JP2004211865A - Flow regulating valve and hot-water supply system using it - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a flow regulating valve and a hot-water supply system where a seal function is given to the valve itself and flow controllability is increased. <P>SOLUTION: A valve body 7 is rotatably stored in a valve chamber 2 of a housing 1. A valve body retainer 11 supports a root side of a driving shaft 10 in water tightened state for valve body retainer 11 and rotatably around a hole center of the valve chamber 2. A valve body 16 for fluid introducing is arranged in a fluid introducing port 3 formed in the housing 1. The valve body 16 for fluid introducing is driven with revolution of a cam part 9a of a cam 9 for driving via a driving rod 16 to adjust the introducing amount of the fluid. An overlapping degree of an opening 8a formed at a cylinder 8 and a fluid discharge port 4 formed at the housing 1 is changed by revolution of the valve body 7 to adjust the discharge amount of the fluid. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
INDUSTRIAL APPLICABILITY The present invention is used in an oil supply circuit of an electric water heater, a water heater using gas, oil or the like as a heat source, and is applied to mix hot water and water to obtain hot water at a predetermined temperature. And a hot water supply device using the same.
[0002]
[Prior art]
In a conventional flow control valve, a cylindrical valve chamber having one end having a hot and cold water discharge port is formed in a housing, and a water inlet and a hot water inlet are separated from each other in a direction toward a center of a hole in the valve chamber to communicate the valve chamber with the outside. The cylindrical valve body is rotatably housed in the valve chamber around the center of the hole of the valve chamber, and a first opening communicating the water inlet and the valve chamber is formed in the valve body. A second opening communicating with the hot water inlet and the valve chamber is provided in the valve body. When the valve body is rotated in one direction around the center of the hole of the valve chamber, the first opening and the second opening overlap (opening ratio) between the first opening and the water inlet. Is changed from the fully closed state to the fully open state, whereas the positional relationship between the second opening and the hot water inlet (opening ratio) is changed from the fully opened state to the fully closed state. Then, the mixing ratio of the water introduced from the water inlet and the hot water introduced from the hot water inlet is adjusted by rotating the valve body, and the hot water at the set temperature is discharged from the hot water outlet. (For example, see Patent Document 1)
[0003]
[Patent Document 1]
JP-A-2002-22039 (FIG. 1)
[0004]
[Problems to be solved by the invention]
Since the conventional flow control valve is configured as described above, a minute clearance exists between the valve chamber and the valve element. Therefore, even if the overlapping state between the first opening and the water inlet is in the fully closed state, a flow path from the water inlet to the hot water outlet through the space between the valve chamber and the valve element is formed. Similarly, even when the degree of overlap between the second opening and the hot water inlet is in the fully closed state, a flow path from the hot water inlet to the hot water outlet through the space between the valve chamber and the valve element is formed. As a result, there is a problem that the discharge of the fluid cannot be completely stopped by the valve alone.
[0005]
The present invention has been made in order to solve the above-mentioned problems, and an object of the present invention is to provide a flow control valve having a valve itself having a sealing function to improve flow controllability and a hot water supply device using the same.
[0006]
[Means for Solving the Problems]
A flow regulating valve according to the present invention is provided with a valve chamber having a circular cross section having an opening at one end in a hole center direction, and communicating the valve chamber with the outside in a direction orthogonal to the hole center direction of the valve chamber. A fluid inlet, a fluid outlet provided to be shifted toward the hole center of the valve chamber with respect to the fluid inlet and to communicate the valve chamber with the outside in a direction orthogonal to the hole center of the valve chamber. And a housing having a valve seat disposed at the fluid introduction port, a cylindrical portion, a driving cam and a driving shaft are formed coaxially, and the driving shaft is extended from an opening of the valve chamber to enter the valve chamber. The drive cam is accommodated rotatably around the center of the hole of the valve chamber, the opening is formed in the cylindrical portion in accordance with the position of the flow rate outlet, and the cam portion is in conformity with the position of the fluid inlet. A valve body formed so as to gradually increase the height from the axis around the axis of the valve; A valve body retainer attached to the opening of the jig in a watertight state, the valve body retainer supporting the valve body rotatably around the center of the hole of the valve chamber while maintaining the watertight state at the root side of the drive shaft, and the fluid introduction port. A seal member disposed so as to be able to reciprocate in a direction perpendicular to the hole center direction of the valve chamber, and in contact with a seat surface of the valve seat to secure a watertight state, and the valve chamber in contact with an outer peripheral surface of the cam portion. And a fluid introduction valve body having a drive rod for receiving a drive force in a direction orthogonal to the hole center direction.
[0007]
Further, the flow control valve according to the present invention is provided with a valve chamber having a circular cross section having an opening at one end in the hole center direction, and communicating the valve chamber with the outside in a direction orthogonal to the hole center direction of the valve chamber. The first fluid introduction port is shifted from the first fluid introduction port toward the hole center of the valve chamber so that the valve chamber communicates with the outside in a direction orthogonal to the hole center direction of the valve chamber. A second fluid inlet provided, a fluid outlet provided to communicate the other end of the valve chamber with the outside, a first valve seat provided at the first fluid inlet, and the second fluid A housing having a second valve seat disposed at the inlet, a cylindrical portion, a second drive cam, a first drive cam, and a drive shaft are formed coaxially, and the drive shaft extends from the opening of the valve chamber. And is housed in the valve chamber so as to be rotatable around the center of a hole in the valve chamber. A valve body formed around the axis of the first and second driving cams so as to gradually increase the height from the axis in accordance with the position of the second flow introduction port; A valve body retainer mounted in a watertight state, supporting the valve body rotatably around the center of the hole of the valve chamber while maintaining the watertight state at the root side of the drive shaft; A first seal member disposed to be reciprocally movable in a direction perpendicular to a center direction of the hole of the valve chamber and in contact with a first seat surface of the first valve seat to ensure a watertight state; and an outer peripheral surface of the first cam portion. A first fluid-introducing valve body having a first drive rod that receives a driving force in a direction perpendicular to the hole center direction of the valve chamber in contact with the first fluid-introducing hole; The second valve seat is disposed so as to be able to reciprocate in the direction in which A second seal member for ensuring the state and a second fluid introduction valve body having a second drive rod which is in contact with the outer peripheral surface of the second cam portion and receives a drive force in a direction perpendicular to the hole center direction of the valve chamber. It has.
[0008]
Further, a hot water supply apparatus according to the present invention uses the above-mentioned flow rate adjusting valve.
[0009]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
Embodiment 1 FIG.
FIG. 1 is a cross-sectional view illustrating the configuration of the flow control valve according to Embodiment 1 of the present invention, and FIG. 2 is a process cross-sectional view illustrating the operation of the flow control valve according to Embodiment 1 of the present invention.
[0010]
In FIG. 1, a housing 1 is a resin molded product obtained by, for example, injection-molding polyphenylene sulfide (PPS) resin. A valve chamber 2 having a circular cross section is formed so as to open one end, and a fluid inlet 3 is formed in the hole. The center is made perpendicular to the center of the hole of the valve chamber 2 so that the opening side of the valve chamber 2 communicates with the outside, and the fluid discharge port 4 is further formed so that the center of the hole is made orthogonal to the center of the hole of the valve chamber 2. It is drilled so that the bottom side of the valve chamber 2 communicates with the outside. A large-diameter opening 2 a is formed at one end of the valve chamber 2.
The valve seat 5 is a resin molded product formed by, for example, injection molding PPS resin. The valve seat 5 is supported by a cylindrical portion having a seat surface 5a formed on one end side and a plurality of ribs extending radially from the cylindrical portion. And a cylindrical guide part 5b provided at the center of the hole of the part. The valve seat 5 is attached to the valve chamber 2 side of the fluid inlet 3 in a watertight state with an O-ring 6 interposed.
[0011]
The valve body 7 is a resin molded product formed by, for example, injection molding PPS resin, and is integrally formed by a cylindrical portion 8 and one end of the cylindrical portion 8 supported by a plurality of ribs extending in a radial direction. 9 and a drive shaft 10 integrally formed at one end of the drive cam 9. The cylindrical portion 8, the driving cam 9 and the driving shaft 10 are formed coaxially. Further, a cam portion 9 a is formed on the outer peripheral surface of the driving cam 9 around the axis of the drive shaft 10. The cam portion 9a is formed so that the height of the outer peripheral surface from the axis of the drive shaft 10 gradually increases counterclockwise around the axis of the drive shaft 10.
The cylindrical portion 8 has an outer diameter substantially equal to the inner diameter of the valve chamber 2, and an opening 8 a having the same shape as the fluid discharge port 4 is formed in the outer peripheral surface.
[0012]
The valve body 7 is inserted into the valve chamber 2 such that the cylindrical portion 8 is located at the bottom of the valve chamber 2. An annular valve body retainer 11 made of, for example, a resin molded product obtained by injection molding PPS resin is press-fitted and fixed to the opening 2a of the valve chamber 2 through the drive shaft 10 through the opening 11a. As a result, the valve element 7 is attached to the housing 1 so as to be rotatable around the center of the hole of the valve chamber 2 and restricted from moving in the direction of the center of the hole of the valve chamber 2. At this time, the positions of the fluid discharge port 4 and the opening 8a in the hole center direction of the valve chamber 2 coincide.
[0013]
An O-ring 12 is interposed between the inner wall surface of the opening 2a of the valve chamber 2 and the outer wall surface of the valve body retainer 11, and the O-ring 13 is provided between the inner wall surface of the opening 11a of the valve body retainer 11 and the drive shaft. It is interposed between the base 10 and the base, and a watertight state is ensured. Since the valve body retainer 11 corresponds to a bearing of the valve body 7, two O-rings 13 are arranged apart from each other in the axial direction.
Further, washers 14 and 15 are interposed between the bottom of the valve chamber 2 and the bottom of the cylindrical portion 8 and between the driving cam 9 and the valve body retainer 11, respectively. These washers 14 and 15 are made of a material having low frictional resistance, such as ethylene tetrafluoride resin, to reduce the frictional resistance when the valve element 7 rotates.
[0014]
Further, the fluid introduction valve body 16 is a resin molded product obtained by, for example, injection molding PPS resin, and a disc-shaped valve portion 16a and a drive rod 16b provided upright at the center of the valve portion 16a are integrally formed. An O-ring 17 as a sealing member is formed on the outer peripheral surface of the valve portion 16a. The fluid introduction valve element 16 is disposed so that the drive rod 16b is inserted into the guide portion 5b of the valve seat 5 and extends into the valve chamber 2, and the drive rod 16b is guided by the guide portion 5b. The fluid inlet 3 can be reciprocated within the fluid inlet 3 toward the center of the hole of the fluid inlet 3. Then, the O-ring 17 comes into close contact with the seat surface 5a of the valve seat 5, and a watertight state is ensured. At this time, the positions of the fluid inlet 3 and the cam portion 9a in the hole center direction of the valve chamber 2 coincide with each other. That is, the positions of the drive rod 16b and the cam portion 9a in the hole center direction of the valve chamber 2 coincide with each other.
Further, a screw hole 18 for attaching a stepping motor (not shown) to the housing 1 is formed on one end surface of the housing 1.
[0015]
Next, the operation of the flow control valve 100 thus configured will be described with reference to FIG.
First, in FIG. 2A, the drive rod 16b of the fluid introduction valve body 16 is not in contact with the cam portion 9a, and the fluid introduction valve body 16 is opened by the pressure of the fluid in the fluid introduction port 3. The O-ring 17 is pressed to the chamber 2 side, and the O-ring 17 comes into close contact with the seat surface 5a of the valve seat 5, so that the watertight state is maintained. At this time, the opening 8 a is located at a position facing the fluid discharge port 4 with the hole center of the valve chamber 2 interposed therebetween.
[0016]
Next, the drive shaft 10 is rotated counterclockwise around the axis of the valve body 7 (the center of the hole of the valve chamber 2) by the stepping motor. Then, the cam portion 9a comes into contact with the drive rod 16b, and the drive rod 16b is moved in a direction away from the valve chamber 2. As a result, as shown in FIG. 2B, the O-ring 17 separates from the seat surface 5a, and the watertight state is broken. At this time, the opening 8a is at a position that does not overlap with the fluid discharge port 4. Then, the fluid is introduced into the valve chamber 2 from the fluid inlet 3, reaches the fluid outlet 4 through a slight clearance formed between the valve chamber 2 and the cylindrical portion 8, and is discharged from the fluid outlet 4. Is done. The discharge of this fluid is very small.
[0017]
When the drive shaft 10 is rotated counterclockwise around the axis of the valve body 7 by the stepping motor, the drive rod 16b is moved further away from the valve chamber 2 and is moved from the fluid inlet 3 to the valve chamber. The area of the opening of the flow path to 2 increases. In addition, as shown in FIG. 2C, the opening 8a partially overlaps with the fluid outlet 4. Therefore, the fluid introduced into the valve chamber 2 from the fluid inlet 3 is discharged from the inside of the cylindrical portion 8 through the overlapping portion of the opening 8 a and the fluid outlet 4 from the fluid outlet 4.
[0018]
Further, when the drive shaft 10 is rotated counterclockwise around the axis of the valve body 7 by the stepping motor, the drive rod 16b is moved further away from the valve chamber 2, and the drive rod 16b is moved from the fluid inlet 3 to the valve chamber. The area of the opening of the flow path to 2 is maximized. Further, as shown in FIG. 2D, the opening 8a completely overlaps with the fluid discharge port 4. That is, the degree of overlap (opening ratio) between the opening 8a and the fluid discharge port 4 is maximized. Then, the fluid introduced from the fluid inlet 3 into the valve chamber 2 is discharged from the fluid outlet 4 from the inside of the cylindrical portion 8 through the opening 8a.
[0019]
As described above, in the flow control valve 100, the degree of overlap (opening ratio) between the opening 8a and the fluid discharge port 4 can be arbitrarily adjusted by rotating the valve body 7 around the center of the hole of the valve chamber 2. The amount of fluid discharged from the fluid discharge port 4 can be controlled.
Further, since the O-ring 17 mounted on the fluid introduction valve element 16 can freely contact and separate from the seat surface 5a of the valve seat 5 disposed at the fluid introduction port 3, the O-ring 17 can be connected to the seat surface 5a. Can completely prevent the fluid from being introduced into the valve chamber 2. Therefore, it is not necessary to newly provide a component such as a solenoid valve in order to prevent the fluid from flowing out to the fluid discharge port 4 side, that is, the secondary side, so that the circuit is simplified and the cost is reduced. .
[0020]
Further, since the valve body 7 composed of the cylindrical portion 8, the driving cam 9 and the driving shaft 10 is made of a resin-molded product as one body, the number of parts is reduced and the assemblability of the flow control valve 100 is improved. And cost reduction.
Further, since the housing 1, the valve seat 5, the valve element 7, the valve element holder 11, and the fluid introduction valve element 16 are made of resin, cost reduction and weight reduction can be achieved. In addition, since these components are resin molded products obtained by injection molding a resin, the dimensional accuracy of the components is ensured. As a result, it is not necessary to perform post-processing such as performing cutting or the like on the component to keep the shape and dimensions of the component within tolerance, thereby achieving cost reduction.
[0021]
In the first embodiment, the valve element 7 is rotated counterclockwise to perform the operation from the fluid sealing state to the full opening of the flow rate. However, the valve element 7 is rotated clockwise. Then, the operation may be performed from the sealed state of the fluid to the full opening of the flow rate. In this case, the height of the outer peripheral surface of the cam portion 9a from the axis of the drive shaft 10 may be gradually increased clockwise around the axis of the drive shaft 10.
In the first embodiment, the fluid inlet 3 is located on the opening side of the valve chamber 2 and the fluid outlet 4 is located on the bottom side of the valve chamber 2. The fluid outlet 4 and the fluid outlet 4 may be formed at positions separated from each other in the direction of the center of the hole of the valve chamber 2. For example, the fluid inlet 3 is located on the bottom side of the valve chamber 2, and the fluid outlet 4 is connected to the valve chamber 2. 2 may be located on the opening side.
Further, in the first embodiment, the cylindrical portion 8, the driving cam 9, and the driving shaft 10 that constitute the valve body 7 are formed integrally with a resin molded product, but the cylindrical portion 8, the driving cam 9 are formed. Alternatively, the drive shaft 10 may be manufactured as a separate component, and these components may be assembled to form the valve body 7.
[0022]
Embodiment 2 FIG.
In the second embodiment, the flow control valve 100 according to the first embodiment is applied to an instant boiling water heater.
FIG. 3 is a circuit diagram showing a circuit configuration of an instant boiling water heater according to Embodiment 2 of the present invention.
In FIG. 3, a water source pipe 39 is connected to a heating path 40 via a water amount sensor 41, and the heating path 40 is connected from the water amount sensor 41 to the fluid inlet 3 of the first flow control valve 100 </ b> A, and includes a combustor 43. A heat exchanger 42 is provided in the heating path 40. Further, the bypass path 44 branches off from the water flow sensor 41 side of the heating path 40 and is connected to the first flow control valve 100A side of the heating path 40. The second flow control valve 100 </ b> B is disposed in the bypass 44. The first and second flow control valves 100A and 100B are the flow control valves 100 according to the first embodiment, and the stepping motor 45 is fastened and fixed to each housing 1 using the screw holes 18. The hot water supply pipe 46 is connected to the fluid discharge port 4 of the first flow control valve 100A. Further, a solenoid valve 47 for controlling hot water supply is arranged in the path of the hot water supply pipe 46.
[0023]
In addition, a water temperature sensor 48 is disposed on the water path sensor 41 side of the heating path 40, a hot water temperature sensor 49 is disposed downstream of the heat exchanger 42 of the heating path 40, and a mixed hot water temperature sensor 50 is disposed on the hot water supply pipe 46. It is arranged downstream of the first flow control valve 100A. The control device 51 controls the driving of the stepping motor 45 based on the output signals from the water temperature sensor 48, the hot water temperature sensor 49, and the mixed hot water temperature sensor 50, so that the first and second flow control valves 100A, 100B Drive control. The stepping motor 45 operates by a certain angle with respect to one input pulse.
Further, an additional-burning burner 52, a bathtub 53, a motor 54, and a tap 55 for a kitchen faucet or shower are connected to a hot water supply pipe 46.
[0024]
The operation of the thus configured hot water supply device will be described.
The controller 51 monitors the water temperature at each position based on output signals from the water temperature sensor 48, the hot water temperature sensor 49, and the mixed hot water temperature sensor 50.
When the set hot water temperature Ts is set from the outside, the control device 51 performs arithmetic processing based on the rotation angle of each stepping motor 45 and the total water amount Qs detected by the water amount sensor 41 to execute the heating path 40. The flow rate Qh flowing and the flow rate Qc flowing in the bypass path 44 are calculated, and the set temperature Ths after heating by the heating path 40 is set. Next, the heating amount Q is calculated from the flow rate Qh, the detected water temperature Tc of the water temperature sensor 48, and the set temperature Ths, and the combustor 43 is driven based on the calculated heating amount Q. Heat the water flowing through 40. Then, the combustor 43 is controlled so that the detected hot water temperature Th of the hot water temperature sensor 49 becomes the set temperature Ths.
Further, a target value of the flow rate flowing through the bypass passage 44 is calculated by performing arithmetic processing based on the flow rate Qh, the hot water temperature Th, the water temperature Tc, and the set temperature Ts, and the mixed hot water temperature Tm detected by the mixed hot water temperature sensor 50 is set. Feedback control of the second flow control valve 100B is performed so that the temperature Ts falls within a preset deviation. That is, the opening degree of the second flow control valve 100B is adjusted by changing the rotation angle of the stepping motor 45 so that the mixed hot water temperature Tm falls within a preset deviation from the set temperature Ts. When the mixed hot water temperature Tm falls within a preset deviation from the set temperature Ts, the opening degree of the second flow control valve 100B is maintained.
[0025]
When the set temperature Ts is high and the capacity of the combustor 43 is insufficient, the opening degree of the first flow control valve 100A is reduced to reduce the total flow rate Qs, thereby setting the mixed hot water temperature Tm. The temperature Ts falls within the set deviation. Then, hot water at the set temperature Ts is supplied to the bathtub 53 and the tap hole 55.
When the temperature of the hot water supplied to the bathtub 53 decreases, the motor 54 is driven to circulate the hot water in the bathtub 53 and ignite the reheating burner 52 to maintain the hot water in the bathtub 53 at a desired temperature. .
[0026]
As described above, according to the second embodiment, a water heater with excellent temperature controllability can be obtained.
[0027]
Embodiment 3 FIG.
4 is a cross-sectional view illustrating the configuration of a flow control valve according to Embodiment 3 of the present invention, FIG. 5 is a process cross-sectional view illustrating the operation of the flow control valve according to Embodiment 3 of the present invention, and FIG. FIG. 9 is a diagram for explaining flow characteristics of a flow control valve according to Embodiment 3 of the present invention.
[0028]
In FIG. 4, a housing 20 is a resin molded product obtained by, for example, injection molding PPS resin. A valve chamber 21 having a circular cross section is formed so as to open one end, and a fluid discharge port 22 has a smaller diameter than the valve chamber 21. The other end of the valve chamber 21 is communicated with the outside through the communication hole 23. An opening 21 a having a larger diameter than the valve chamber 21 is formed at one end of the valve chamber 21. The opening 21a, the valve chamber 21, the communication hole 23, and the fluid outlet 22 are formed coaxially.
In the housing 20, a first fluid inlet 24 is bored so that the center of the hole is orthogonal to the center of the hole of the valve chamber 21 so that the opening 21a side of the valve chamber 21 communicates with the outside. The two-fluid inlet 25 is formed so that the center of the hole is orthogonal to the center of the hole of the valve chamber 21 so that the fluid outlet 22 of the valve chamber 2 communicates with the outside.
[0029]
The first valve seat 26 is a resin molded product obtained by, for example, injection molding PPS resin. The first valve seat 26 includes a cylindrical portion having a first seat surface 26a formed on one end side and a plurality of ribs extending radially from the cylindrical portion. And a first cylindrical guide portion 26b supported at the center of the hole of the cylindrical portion. The first valve seat 26 is attached to the valve chamber 21 side of the first fluid inlet 24 with the O-ring 6 interposed therebetween in a watertight state. The second valve seat 27 is a resin molded product obtained by, for example, injection molding PPS resin. The second valve seat 27 has a cylindrical portion having a second seat surface 27a formed on one end side and a plurality of radially extending portions formed on the cylindrical portion. And a cylindrical second guide portion 27b supported by the rib and provided at the center of the hole of the cylindrical portion. The second valve seat 27 is attached to the second fluid inlet 25 on the valve chamber 21 side with the O-ring 6 interposed therebetween in a watertight state.
[0030]
The valve body 28 is a resin molded product formed by, for example, injection molding PPS resin, and is formed integrally with a cylindrical portion 29 supported by a plurality of radially extending ribs at one end of the cylindrical portion 29. Cam 30, a first drive cam 31 integrally formed at one end of the second drive cam 30, and a drive shaft 32 integrally formed at one end of the first drive cam 31. . The cylindrical portion 29, the second drive cam 30, the first drive cam 31, and the drive shaft 32 are formed coaxially. A second cam portion 30 a is formed on the outer peripheral surface of the second drive cam 30 around the axis of the drive shaft 32. The second cam portion 30a is formed so that the height of the outer peripheral surface from the axis of the drive shaft 32 gradually increases counterclockwise around the axis of the drive shaft 32. A first cam portion 31 a is formed on the outer peripheral surface of the first driving cam 31 around the axis of the drive shaft 32. The first cam portion 31a is formed so that the height of the outer peripheral surface from the axis of the drive shaft 32 gradually increases counterclockwise around the axis of the drive shaft 32. Here, the height of the first cam portion 31a from the axis of the drive shaft 32 is minimized when the height of the second cam portion 30a from the axis of the drive shaft 32 is maximum, and the height of the second cam portion 31a is small. The second cam portion 30a is offset around the axis of the drive shaft 32 so that the height of the drive shaft 30a from the axis of the drive shaft 32 becomes minimum when the height becomes minimum.
[0031]
The valve body 28 is inserted into the valve chamber 21 such that the cylindrical portion 29 is located at the bottom of the valve chamber 21. An annular valve body retainer 33 of a resin molded product formed by, for example, injection molding PPS resin is press-fitted and fixed to the opening 21a of the valve chamber 21 through the drive shaft 32 through the opening 33a. Thereby, the valve body 28 is attached to the housing 20 so as to be rotatable around the center of the hole of the valve chamber 21 and the movement of the valve chamber 21 in the direction of the center of the hole is regulated.
[0032]
The O-ring 12 is interposed between the inner wall surface of the opening 21 a of the valve chamber 21 and the outer wall surface of the valve body retainer 33, and the O-ring 13 is provided between the inner wall surface of the opening 33 a of the valve body retainer 33 and the drive shaft. 32 are interposed between the base portion and the base portion 32, and a watertight state is ensured.
Since the valve body retainer 33 corresponds to a bearing of the valve body 28, the two O-rings 13 are disposed apart from each other in the axial direction.
Washers 14 and 15 are interposed between the bottom of the valve chamber 21 and the bottom of the cylindrical portion 29, and between the first driving cam 31 and the valve body retainer 33, respectively. These washers 14 and 15 are made of a material having low frictional resistance, such as ethylene tetrafluoride resin, to reduce the frictional resistance when the valve body 28 rotates.
[0033]
The first fluid introduction valve body 34 is a resin molded product obtained by, for example, injection molding PPS resin. The first fluid introduction valve body 34 has a disc-shaped first valve portion 34a and a first valve portion 34a provided at the center of the first valve portion 34a. The first drive rod 34b is integrally formed, and the O-ring 17 as a first seal member is mounted on the outer peripheral surface of the first valve portion 34a. The first fluid introduction valve element 34 is inserted into the first fluid introduction port 24 so that the first drive rod 34b is inserted into the first guide portion 26b of the first valve seat 26 and extends into the valve chamber 21. The first drive rod 34b is provided so as to be guided by the first guide portion 26b so as to be able to reciprocate toward the center of the hole of the first fluid introduction port 24. Then, the O-ring 17 comes into close contact with the first seat surface 26a of the first valve seat 26, and a watertight state is ensured. At this time, the positions of the first fluid inlet 24 and the first cam portion 31a in the hole direction of the valve chamber 21 coincide with each other. That is, the positions of the first drive rod 34b and the first cam portion 31a in the hole center direction of the valve chamber 21 match.
[0034]
The second fluid introduction valve body 35 is a resin molded product obtained by, for example, injection molding PPS resin. The second fluid introduction valve body 35 has a disc-shaped second valve portion 35a and a second valve portion 35a provided at the center of the second valve portion 35a. The second drive rod 35b is integrally formed, and the O-ring 17 as a second seal member is mounted on the outer peripheral surface of the second valve portion 35a. The second fluid introduction valve body 35 is inserted into the second fluid introduction port 25 so that the second drive rod 35b is inserted into the second guide portion 27b of the second valve seat 27 and extends into the valve chamber 21. The second drive rod 35b is provided so as to be guided by the second guide portion 27b so as to reciprocate toward the center of the hole of the second fluid introduction port 25. Then, the O-ring 17 comes into close contact with the second seat surface 27a of the second valve seat 27, and a watertight state is ensured. At this time, the positions of the second fluid introduction port 25 and the second cam portion 30a in the hole center direction of the valve chamber 21 match. That is, the positions of the second drive rod 35b and the second cam portion 30a in the hole center direction of the valve chamber 21 match.
Further, a screw hole 18 for attaching a stepping motor (not shown) to the housing 20 is formed on one end surface of the housing 1.
[0035]
Next, the operation of the flow control valve 101 thus configured will be described with reference to FIG.
First, in FIG. 5A, the first drive rod 34b of the first fluid introduction valve body 34 is not in contact with the first cam portion 31a, and the first fluid introduction valve body 34 is in the first fluid introduction state. The O-ring 17 is pressed against the first seat surface 26a of the first valve seat 26 by the pressure of the fluid in the inlet 24 toward the valve chamber 21, and the watertight state is maintained. That is, the flow path from the first fluid introduction port 24 to the valve chamber 21 is in a fully closed state. On the other hand, the second drive rod 35b of the second fluid introduction valve body 35 is in contact with the second cam portion 30a, and the O-ring 17 separates from the second seat surface 27a of the second valve seat 27, and is in a watertight state. Has been destroyed. At this time, the height of the second cam portion 30a from the center of the hole of the valve chamber 21 is maximum, and the opening area of the flow path from the second fluid inlet 24 to the valve chamber 21 is maximum (full open state). Has become. Thereby, the second fluid is introduced into the valve chamber 21 from the second fluid inlet 24 and is discharged from the fluid outlet 22.
[0036]
Next, the drive shaft 32 is rotated counterclockwise around the axis of the valve body 28 (the center of the hole of the valve chamber 21) by the stepping motor. Then, the first cam portion 31a comes into contact with the first drive rod 34b, and the first drive rod 34b is moved in a direction away from the valve chamber 21. As a result, as shown in FIG. 5B, the O-ring 17 separates from the first sheet surface 26a, and the watertight state is broken. On the other hand, the height of the second cam portion 30a from the center of the hole of the valve chamber 21 is reduced, and the second drive rod 35b of the second fluid introduction valve body 35 moves the second fluid in the second fluid introduction port 25. The pressure is pressed to the valve chamber 21 side, and the opening area of the flow path from the second fluid introduction port 25 to the valve chamber 21 decreases. As a result, the first fluid introduced from the first fluid inlet 24 into the valve chamber 21 and the second fluid introduced from the second fluid inlet 25 into the valve chamber 21 are mixed, and the fluid is discharged from the fluid outlet 22. Is discharged.
[0037]
Then, when the drive shaft 32 is rotated counterclockwise around the axis of the valve body 28 by the stepping motor, as shown in FIG. 5C, a hole in the valve chamber 21 of the first cam portion 31a is formed. The height from the center further increases, and the height of the second cam portion 30a from the center of the hole of the valve chamber 21 further decreases. Then, the first drive rod 34b of the first fluid introduction valve body 34 moves in a direction away from the center of the hole of the valve chamber 21 by the driving force of the first cam portion 31a, and the first drive rod 34b moves from the first fluid introduction port 24 to the valve chamber. The opening area of the flow path to 21 further increases. On the other hand, the second drive rod 35b of the second fluid introduction valve body 35 moves in a direction approaching the center of the hole of the valve chamber 21 due to the pressure of the second fluid, and the second drive rod 35b moves from the second fluid introduction port 25 to the valve chamber 21. The opening area of the flow path is further reduced. As a result, the first fluid introduced from the first fluid inlet 24 into the valve chamber 21 and the second fluid introduced from the second fluid inlet 25 into the valve chamber 21 are mixed, and the fluid is discharged from the fluid outlet 22. Is discharged.
[0038]
Further, when the drive shaft 32 is rotated counterclockwise around the axis of the valve body 28 by the stepping motor, the hole of the valve chamber 21 of the first cam portion 31a is formed as shown in FIG. The height from the center becomes the maximum, and the height from the hole center of the valve chamber 21 of the second cam portion 30a becomes the minimum. Then, the first driving rod 34b of the first fluid introduction valve body 34 further moves in the direction away from the center of the hole of the valve chamber 21 by the driving force of the first cam portion 31a, and the valve is moved from the first fluid introduction port 24 to the valve. The opening area of the flow path to the chamber 21 is maximized. On the other hand, the second drive rod 35b of the second fluid introduction valve body 35 moves in the direction approaching the center of the hole of the valve chamber 21 due to the pressure of the second fluid, and the O-ring 17 is pressed against the second seat surface 27a. Then, the flow path from the second fluid introduction port 25 to the valve chamber 21 is in a fully closed state. Thereby, only the first fluid introduced into the valve chamber 21 from the first fluid inlet 24 is discharged from the fluid outlet 22.
[0039]
As described above, in the flow control valve 101, the flow path from the first fluid inlet 24 to the valve chamber 21 is completely closed by rotating the valve body 28 counterclockwise around the center of the hole of the valve chamber 21. The state transitions from the state to the fully open state, and the flow path from the second fluid inlet 25 to the valve chamber 21 moves from the fully open state to the fully closed state. As a result, the flow rate of the first fluid flowing into the valve chamber 21 from the first fluid inlet 24 increases as the rotation angle of the valve body 28 increases, as shown in FIG. As shown in FIG. 6B, the flow rate of the second fluid flowing from the fluid inlet 25 into the valve chamber 21 decreases as the rotation angle of the valve body 28 increases. As a result, the flow control valve 101 operates as a mixing valve that can control the mixing ratio of the first and second fluids by adjusting the rotation angle of the valve body 28.
[0040]
Further, since the O-ring 17 mounted on the first fluid introduction valve element 34 can freely contact and separate from the first seat surface 26a of the first valve seat 26 disposed on the first fluid introduction port 24. , The O-ring 17 is brought into contact with the first seat surface 26a, whereby the introduction of the first fluid into the valve chamber 21 can be completely prevented. Similarly, the O-ring 17 mounted on the second fluid introduction valve body 35 can freely contact and separate from the second seat surface 27a of the second valve seat 27 provided on the second fluid introduction port 25. Therefore, by bringing the O-ring 17 into contact with the second seat surface 27a, the introduction of the second fluid into the valve chamber 21 can be completely prevented. Therefore, it is not necessary to newly provide a component such as a solenoid valve in order to prevent the first and second fluids from flowing out to the valve chamber 21, so that the circuit is simplified and the cost is reduced.
[0041]
Further, since the valve body 28 composed of the cylindrical portion 29, the second drive cam 30, the first drive cam 31, and the drive shaft 32 is made of a resin-molded product as an integral body, the number of parts is reduced, The assemblability of the flow control valve 101 is improved, and the cost is reduced.
Further, since the housing 20, the first and second valve seats 26 and 27, the valve body 28, the valve body retainer 33, the first fluid introduction valve body 34, and the second fluid introduction valve body 35 are made of resin, a low Cost and weight are reduced. In addition, since these components are resin molded products obtained by injection molding a resin, the dimensional accuracy of the components is ensured. As a result, it is not necessary to perform post-processing such as performing cutting or the like on the component to keep the shape and dimensions of the component within tolerance, thereby achieving cost reduction.
[0042]
In the third embodiment, the height of the first cam portion 31a from the axis of the drive shaft 32 is minimum when the height of the second cam portion 30a from the axis of the drive shaft 32 is maximum. The height of the second cam portion 30a from the axis of the drive shaft 32 is maximized when the height is minimum, but the axis of the drive shaft 32 of the first cam portion 31a is maximized. Is maximum when the height of the second cam portion 30a from the axis of the drive shaft 32 is maximum, and the height of the second cam portion 30a from the axis of the drive shaft 32 is minimum. It may be formed so as to be minimized when it becomes necessary. In this case, the flow rates of the first and second fluids to the valve chamber 21 become zero at the same time and simultaneously become maximum. Thus, the same effect as that of the flow control valve 100 according to the first embodiment can be obtained for two types of fluids. Furthermore, various flow characteristics can be obtained by appropriately setting the shapes and arrangements of the first and second cam portions 30a and 31a.
[0043]
In the third embodiment, the cylindrical portion 29, the second drive cam 30, the first drive cam 31, and the drive shaft 32 that constitute the valve body 28 are integrally formed of a resin molded product. The cylindrical portion 29, the second drive cam 30, the first drive cam 31, and the drive shaft 32 may be manufactured as separate parts, and these parts may be assembled to form the valve body 28.
In the third embodiment, the first and second fluid introduction ports 24 and 25 are provided. However, if the positions of the fluid introduction ports are shifted from each other in the direction of the center of the hole of the valve chamber 21, the fluid introduction ports are provided. May be three or more. In such a configuration, the flow rates of three or more kinds of fluids can be independently adjusted. In this case, the driving cams are provided on the valve body in accordance with the number of the fluid introduction ports.
[0044]
Embodiment 4 FIG.
In the fourth embodiment, the flow rate adjusting valve 101 according to the third embodiment is applied to a hot water supply device of a hot water storage type.
FIG. 7 is a circuit diagram showing a circuit configuration of a hot water supply type hot water supply apparatus according to Embodiment 4 of the present invention.
In FIG. 7, a water source pipe 60 is connected to first and second introduction paths 62 and 63 via a pressure reducing valve 61 for reducing the water source water pressure. The first introduction path 62 is connected to the first fluid introduction port 24 of the first and second flow control valves 101A and 101B, and the second introduction path 63 is connected to the first and second flow control valves via a hot water storage tank 64. It is connected to the second fluid inlet 25 of 101A and 101B. Then, a first hot water supply pipe 65 to which a tap 55 such as a faucet or a shower is connected is connected to the fluid discharge port 22 of the first flow control valve 101A, and the additional heating burner 52, the bathtub 53, the motor 54 and the like are connected. The second hot water supply pipe 66 is connected to the fluid discharge port 22 of the second flow control valve 101B. The first and second flow control valves 101A and 101B are the flow control valves 101 according to the third embodiment, and the stepping motor 45 is fastened and fixed to each housing 20 using the screw holes 18. An electromagnetic valve 47 for controlling hot water supply is disposed in the path of the second hot water supply pipe 66.
[0045]
Further, a water temperature sensor 67 is provided in the first introduction path 62, a hot water temperature sensor 68 is provided downstream of the hot water storage tank 64 in the first introduction path 63, and a first mixed hot water temperature sensor 69 is provided in the first hot water supply pipe. A second mixed hot water temperature sensor 70 is provided downstream of the solenoid valve 47 of the second hot water supply pipe 66. Then, the control device 71 controls the drive of the stepping motor 45 based on the output signals from the water temperature sensor 67, the hot water temperature sensor 68, and the first and second mixed hot water temperature sensors 69 and 70, and the first and second The flow control valves 101A and 101B are driven and controlled. Further, the water amount sensors 41 are disposed downstream of the first flow control valve 101A of the first hot water supply pipe 65 and downstream of the second flow control valve 101B of the second hot water supply pipe 66, respectively.
[0046]
The operation of the thus configured hot water supply device will be described.
The controller 71 monitors the water temperature at each position based on the output signals from the water temperature sensor 67, the hot water temperature sensor 68, and the first and second mixed hot water temperature sensors 69 and 70, and outputs the output signal from the water amount sensor 41. The flow rate of the mixed hot water flowing through the first and second hot water supply pipes 65 and 66 is monitored based on the above. Then, the water introduced from the water source pipe 60 into the hot water storage tank 64 via the pressure reducing valve 61 and the second introduction path 63 is heated to a predetermined temperature by a heating means (not shown) such as a burner.
[0047]
Then, when the first set hot water temperature Ts1 is set from the outside, the control device 71 detects the rotation angle of the stepping motor 45 of the first flow rate adjustment valve 101A, and the water temperature Tc detected by the water temperature sensor 67 and Water introduced into the valve chamber 21 from the first fluid inlet 24 for introducing the first set hot water temperature Ts1 by performing arithmetic processing based on the hot water temperature Th detected by the hot water temperature sensor 68 and the second fluid are introduced. The target value of the flow ratio with the hot water introduced into the valve chamber 21 from the port 25 is calculated. Next, based on the target value of the flow ratio, the stepping motor 45 of the first flow control valve 101A is rotationally driven to rotate the valve body 28. As a result, water and hot water are introduced into the valve chamber 21 at a predetermined flow rate ratio, and are discharged as a mixed hot water from the fluid discharge port 22. Next, the stepping motor 45 is feedback-controlled such that the mixed hot water temperature Tm1 detected by the first mixed hot water temperature sensor 69 falls within a preset deviation from the first set temperature Ts1. When the temperature of the mixed hot water Tm1 falls within a predetermined deviation from the first set temperature Ts1, the rotation angle of the stepping motor 45 is maintained. Thereby, hot water of the first set temperature Ts1 is supplied from the tap hole 55.
[0048]
Further, when the second set hot water temperature Ts2 is set from the outside, the control device 71 detects the rotation angle of the stepping motor 45 of the second flow rate regulating valve 101B, and the water temperature Tc detected by the water temperature sensor 67 and Water to be introduced into the valve chamber 21 from the first fluid inlet 24 for introducing the second set hot water temperature Ts2 through the arithmetic processing based on the hot water temperature Th detected by the hot water temperature sensor 68 and the second fluid are introduced. The target value of the flow ratio with the hot water introduced into the valve chamber 21 from the port 25 is calculated. Next, based on the target value of the flow ratio, the stepping motor 45 of the second flow control valve 101B is driven to rotate, and the valve body 28 is rotated.
As a result, water and hot water are introduced into the valve chamber 21 at a predetermined flow rate ratio, and are discharged as a mixed hot water from the fluid discharge port 22. Next, the stepping motor 45 is feedback-controlled so that the mixed hot water temperature Tm2 detected by the second mixed hot water temperature sensor 70 falls within a predetermined deviation from the second set temperature Ts2. Then, when the mixed hot water temperature Tm2 falls within a preset deviation from the second set temperature Ts2, the rotation angle of the stepping motor 45 is maintained. Thereby, hot water at the second set temperature Ts2 is supplied to the bathtub 53.
[0049]
Thus, according to the fourth embodiment, it is possible to obtain a hot water supply apparatus which is excellent in temperature controllability and can simultaneously supply hot water having different temperatures.
[0050]
In each of the above embodiments, the housing 1, 20, the valve seat 5, the first and second valve seats 26, 27, the valve bodies 7, 28, the valve body pressers 11, 33, the fluid introducing valve body 16, Although the first fluid introduction valve body 34 and the second fluid introduction valve body 35 are made of PPS resin, the material of these parts is not limited to PPS resin, and the required specifications of the flow rate regulating valve are It suffices to have satisfactory heat resistance and mechanical strength, such as polyolefin resins such as polyethylene and polypropylene, polyvinyl chloride resins, aliphatic polyamide resins such as nylon 6, nylon 66, and polyphthalamide. Aromatic polyamide resin, polyester resin such as polyethylene terephthalate and polybrylene terephthalate, polymethylene resin, polyetheretherketone resin , A crystalline resin such as a fluororesin, a polystyrene resin, a polycarbonate resin, a polysulfone resin, a polyethersulfone resin, a polyphenylene ether resin, a polyallelic resin, a polyamideimide resin, a polyetherimide resin, and acrylonitrile -Amorphous resins such as styrene resins and acrylonitrile-styrene-butadiene resins, and liquid crystal polymers such as aromatic polyester resins and aromatic polyesteramide resins can be used. Further, a resin containing a filler such as an alloy or a glass fiber may be used.
Further, a metal such as a bronze casting material can be used.
Here, in the flow control valve of this type, since the maximum temperature of the hot water is 80 to 90 ° C., a heat resistance of 100 ° C. is required. In terms of strength, fatigue strength against pressure rise due to water hammer is required, and specifically, mechanical strength capable of withstanding 1,000,000 times of repetition at a pressure amplitude of 17.5 atm is required. For this reason, it is desirable to use, as a material of each component, a material obtained by reinforcing the above-described resin material with glass fibers (weight percentage of glass fibers is 10 to 40%).
[0051]
【The invention's effect】
As described above, the present invention provides a valve chamber having a circular cross section having an opening at one end in the hole center direction, provided so as to communicate the valve chamber with the outside in a direction orthogonal to the hole center direction of the valve chamber. A fluid discharge port provided in such a manner as to be displaced in the direction of the hole center of the valve chamber with respect to the fluid inlet and to communicate the valve chamber with the outside in a direction perpendicular to the hole center of the valve chamber A housing having an outlet and a valve seat disposed at the fluid inlet, a cylindrical portion, a drive cam and a drive shaft are formed coaxially, and the drive shaft is extended from an opening of the valve chamber to form the valve chamber. The valve chamber is rotatably housed around a hole center of the valve chamber, an opening is formed in the cylindrical portion in accordance with the position of the flow rate outlet, and a cam portion is formed in the cylindrical portion in accordance with the position of the fluid inlet. A valve body formed around the axis of the cam so as to gradually increase the height from the axis; A valve body retainer attached to an opening of the housing in a watertight state, the valve body retainer supporting the valve body rotatably around a hole center of the valve chamber while maintaining a watertight state at the root side of the drive shaft; A seal member disposed so as to be able to reciprocate in a direction perpendicular to the hole center direction of the valve chamber, and in contact with a seat surface of the valve seat to secure a watertight state, and the valve chamber in contact with an outer peripheral surface of the cam portion. And a fluid introduction valve body having a driving rod for receiving a driving force in a direction orthogonal to the hole center direction, so that the valve itself has a sealing function and a new side for preventing fluid outflow to the secondary side. A simple flow rate control valve with improved flow controllability can be obtained.
[0052]
A valve chamber having a circular cross section having an opening at one end in the hole center direction, a first fluid inlet provided to communicate the valve chamber with the outside in a direction orthogonal to the hole center direction of the valve chamber; A second fluid inlet provided to shift the valve chamber toward the center of the hole of the valve chamber with respect to the first fluid inlet and to communicate the valve chamber with the outside in a direction orthogonal to the center of the hole of the valve chamber; A fluid outlet provided to communicate the other end of the valve chamber with the outside, a first valve seat provided at the first fluid inlet, and a second valve provided at the second fluid inlet. A housing having a valve seat, a cylindrical portion, a second drive cam, a first drive cam, and a drive shaft are formed coaxially, and the drive shaft extends from an opening of the valve chamber, and the valve is inserted into the valve chamber. The first and second cam portions are rotatably housed around the center of the hole of the chamber so that the first and second cam portions are aligned with the positions of the first and second flow introduction ports, respectively. A valve body formed around the axis of the first and second drive cams so as to gradually increase the height from the axis, and a water-tightly attached to an opening of the housing, A valve body retainer for supporting the valve body rotatably around the center of the hole of the valve chamber while maintaining a watertight state at the root side of the valve body; and the first fluid introduction port being perpendicular to the hole center direction of the valve chamber. A first seal member disposed to be reciprocally movable in a direction, in contact with a first seat surface of the first valve seat to secure a watertight state, and a hole center of the valve chamber in contact with an outer peripheral surface of the first cam portion. A first fluid introduction valve body having a first drive rod for receiving a drive force in a direction perpendicular to the direction, and a second fluid introduction port disposed reciprocally in a direction perpendicular to a hole center direction of the valve chamber. And a second seal member that contacts a second seat surface of the second valve seat to secure a watertight state. And a second fluid introduction valve body having a second drive rod which is in contact with the outer peripheral surface of the second cam portion and receives a drive force in a direction perpendicular to the center of the hole of the valve chamber. , A new member for preventing the outflow of fluid is not required on the secondary side, and an inexpensive flow control valve with improved flow control and operating as a mixing valve can be obtained.
[Brief description of the drawings]
FIG. 1 is a cross-sectional view illustrating a configuration of a flow control valve according to Embodiment 1 of the present invention.
FIG. 2 is a process cross-sectional view for explaining the operation of the flow control valve according to Embodiment 1 of the present invention.
FIG. 3 is a circuit diagram showing a circuit configuration of an instant boiling water heater according to Embodiment 2 of the present invention.
FIG. 4 is a cross-sectional view illustrating a configuration of a flow control valve according to Embodiment 3 of the present invention.
FIG. 5 is a process sectional view illustrating an operation of the flow control valve according to Embodiment 3 of the present invention.
FIG. 6 is a diagram illustrating flow characteristics of a flow control valve according to Embodiment 3 of the present invention.
FIG. 7 is a circuit diagram showing a circuit configuration of an instant boiling water heater according to Embodiment 4 of the present invention.
[Explanation of symbols]
Reference Signs List 1 housing, 2 valve chamber, 2a opening, 3 fluid inlet, 4 fluid outlet, 5 valve seat, 5a seat surface, 7 valve body, 8 cylindrical portion, 8a opening, 9 driving cam, 9a cam portion, 10 Drive shaft, 11 valve body holding, 16 fluid introduction valve body, 16b drive rod, 17 O-ring (seal member, first seal member, second seal member), 20 housing, 21 valve chamber, 21a opening, 22 fluid Discharge port, 24 first fluid inlet, 25 second fluid inlet, 26 first valve seat, 26a first seat surface, 27 second valve seat, 27a second seat surface, 28 valve body, 29 cylindrical portion, 30 2nd drive cam, 30a 2nd cam part, 31 1st drive cam, 31a 1st cam part, 34 1st fluid introduction valve body, 34b 1st drive rod, 35 2nd fluid introduction valve body, 35b Second drive rod.

Claims (6)

A valve chamber having a circular cross section having an opening at one end in the hole center direction, a fluid introduction port provided to communicate the valve chamber with the outside in a direction orthogonal to the hole center direction of the valve chamber, The fluid outlet and the fluid inlet are provided so as to be shifted toward the hole center of the valve chamber and communicate with the valve chamber and the outside in a direction orthogonal to the center of the hole of the valve chamber. A housing having a valve seat;
A cylindrical portion, a drive cam and a drive shaft are formed coaxially, and the drive shaft is extended from an opening of the valve chamber and housed in the valve chamber so as to be rotatable around a center of a hole of the valve chamber. Is formed on the cylindrical portion in accordance with the position of the flow outlet, and the cam portion is gradually increased in height from the axis around the axis of the driving cam in accordance with the position of the fluid inlet. A valve body formed on the
A valve body retainer attached to the opening of the housing in a watertight state, supporting the valve body rotatably around a hole center of the valve chamber while maintaining a watertight state at the root side of the drive shaft,
The fluid introduction port is disposed so as to be able to reciprocate in a direction orthogonal to the hole center direction of the valve chamber, and is in contact with a seal member that contacts a seat surface of the valve seat to ensure a watertight state and an outer peripheral surface of the cam portion. And a fluid introduction valve body having a driving rod for receiving a driving force in a direction perpendicular to a center direction of the hole of the valve chamber. A valve chamber having a circular cross section having an opening at one end in the hole center direction, a first fluid introduction port provided to communicate the valve chamber with the outside in a direction orthogonal to the hole center direction of the valve chamber; A second fluid inlet provided to shift the valve chamber toward the center of the hole of the valve chamber with respect to the fluid inlet and to communicate the valve chamber with the outside in a direction orthogonal to the center of the hole of the valve chamber; A fluid outlet provided to communicate the other end of the chamber with the outside, a first valve seat provided at the first fluid inlet, and a second valve seat provided at the second fluid inlet A housing having
The cylindrical portion, the second driving cam, the first driving cam, and the driving shaft are formed coaxially, and the driving shaft extends from the opening of the valve chamber and is turned around the center of the hole of the valve chamber into the valve chamber. The first and second cams are movably housed, and the heights of the first and second driving cams are set around the axes of the first and second driving cams in accordance with the positions of the first and second flow introduction ports, respectively. And a valve body formed so as to gradually increase
A valve body retainer attached to the opening of the housing in a watertight state, supporting the valve body rotatably around a hole center of the valve chamber while maintaining a watertight state at the root side of the drive shaft,
A first seal member disposed at the first fluid inlet so as to be able to reciprocate in a direction orthogonal to the hole center direction of the valve chamber, and in contact with a first seat surface of the first valve seat to ensure a watertight state; A first fluid introduction valve body having a first drive rod which is in contact with an outer peripheral surface of the first cam portion and receives a drive force in a direction orthogonal to a hole center direction of the valve chamber;
A second seal member disposed at the second fluid inlet so as to be able to reciprocate in a direction perpendicular to the center direction of the hole of the valve chamber, and in contact with a second seat surface of the second valve seat to ensure a watertight state; A second fluid introduction valve body having a second drive rod which is in contact with the outer peripheral surface of the second cam portion and receives a drive force in a direction perpendicular to the hole center direction of the valve chamber. Flow control valve. 3. The flow regulating valve according to claim 1, wherein the valve element is formed integrally. 4. The flow control valve according to claim 1, wherein the housing, the valve body, the valve body retainer, and the fluid introduction valve body are resin molded products. 4. The flow rate according to claim 2, wherein the housing, the valve body, the valve body retainer, the first fluid introduction valve body, and the second fluid introduction valve body are resin molded products. Regulating valve. A hot water supply apparatus comprising the flow control valve according to any one of claims 1 to 5.

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