted.
Since the intermediate gear 31 is supported by the support portion 34 via the bearing 33, the intermediate gear 31 is not in contact with the support portion 34. In addition, the rotation of the bearing 33 in contact with the support portion 34 is restricted by the rotation restricting portion 342 with respect to the support portion 34. Therefore, since the support part 34 does not slide directly with the intermediate gear 31 and the bearing 33, generation of squealing noise when the intermediate gear 31 rotates can be suppressed, and sliding wear of the housing 10 can be prevented.

The rotation restricting portion 342 extends from the housing 10 in the negative x-axis direction and is formed integrally with the support portion 34. Thereby, since the rotation restricting portion 342 can be processed simultaneously with the molding of the housing 10, the productivity of the MCV 9 can be improved. Further, since the strength of the restricting portion 342a can be improved as compared with the case where both the restricting portions 342a and 342a are formed away from the support portion 34, the formability can be improved by thinning the restricting portions 342a and 342a. .
The support portion 34 has a reinforcing rib 341 a that connects to the housing 10. Thereby, the load resistance of the housing 10 against the axial load of the intermediate gear 31 can be improved.
The housing 10 includes a temporary placement portion 37 on which the intermediate gear 31 can be placed between the support portions 34 and 34. As a result, when the pair of pins 31c and 31c are press-fitted into the intermediate gear 31, neither the support of the intermediate gear 31 nor the alignment between the insertion port 31d and the hole 332a is required. It can be improved.
The output shaft 29a of the electric motor 29 and the rotation shaft 13 of the rotor 12 are arranged in parallel to each other along the x-axis direction, and the intermediate gear 31 is orthogonal to the rotation axis direction (x-axis direction) of the output shaft 29a and the rotation shaft 13 It is arranged along the direction. Thereby, compared with the case where the electric motor 29 and the rotor 12 are arrange | positioned non-parallel, size reduction of the radial direction of MCV9 (radial direction of the rotor 12) can be achieved.
The cutout portion 331a is formed by cutting out a part of the disc-like disc portion 331 in a planar shape. Thereby, the rotation of the disk portion 331 can be restricted with a simple configuration, and the wear of the housing 10 can be prevented.

[Embodiment 2]
Next, Embodiment 2 will be described. Since the basic configuration of the second embodiment is the same as that of the first embodiment, only portions different from the first embodiment will be described.
8A and 8B are diagrams showing a support structure for the intermediate gear 31 in the second embodiment, where FIG. 8A is a perspective view of the main part, and FIG. 8B is a cross-sectional view of the main part taken along line AA in FIG.
Both regulating portions 342a have a convex portion 342b. The convex part 342b protrudes from the x-axis negative direction end of the restricting part 342a contacting the notch part 331a to the x-axis negative direction side. The convex portion 342b is located on the opposite side to the support portion 34 side with respect to the disc portion 331 of the bearing 33, and abuts on the disc portion 331 in the intermediate gear axial direction.
The rotation restricting portion 342 of the second embodiment has a convex portion 342b that abuts the disk portion 331 of the bearing 33 in the intermediate gear axial direction and restricts the movement of the bearing 33 toward the intermediate gear 31 side. In the conventional flow control valve, the washer interposed between the intermediate gear and the housing (supporting portion) moves in the axial direction of the intermediate gear to become a vibration source. On the other hand, in the second embodiment, since the movement of the bearing 33 in the direction of the rotation axis is restricted, the vibration of the bearing 33 can be suppressed, and the generation of abnormal noise accompanying the vibration and the wear of the housing 10 can be reduced.

[Embodiment 3]
Next, Embodiment 3 will be described. Since the basic configuration of the third embodiment is the same as that of the first embodiment, only the differences from the first embodiment will be described.
9A and 9B are diagrams showing a support structure for the intermediate gear 31 according to the third embodiment, in which FIG. 9A is a perspective view of relevant parts, and FIG.
The bearing 33 has a shape in which a disk is cut out in a convex shape. The notched portion, that is, the portion of the outer peripheral surface of the disk portion 331, which is a combination of a straight portion extending in a direction perpendicular to the x axis and a straight portion extending parallel to the x axis, is a notched portion (locking portion) 331b. Become. Two cutout portions 331b are formed corresponding to both restriction portions 342a and 342a.
The cutout portion 331b of the third embodiment is formed by cutting out a part of the disc-shaped disc portion 331 into a convex shape. Thereby, the rotation of the disk portion 331 can be restricted with a simple configuration, and the wear of the housing 10 can be prevented.

[Embodiment 4]
Next, a fourth embodiment will be described. Since the basic configuration of the fourth embodiment is the same as that of the first embodiment, only the differences from the first embodiment will be described.
10A and 10B are diagrams showing a support structure of the intermediate gear 31 in the fourth embodiment, in which FIG. 10A is a perspective view of a main part, and FIG.
The bearing 33 has a shape in which a disk is cut out in a concave shape. The notched portion, that is, the portion of the outer peripheral surface of the disk portion 331, which is a combination of two straight portions extending in the direction perpendicular to the x axis and a semicircular arc portion connecting both straight portions, is a notched portion (locking Part) 331c.
The rotation restricting portion 342 extends from the upper surface 14a in the negative x-axis direction and is connected to the inner side surface 34a of the support portion 34. The rotation restricting portion 342 has a shape corresponding to the notch portion 331c and abuts the notch portion 331c in the x-axis direction.
The cutout portion 331c of the fourth embodiment is formed by cutting out a part of the disc-shaped disc portion 331 into a concave shape. Thereby, the rotation of the disk portion 331 can be restricted with a simple configuration, and the wear of the housing 10 can be prevented.

[Other Embodiments]
Although the embodiment for carrying out the present invention has been described above, the specific configuration of the present invention is not limited to the configuration of the embodiment, and there are design changes and the like within the scope not departing from the gist of the invention. Are also included in the present invention.
The shapes of the notch and the rotation restricting portion can be arbitrarily set as long as they are in contact with each other in the rotation direction of the intermediate gear and can regulate the rotation of the bearing.
The flow control valve of the present invention can be applied to other than the engine cooling water circulation system.

2 Engine
9 Flow control valve
10 Housing
12 Rotor (valve)
13 Rotating axis
16 Main communication port (introduction port)
17 Secondary communication port (discharge port)
29 Electric motor (actuator)
29a Output shaft
30 1st cylindrical worm (1st gear)
31 Intermediate gear
31a 1st worm wheel (3rd gear)
31b Second cylindrical worm (fourth gear)
32 Second worm wheel (second gear)
33 Bearing
34 Support section
35 Deceleration mechanism
37 Temporary storage
41 Sub-opening (opening)
331 Disc part (plate part)
331a Notch (locking part)
331b Notch (locking part)
331c Notch (locking part)
332 Shaft
341a Reinforcement rib
342 Rotation restriction part
342b Convex
343 hole

Claims (6)

A housing having an inlet through which a fluid is introduced and an outlet through which the introduced fluid is discharged;
A valve body that is rotatably supported in the housing and has an opening that changes a polymerization state with the discharge port according to the rotation angle;
An actuator that rotationally drives the output shaft;
A deceleration mechanism that decelerates the rotational speed of the output shaft and transmits it to the rotational shaft of the valve body;
With
The speed reduction mechanism includes a first gear fixed to the output shaft, a second gear fixed to the rotation shaft, and an intermediate gear that transmits the rotation of the first gear to the second gear. ,
The housing has a pair of support portions that rotatably support the intermediate gear via a bearing,
The bearing has a disk part in which a notch part is formed, and a shaft part that supports the intermediate gear,
The said support part is a flow control valve which has the rotation control part contact | abutted in the direction around the rotating shaft line of the said notch part and the said intermediate gear, and the hole part in which the said shaft part is inserted. The flow control valve according to claim 1,
The rotation restricting portion extends from the housing and is formed integrally with the support portion. The flow control valve according to claim 2,
The rotation restricting portion is a flow control valve having a convex portion that abuts the disk portion in the rotation axis direction and restricts movement of the bearing in the rotation axis direction. The flow control valve according to claim 1,
The said support part is a flow control valve which has a reinforcement rib connected with the said housing. A flow control valve for controlling a flow rate of fluid,
A valve body rotatably supported;
A housing for accommodating the valve body;
An actuator that rotationally drives the output shaft;
A deceleration mechanism that decelerates the rotational speed of the output shaft and transmits it to the rotational shaft of the valve body;
With
The speed reduction mechanism has an intermediate gear formed with a third gear meshing with a first gear fixed to the output shaft and a fourth gear meshing with a second gear fixed to the rotating shaft,
The housing has a pair of support portions that rotatably support the intermediate gear via a bearing,
The bearing includes a plate portion on which a locking portion is formed, and a shaft portion that supports the intermediate gear,
The said support part is a flow control valve which has the rotation control part which contact | abuts in the direction around the rotating shaft line of the said latching part and the said intermediate gear, and the hole part in which the said shaft part is inserted. The flow control valve according to claim 5,
The locking portion is a flow control valve formed by cutting out a part of the disk-shaped plate portion in a planar shape.

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