JPH10197067A - Flow rate regulating device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve the responsiveness in controlling the flow rate by making a control so that the regulation of the passing degree of opening by a regulating means and the operation by an operating means. SOLUTION: A control circuit is provided with a storage function part to store the relationship between the turning angle 44 of the water pressure to be detected corresponding to the reference value and the water flow rate 75. The control circuit is provided with a relationship operating function part to operate the relationship between the flow rate 75 corresponding to the arbitrary detected water pressure and the turning angle 44 based on the stored relationship. Various curves to express the relationship between the turning angle 44 corresponding to the arbitrary water pressure, for example, 0.3MP and 0.5MP and the flow rate 75 are obtained by the operation by the relationship operating function part. Based on the relationship between the turning angle 44 and the flow rate 75, the turning angle 44 corresponding to the set flow rate at the converted water pressure is operated. The turning angle 44 of a motor is regulated so as to be the operated turning angle 44. The degree of opening is regulated, and the responsiveness in regulating the water quantity in the start is improved.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

TECHNICAL FIELD The present invention relates to a flow control device,
In particular, the present invention relates to a flow rate adjusting device that adjusts the flow rate of the fluid in a pipeline through which the fluid passes.

[0002]

2. Description of the Related Art FIG. 9 is an explanatory view of a conventional water amount adjusting device (9). The water amount adjusting device (9) shown in the figure is built in a hot water supply device (not shown), and a water amount adjusting valve (9a) provided in a water supply line (not shown) of the hot water supply device, Control circuit (9b) that controls the water volume adjustment operation with the water volume adjustment valve (9a)
And consisting of

The water quantity control valve (9a) comprises a valve body (91) which is movably held in the axial direction, and a drive section (92) for moving the valve body (91). Have been. The valve body described above
The distance between the valve element (91) and the valve port (95) by the movement of (91),
That is, the opening is adjusted, and the flow rate of water passing through the water supply pipe is adjusted. Also, the valve body (91) in the water flow control valve (9a)
The impeller (9
3) is located. And, on the constituent wall of the flow path,
A signal output unit that detects the number of revolutions of the impeller (93) and outputs a signal
(94) is installed. These impeller (93) and signal output section
(94) constitutes a flow sensor.

In this apparatus, when an operation switch (not shown) of the water heater is turned on, an electromagnetic valve (not shown) provided in the water supply line is opened, or
The hot water tap (not shown) is opened, and the water in the water supply conduit starts to flow toward the downstream side. In this state the impeller
Since (93) rotates, the flow rate of water flowing through the water supply pipe line is detected. After that, the valve body (91) that has initially been on standby at the maximum opening is driven in the closing direction (to the valve opening (95) side) to reduce the opening. As a result, the flow rate of water in the water supply conduit decreases, and the flow rate detected by the flow rate sensor decreases. Then, when the detected flow rate matches the preset flow rate, the driving is stopped. As a result, the flow rate of water in the water supply conduit matches the set flow rate.

After that, the flow rate of water in the water supply line, that is, the detected flow rate may differ from the set flow rate due to fluctuations in water pressure in the water supply line.
In this case, the valve body (91) is driven in the closing direction or the opening direction to adjust the opening. If the detected flow rate is made to match the set flow rate by this adjustment, the flow rate of water in the water supply pipe will be the same as the set flow rate again.

Further, when changing the set flow rate while water is passing through the water supply conduit, the flow rate of water in the water supply conduit is adjusted in the same manner as described above. The above control is executed by the control circuit (9b).

[0007]

However, in this conventional technique, a sudden change in the water pressure in the water supply pipe or the like causes a problem.
Turbulence may occur in the flow path in the water amount control valve (9a). In this case, the rotation of the impeller (93) becomes unstable due to the turbulent flow, and it takes time until the rotation is stabilized by the convergence of the turbulent flow. This causes a time lag until the detected flow rate detected via the impeller (93) reaches an accurate value that matches the flow rate of water in the water supply conduit. Even if the control circuit (9b) has a function of averaging the variations of the output pulse from the signal output section (94) to calculate the flow rate, the variation in rotation during the turbulent flow is higher than usual. Is significantly large, the calculation takes time, and the time lag occurs.

Further, during the turbulent flow, the rotation of the impeller (93) tends to deviate from the rotation corresponding to the flow rate due to the inertial force of the impeller (93), and this also causes the time lag. . Therefore, in this one, the water flow control valve (9a)
There was a problem that the responsiveness of the water amount control in was poor.

[0009] It is an object of the present invention to provide a flow control device with improved responsiveness of flow control. On the other hand, in this conventional technique, after the solenoid valve is opened and the passage of water in the water supply conduit is started, by narrowing the valve body (91) from the maximum opening degree based on the detected flow rate, The flow rate of water in the water supply line is made to match the set flow rate. Therefore, it takes time from the time when the passage is started until the opening degree of the valve body (91) is narrowed down to the opening degree corresponding to the set flow rate.

In addition, even at the beginning of the passage,
Turbulent flow occurs in the flow path inside the water flow control valve (9a), and the rotation of the impeller (93) becomes unstable. Accordingly, it takes time until the detected flow rate becomes an accurate value, and the completion of the narrowing-down operation of the valve element (91) is delayed. Therefore, in this device, the flow rate of water in the water supply pipe line at the beginning is larger than the set flow rate. Thereby, in this water heater,
The supply amount of water with respect to the heating amount becomes excessive, and the rise time until the temperature of the hot water discharged from the hot water supply device reaches the set temperature becomes long.

It is an object of the present invention to provide a flow rate adjusting device which improves the responsiveness of flow rate control at the start of passage of a fluid.

[0012]

The object of the present invention is to provide a flow rate adjusting device for adjusting the flow rate of the fluid in a pipe through which the fluid passes, wherein the flow rate adjusting device sets the flow rate to be passed. Setting means, a pressure detecting means for detecting the pressure of the fluid at a predetermined position in the pipeline, and a passage opening degree of the fluid in the pipeline which is provided in a part of the pipeline Adjusting means, an opening degree detecting means for detecting the passage opening degree, and a flow rate of the fluid passing through the pipe line is calculated based on a detected pressure of the pressure detecting means and a detected opening degree of the opening degree detecting means. Computing means and control means for controlling such that the adjustment of the passage opening degree by the adjusting means and the computation by the computing means are repeated so that the calculated flow rate becomes the set flow rate by the setting means. To provide ".

In this case, the flow rate to be passed through the pipeline is set by the setting means. Further, the flow rate of the fluid passing through the pipeline is calculated by the calculating means based on the detected pressure of the pressure detecting means and the detected opening degree of the opening degree detecting means. Then, the adjustment of the passage opening by the adjusting means and the calculation by the calculating means are repeated so that the flow rate calculated by the control means becomes the flow rate set by the setting means. By this control, the flow rate of the fluid passing through the pipe line matches the set flow rate.

Here, as in the invention of claim 2, "the arithmetic means stores the relationship between the passage opening and the flow rate corresponding to the reference pressure of the detected pressure, and the storage means. A relationship calculating means for calculating a relationship between the flow rate and the passage opening corresponding to any of the detected pressures based on the relationship. Included is an opening degree calculating means for calculating the passage opening degree corresponding to the set flow rate at the detected pressure. "

In this configuration, the storage means stores the relationship between the passage opening and the flow rate corresponding to the reference pressure of the detected pressure. Then, the relation calculating means calculates the relation between the flow rate and the passage opening corresponding to the arbitrary detected pressure based on the stored relation. Based on the calculated relationship, the flow rate of the fluid in the pipeline at the detected pressure and the detected opening is calculated.

Further, the opening degree corresponding to the set flow rate at the arbitrary detected pressure is calculated by the opening degree calculating means based on the calculated relation. The adjusting means is adjusted so as to obtain the calculated passage opening. According to a third aspect of the present invention, "the relation calculation means is:
_{Equation, Q 2 / Q 1 = K} (P 2 / P 1) 1/2 P 1: the reference pressure P _2: the arbitrary sensed pressure Q _1: in the reference pressure the flow rate Q _2: wherein The flow rate at an arbitrary detected pressure includes a constant K ”, and the flow rate corresponding to the arbitrary detected pressure is calculated from the relationship between the flow rate corresponding to the reference pressure and the passage opening degree. And the passage opening degree is calculated.

According to a fourth aspect of the present invention, there is provided a pipeline opening / closing means provided in a part of the pipeline for passing or stopping the fluid in the pipeline, and the detection pressure in the stopped state. And a commanding means for instructing a start of passage of the fluid in the pipeline, wherein the control means responds to an instruction from the instruction means. Then, the passage opening is calculated by using the converted detected pressure as the arbitrary detected pressure, and the passage opening is adjusted by the adjusting means so as to be the calculated passage opening, and then the passage It further includes a function of controlling the pipe opening / closing means so as to be started ”.

[0018] In this case, the detection pressure in a state where the passage of the fluid in the pipeline is stopped is converted into the detection pressure during the passage by the conversion means. Then, when the instruction means instructs the passage start of the fluid in the conduit, the control means calculates the passage opening degree by using the converted detected pressure as the arbitrary detected pressure, and The passage opening is adjusted by the adjusting means so as to have the calculated passage opening, and the passage opening / closing means is controlled so that the passage starts after the adjustment.

According to a fifth aspect of the present invention, "the control means compares the flow rate calculated by the calculation means with the set flow rate. If the calculated flow rate is larger than the set flow rate, Controlling the adjusting means so that the passage opening becomes smaller, and controlling the adjusting means so that the passage opening becomes larger when the calculated flow rate is smaller than the set flow rate. '' But it's okay.

In this configuration, when the calculated flow rate is larger than the set flow rate, the adjusting means is controlled so that the passage opening becomes small. by this,
The flow rate of the fluid in the pipeline, that is, the calculated flow rate becomes smaller and approaches the set flow rate. Further, when the calculated flow rate is smaller than the set flow rate, the adjusting means is controlled so that the passage opening becomes large. As a result, the flow rate of the fluid in the pipeline, that is, the calculated flow rate increases, and approaches the set flow rate.

According to a sixth aspect of the present invention, the apparatus further comprises a casing which forms a part of the conduit, wherein the adjusting means corresponds to a valve port formed in the casing and a valve port corresponding to the valve port. And the valve body accommodated in the casing as described above, and the pressure detecting means includes a pressure sensor mounted on a component wall of the casing and in which a pressure receiving portion comes into contact with the fluid.

According to a seventh aspect of the present invention, "the valve body is
The valve port can be closed in a watertight state, and the pressure sensor is
Disposed upstream of the valve port. " The problem solving means of the invention according to claim 8 is a flow rate adjusting device for adjusting a flow rate of the fluid in a pipe through which the fluid passes, wherein a setting means for setting the flow rate to be passed, Pressure detecting means for detecting the pressure of the fluid at a predetermined position, adjusting means provided in a part of the pipeline and capable of adjusting the passage opening of the fluid in the pipeline, Based on a pipeline opening / closing means which is provided in a part and which allows the fluid to pass or stop in the pipeline, the pressure detected by the pressure detecting means in the stopped state, and the set flow rate by the setting means. A passage opening calculating means for calculating a passage opening, and the conduit opening and closing so that the passage is started after the passage opening is adjusted by the adjusting means so as to have the calculated passage opening. And an opening / closing control means for controlling the means ”. And it features.

In this case, the passage opening calculating means determines the passage opening based on the pressure detected by the pressure detecting means and the flow rate set by the setting means when the fluid is stopped in the pipeline. The degree is calculated. The opening / closing control means adjusts the passage opening degree in the adjusting means so as to reach the calculated passage opening degree, and then the pipe is started so that the fluid starts to pass through the pipeline. The road opening / closing means is controlled.

[0024]

As described above, according to the first aspect of the invention, the flow rate of the fluid passing through the pipe is obtained by the calculation based on the detected pressure and the detected opening. And
The detected pressure is less susceptible to turbulence generated in the pipeline. Therefore, the time required to detect the flow rate is significantly shortened as compared with the above-described conventional method in which the flow rate is directly detected via the impeller. Thereby, the responsiveness of the flow rate control is improved as compared with the conventional one.

When this flow rate adjusting device is used in a water supply line of a hot water supply device, the responsiveness of a control operation such as combustion based on the flow rate is also improved. According to the invention of claim 4, when the passage opening / closing means starts the passage of the fluid in the pipeline, the passage opening degree in the adjusting means has already been adjusted. Responsiveness of the flow rate control at the start of the passage is improved as compared with the case where the passage opening is adjusted after the start.

In addition, since the adjusted passage opening is a passage opening corresponding to the set flow rate at the detection pressure,
It becomes unnecessary to adjust the passage opening after the passage is started. And when this flow rate control device is used for the water supply line of the hot water supply device, the inconvenience that the water supply amount becomes excessive at the beginning of the passage start is prevented, and the rise time until the tap water temperature reaches the set temperature is prevented. Be shorter.

According to the seventh aspect of the present invention, the valve body can close the valve port in a watertight state. However, since the pressure sensor is disposed on the upstream side of the valve port, it is possible to close the valve port in the closed state. The pressure detection by the pressure sensor and the calculation based on the detected pressure are accurate. In the invention of claim 8, when the passage of the fluid in the pipeline is started,
Since the passage opening degree is already adjusted to the predetermined opening degree, the adjustment of the passage opening degree after the passage start is small.
Alternatively, the adjustment becomes unnecessary. Therefore, the response of the flow rate control at the start of the passage is improved as compared with the conventional one in which the adjustment of the passage opening is started after the passage is started.

Further, even when this flow rate adjusting device is used in the above-mentioned water supply line, the disadvantage that the amount of water supply becomes excessive at the beginning of the passage is prevented, and the rise time until the tap water temperature reaches the set temperature is prevented. It gets shorter.

[0029]

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described.
This will be described with reference to the drawings. FIG. 1 is an explanatory view of a hot water supply apparatus (1) according to an embodiment of the present invention, and FIG.
FIG. 3 is a sectional view of a water amount control valve (100) built in the hot water supply device (1) of FIG. 3, and FIG. 3 is a partially enlarged view of the water amount control valve (100) of FIG. 2.

[Configuration of Hot Water Supply Device (1)] As shown in FIG. 1, the hot water supply device (1) includes a heat exchanger (1a) housed in a can (10) and a heat exchanger (1a). A gas burner (1b) for heating (1a) by gas combustion, and a fan (1c) for sending the air for gas combustion to the gas burner (1b) are provided.

The heat exchanger (1a) is connected to a water supply pipe line (11) for supplying water and a tap water pipe line (12) for guiding hot water heated by the heating to a bath or the like. ing. In the water supply pipe (11), a water amount control valve (100) for adjusting the flow rate of water flowing toward the heat exchanger (1a) and water passing or stopped in the water supply pipe (11). There is provided a water valve (18) for causing the water to flow.
Note that an electromagnetic valve is used as the water valve (18).

A gas supply line (15) for supplying gas is connected to the gas burner (1b). Gas supply to the gas burner (1b) is turned on in this gas supply line (15).
A gas valve (17) for turning off and a gas amount control valve (16) for controlling the flow rate of passing gas in the gas supply pipe (15) are provided. Note that an electromagnetic valve is employed as the gas valve (17).

The hot water supply device (1) includes a water amount control valve (100), a water valve (18), a gas amount control valve (16), and a gas valve (17).
And the like, and an operation switch (19) for instructing activation / inactivation of the hot water supply device (1). [Configuration of water flow control valve (100)] The above water flow control valve
As shown in FIG. 2, (100) is a casing (2) constituting a part of the water supply pipe (11) and a valve body (24) corresponding to a valve port (24) inside the casing (2). 3), a drive device (4) capable of driving the valve body (3) in the axial direction, and a water pressure sensor (5) mounted on the constituent wall of the casing (2) and detecting the water pressure in the casing (2). A potentiometer (6) for indirectly detecting the opening of the valve element (3), and a casing.
A flow rate sensor (7) for directly detecting the flow rate of water passing through (2).

Next, the structure of each part of the water quantity control valve (100) will be described. * Casing (2) * As shown in Figs. 1 to 3, the casing (2) has a main cylinder part (22) arranged in a substantially horizontal posture and having a substantially circular cross section, and the main cylinder part (22). An inflow cylindrical portion (21) having a substantially circular cross-section, which is connected to a lower side of one end of the main body in a substantially vertical posture and allows water to flow into the main cylindrical portion (22); An outflow tube portion (23) which is provided and allows water to flow out from the main tube portion (22).

The outflow cylinder portion (23) has a smaller diameter than the main cylinder portion (22), and an inner surface of a boundary between the main cylinder portion (22) and the outflow cylinder portion (23) has a valve port. (24) is formed. An insertion member (2a) that is held in a watertight state at an end opposite to the outflow cylinder (23) is disposed inside the main cylinder (22). At the end of the insertion member (2a) on the side of the outflow cylinder (23), a cylinder (26) that is coaxial with the main cylinder (22) is formed, and this cylinder (26) Thereby, a valve body (3) described later is held so as to be movable in the axial direction. A slide member (4b) and a valve shaft (4c), which will be described later, are fitted into the insertion member (2a) so as to pass through the center of the cross section in the axial direction.

* Valve body (3) * The above-mentioned valve body (3) is a cylindrical body densely housed in the valve body (26) so as to be coaxial with the valve body (3). The end portion on the 24) side projects from the cylindrical portion (26). A part of the projection in the axial direction is formed so as to protrude toward the outer peripheral side over the entire circumference, and an annular rubber portion (30) is formed substantially over the entire outer surface. ing. This rubber part (30)
The size of the valve body (3) is set such that the valve body (3) can come into contact with the peripheral portion of the valve port (24) over the entire periphery by the axial movement. By the contact, the rubber portion (30) and the peripheral portion are in close contact with each other, so that the valve opening (24) is closed in a watertight state to stop water.

* Driving device (4) * The driving device (4) is provided with an outflow cylinder (2) in the main cylinder (22).
The motor (40) screwed to the end opposite to 3),
The cylinder (4a) integrated with the output shaft (not shown) of the motor (40) and formed with a female screw, and a certain range on the motor (40) side is screwed with respect to the cylinder (4a). A slide member (4b) which is fitted so that the end on the valve body (3) side is relatively movable only in the axial direction with respect to the insertion member (2a);
A valve shaft (4c) which is penetrated through (4b) and is held in a state where relative movement in the axial direction with respect to the slide member (4b) is blocked.
And is provided.

The valve shaft (4c) is inserted in the valve body (3), and the valve shaft (4c) is provided with a valve so that the valve body (3) does not come out to the valve opening (24) side. An annular engagement part (41) that engages with the body (3)
Are formed. Further, a spring which is fitted to the inside of the tubular portion (26) of the valve shaft (4c) and is interposed between the inner peripheral portion of the tubular portion (26) and the inner peripheral portion of the valve body (3). (4d) is provided. The valve body (3) is maintained in a state where the axial movement relative to the valve shaft (4c) is prevented by the engagement portion (41) and the spring (4d).

In this structure, when the motor (40) operates, the output shaft of the motor (40) rotates and the cylinder (4a) rotates. At this time, since the slide member (4b) screwed to the cylinder (4a) is relatively movable only in the axial direction with respect to the insertion member (2a) fixed at a fixed position, the motor (40 The slide member (4b) moves in the axial direction by the operation of ()). And
Since the axial relative movement of the valve shaft (4c) with respect to the slide member (4b) and the axial movement of the valve body (3) with respect to the valve shaft (4c) are prevented, the motor (40) The actuation causes the valve body (3) to move axially. By this movement, the distance between the valve body (3) and the valve port (24), that is,
The opening (300) of the valve body (3) is adjusted.

The valve shaft (4c) is moved to the valve port (24) side so that the rubber portion (30) of the valve body (3) can abut on the peripheral edge of the valve port (24). It is set. In addition, the above motor (40)
The operation of is controlled by a signal from a control circuit (8) described later. * Water pressure sensor (5) * The water pressure sensor (5) is mounted on the constituent wall on the opposite side (upper side) of the inflow cylinder part (21) in the main cylinder part (22). Then, in the water pressure sensor (5), a disc-shaped pressure receiving portion (51) arranged so as to close the through hole (27) formed in the constituent wall and the through hole (27) are provided. The conversion output section (5) converts the pressure applied to the pressure receiving section (51) into an electric signal and outputs it.
2) and are provided. The detected water pressure (55) of the water pressure sensor (5) is applied to a control circuit (8) described later.

* Potentiometer (6) * The potentiometer (6) is in contact with the outer peripheral surface of the cylindrical body (4a) and the rotation angle (44) of the output shaft of the motor (40).
Is configured to detect. In this configuration, the rotation angle (44) is detected uniquely because the rotation angle (44) and the opening degree (300) are uniquely corresponded by the configuration of the drive device (4). Thus, the opening (300) is detected. In addition, the detection angle of this potentiometer (6) (6
4) is applied to a control circuit (8) described later.

* Flow sensor (7) * The above flow sensor (7) is the same as the conventional one,
An impeller (7a) coaxially arranged in the inflow cylinder (21).
And an impeller mounted on a part of the constituent wall of the inflow cylinder (21).
An output unit (7b) that outputs the rotation speed of (7a) as an electric signal,
Consists of. The impeller (7a) is equipped with a magnet on each of its blades, and the output section (7b) generates and outputs a pulse signal when each of the magnets passes through its vicinity. Has been adopted. The detected flow rate (71) of the flow rate sensor (7) is applied to the control circuit (8) described later. Further, the control circuit (8) has a function of averaging the variations of the output pulses from the output section (7b) and calculating the flow rate.

[Regarding Configuration of Control Circuit (8)] The control circuit (8) has a configuration including a microcomputer (8a), and the microcomputer (8a) includes the hot water supply device (1). The control program for executing the water flow control is stored. [Use of Hot Water Supply Device (1)] FIG. 4 is a flowchart of a control program stored in the microcomputer (8a) of the control circuit (8) of FIG. 1, and FIG. 5 is a flowchart of the control program of FIG. FIG. 6 is a flowchart of a first water volume control routine, and FIG. 6 is a flowchart of a second water volume control routine of the control program of FIG. FIG. 7 is a graph showing the relationship between the rotation angle (44) of the water flow control valve (100) in FIG. 2 and the flow rate (75).

The operation of the hot water supply device (1) will be described with reference to FIG. In the hot water supply device (1), when the operation switch (19) is turned on, first, a first water amount control routine is executed (steps (S1) and (S2)), and the water amount adjustment valve (100) is operated. Are in a standby state at a predetermined opening degree in advance. The details of the first water amount control routine will be described later.

Thereafter, the water valve (18) is opened, and the passage of water through the water supply line (11) is started (step (S3)). Then, when the flow rate (71) detected by the flow rate sensor (7) reaches a predetermined flow rate, the hot water supply device (1) starts combustion (steps (S4) (S5)). The predetermined flow rate is determined by the water heater.
It is set to the minimum flow rate within the settable flow range in (1).

In step (S5), the fan (1c) is operated to supply combustion air to the gas burner (1b), the opening of the gas amount control valve (16) is adjusted, and the gas valve (1) is operated. 17)
In the open state, the gas burner (1b) is ignited by an ignition device (not shown). Thereby, gas combustion is started in the gas burner (1b). By this gas combustion, the temperature of water flowing from the water supply pipe (11) into the heat exchanger (1a) and passing through the heat exchanger (1a) is increased to hot water. This hot water
It flows from the heat exchanger (1a) to the hot water outlet pipe (12) and is supplied to a bath or the like.

In this combustion state, the second water amount control routine is executed (step (S6)), and the flow rate of water passing through the water supply line (11) is controlled. This second water amount control routine is repeatedly executed until the operation switch (19) is turned off (step (S7)). The details of the second water amount control routine will be described later. When the operation switch (19) is turned off, the hot water supply device (1) stops burning (steps (S7) and (S8)). When the combustion is stopped, the gas valve (17) is closed and the combustion in the gas burner (1b) disappears, and the fan (1c) is stopped when a certain time has passed after the closed state. To do.

Also, after the closed state, the water valve
(18) is closed, and the flow of water in the water supply pipeline (11) is stopped (step (S9)). After this, the motor (4
0) is activated, and the water flow control valve (100) returns to the initial maximum opening (step (S10)). [Regarding First and Second Water Quantity Control Routine] Next, each of the first and second water quantity control routines will be described in detail.

* First Water Volume Control Routine * The control circuit (8) includes the rotation angle (44) corresponding to the reference water pressure (54) of the detected water pressure (55) as shown in FIG.
A storage function unit (80) (not shown) for storing a relationship between the flow rate and the flow rate of water (75) is provided. The above relationship is a unique relationship determined by the shape and size of the water amount control valve (100), and is as shown by the curve in FIG. Further, the above relationship has been experimentally obtained. The detected water pressure (55)
Is the water pressure when water is passing through the water flow control valve (100), and the reference water pressure (54) is, for example, 0.1 M
P is adopted.

The control circuit (8) calculates the relationship between the flow rate (75) and the rotation angle (44) corresponding to an arbitrary detected water pressure (55) based on the stored relationship. A relational operation function unit (81) (not shown) is provided. The relational operation function unit (81), specifically, the formula: Q ₂ / Q ₁ = K
It is configured to execute the operation represented by (P ₂ / P ₁ ) ^1/2 . Here, “P ₁ ” is a reference water pressure (54), “P ₂ ” is an arbitrary detected water pressure (55), and “Q
₁ '' is the flow rate (75) at the reference water pressure (54),
“Q ₂ ” is the flow rate (75) at the arbitrary detected water pressure (55).
And “K” is a constant.

By the calculation in the relational calculation function section (81), an arbitrary detected water pressure (55) as shown in FIG. 7 (for example,
Each curve representing the relationship between the rotation angle (44) corresponding to 0.3MP and 0.5MP) and the flow rate (75) is obtained. Then, as described above, this first water amount control routine is executed with the water valve (18) closed, that is, with the water flow in the water supply conduit (11) stopped.

The calculation in the relational calculation function section (81) and the like is based on the detected water pressure (55) in the state where water does not pass through the water supply pipe (11). For use, as shown in FIG. 5, a value obtained by subtracting a predetermined value (56) from the above detected water pressure (55) in the stopped state is set as a converted water pressure (57) (step (S11)). The water pressure (57) is regarded as the detected water pressure (55) during the passage. The above-mentioned predetermined value (56) is obtained experimentally.

Then, based on the relationship between the rotation angle (44) and the flow rate (75) calculated by the relation calculation function section (81), the set flow rate (74) at the reduced hydraulic pressure (57) is obtained. Rotation angle corresponding to
(44) is calculated (step (S12)). This calculation is executed by an angle calculation function unit (82) (not shown) provided in the control circuit (8). The set flow rate (74)
Is set by calculation or the like based on factors such as hot water temperature and hot water flow rate of the hot water supply device (1). Therefore, the control circuit (8) is provided with a setting function unit (83) for executing the setting.

After the calculation by the angle calculation function section (82) is performed, the rotation angle (44) of the motor (40) is adjusted so as to become the calculated rotation angle (44). (Step (S1
3)). As a result, the opening (300) is adjusted. After this adjustment, the water valve (1
8) is opened, and the passage of water through the water supply pipe (11) is started.

In this case, as described above, when the passage of water through the water supply line (11) is started by the water valve (18), the opening (300) is already calculated by the angle calculation function unit. The opening is adjusted to the rotation angle (44) calculated in (82).
As a result, there is no time lag in water volume control immediately after the start. Therefore, the responsiveness of the water amount adjustment at the start is improved as compared with the conventional case where the opening is adjusted so as to be narrowed from the maximum opening only after the start.

In addition, the adjusted opening degree (300) is set at the set flow rate (74) by the calculation in the angle calculation function section (82).
, The opening adjustment immediately after the start of the passage is unnecessary. Therefore, the responsiveness of the water amount adjustment at the start is further improved. In particular, the above-described improvement of the responsiveness prevents the problem that the flow rate of the water in the water supply pipe (11) becomes excessive immediately after the start as in the related art. Therefore, the amount of water supplied to the heat exchanger (1a) is
The combustion amount in (1b) is not too large, and the rise time until the temperature of the hot water discharged from the heat exchanger (1a) reaches the set temperature is short.

Further, due to the improvement of the responsiveness, cold water flows out of the hot water supply device (1) at the rise time when the hot water supply device (1) is restarted immediately after the operation is stopped. However, it is suppressed. In this hot water supply device (1), the valve body (3) closes the valve port (24) when the operation switch (19) is in the “OFF” state. In the first water amount control routine, the opening is adjusted from the closed state. At this time, the water pressure sensor (5)
Since it is arranged on the upstream side, the water pressure detection in the closed state and the calculation based on the detected water pressure (55) are accurate.

* Second Water Volume Control Routine * The second water volume control routine is executed in a state where water is flowing in the water supply line (11) as described above. In the second water amount control routine, as shown in FIG. 6, the flow rate (75) and the rotation angle (44) corresponding to the arbitrary detected water pressure (55) calculated by the relational calculation function section (81). Based on the relationship
The flow rate (calculated flow rate (76)) calculated from the detected water pressure (55) and the detection angle (64) is calculated (step (S21)). The calculated flow rate (76) substantially matches the actual flow rate (75). still,
The control circuit (8) includes a flow rate calculation function section (84) for the calculation.

Then, the calculated flow rate (76) and the set flow rate (7
If 4) is in agreement, this second water amount control routine ends, and conversely, due to pressure fluctuations in the water supply conduit (11), etc., the calculated flow rate (76) and the set flow rate (74) If no longer matches, the next step (S23) is executed (step
(S22)). In step (S23), it is judged whether the calculated flow rate (76) is larger than the set flow rate (74) (step
(S23)).

When the calculated flow rate (76) is larger than the set flow rate (74), the water flow control valve (100) is throttled by the operation of the motor (40) (step (S24)). This reduces the above flow rate (75). And the steps mentioned above
The calculated flow rate (76) is calculated by the same calculation as in (S21) (step (S25)). These steps (S24) and (S25) are repeatedly executed until the calculated flow rate (76) reaches the set flow rate (74), and when the calculated flow rate (76) reaches the set flow rate (74), the second The water flow control routine ends (step
(S26)).

When the calculated flow rate (76) is smaller than the set flow rate (74), the water flow control valve (100) is opened (step (S28)
). This increases the flow rate (75). And
Calculated flow rate by the same calculation as the above step (S21)
(76) is calculated (step (S29)). These steps (S2
8) (S29), the calculated flow rate (76) calculated is the set flow rate (7
It is repeatedly executed until the flow rate reaches 4). When the calculated flow rate (76) reaches the set flow rate (74), the second water volume control routine ends (step (S30)).

In this case, as described above, the water supply line
The flow rate (75) of the water passing through (11) is calculated by the calculation based on the detected water pressure (55) and the detection angle (64).
It is calculated as 6). At this time, since the detected water pressure (55) is hardly affected by turbulence or the like generated in the casing (2) of the water flow control valve (100), the detected water pressure (55) is passed through the impeller (7a) as in the conventional case described above. The time required for detecting the flow rate (75) is greatly reduced as compared with the case where the flow rate is controlled based on the detected flow rate (71). Therefore, set the flow rate (75) to the set flow rate.
The responsiveness of flow rate control such as adjustment to (74) is improved compared to the conventional one.

Further, in addition to the above-mentioned pressure fluctuation and the like, even when the set flow rate (74) is changed, the flow rate is controlled by the second water amount control routine in the same manner as described above. or,
Even in this case, the same effect of improving the response as described above is exerted.
In particular, in this water heater (1), the responsiveness of control operations such as combustion based on the flow rate (75) is also improved.

In the above water amount control, the water pressure sensor
Although (5) and the flow sensor (7) are always energized, they may be energized only when detection is necessary. In this, the water supply pipe (11) corresponds to the "pipe" described in the claims, and the water amount control valve (100), the control circuit (8) and the water valve (18). Corresponds to the “flow rate adjusting device” described in the claims.
Further, the water valve (18) corresponds to the “pipe opening / closing means” described in the claims described above, and the operation switch (19) corresponds to the “instruction means” described in the claims set forth above. Is equivalent to

The setting function section (83) corresponds to the “setting means” described in the appended claims. Further, the water pressure sensor (5) corresponds to the "pressure sensor" and "pressure detecting means" described in the claims, and the valve opening (24), the valve body (3) and the driving device ( 4) corresponds to the “adjusting means” described in the claims described above, and the potentiometer described above.
(6) corresponds to the “opening degree detecting means” described in the appended claims.

The storage function unit (80) corresponds to “storage means” described in the above-described claims, and the relation calculation function unit (81) corresponds to “relationship” described in the above-described claims. Computing means "
Corresponding to the memory function unit (80) and the relational operation function unit (8
1) and the flow rate calculating function section (84) correspond to the "calculating means" described in the claims. The angle calculation function unit (82) corresponds to the “opening degree calculation means” and “passing opening degree calculation means” described in the claims, and the angle calculation function unit (82) and the step (S2), (S3), (S6) and (S7) correspond to the "control means" described in the appended claims. Furthermore, the above steps (S2) and (S3) correspond to the "opening / closing control means" described in the claims. [Other embodiments]. FIG. 8 is a graph showing the relationship between the rotation angle (44) and the flow rate (75) in another embodiment.

In the above water amount control, the rotation angle (44) corresponding to the set flow rate (74) is calculated based on the detected water pressure (55) when water is passing through the water supply pipe (11). Then, the opening is adjusted. As shown in FIG. 8, the rotation angle (44) corresponding to the detected water pressure (55) when the water is stopped in the water supply pipe (11) and the flow rate when the water starts to pass (75) is determined in advance, and the detected water pressure in the stopped state (55)
The rotation angle (44) may be calculated based on the set flow rate (74) and the set flow rate (74).

In this case, the flow rate (75) at the start of the passage at the calculated rotation angle (44) may or may not match the set flow rate (74). Even if they do not match, at the time when the passage is started, since the opening is already adjusted, the time lag of the water amount adjustment immediately after the start is smaller than that when the opening is adjusted for the first time after the start. Become. This improves the responsiveness of the water volume control at the start.

.. The aforementioned “fluid” is not limited to the above-mentioned water. For example, a liquid such as oil or a gas such as a gas may be used. . The above-mentioned “pipe” is not limited to the above water supply pipe (11) as long as it is a pipe through which a fluid passes. For example, the gas supply line (15) described above may be used. . The above-mentioned “opening degree detecting means” is not limited to the above potentiometer (6). For example, the rotation angle (44) may be detected by reading an instruction signal of the rotation angle (44) for the motor (40) in the control circuit (8).
Alternatively, the distance (opening (300)) between the valve body (3) and the valve opening (24) may be directly detected.

[Brief description of the drawings]

FIG. 1 is an explanatory view of a hot water supply apparatus (1) according to an embodiment of the present invention.

FIG. 2 is a diagram showing a water control valve (1
00) cross section

FIG. 3 is a partially enlarged view of a water flow control valve (100) in FIG. 2;

4 is a microcomputer of the control circuit (8) of FIG.
Flow chart of the control program stored in (8a)

FIG. 5 is a flowchart of a first water amount control routine of the control program of FIG. 4;

FIG. 6 is a flowchart of a second water amount control routine of the control program of FIG. 4;

FIG. 7 is a graph showing a relationship between a rotation angle (44) and a flow rate (75) at the water flow control valve (100) in FIG. 2;

FIG. 8 is a graph showing the relationship between the rotation angle (44) and the flow rate (75) in another embodiment.

FIG. 9 is an explanatory view of a conventional water amount adjusting device (9).

[Explanation of symbols]

 (11) ・ ・ ・ Water supply line (100) ・ ・ ・ Water control valve (8) ・ ・ ・ Control circuit (18) ・ ・ ・ Water valve (5) ・ ・ ・ Water pressure sensor (24) ・ ・ ・ Valve (3) ・ ・ ・ Valve disc (4) ・ ・ ・ Drive device (6) ・ ・ ・ Potentiometer (8) ・ ・ ・ Control circuit

Claims (8)

[Claims] 1. A flow control device for adjusting a flow rate of the fluid in a pipe through which the fluid passes, a setting means for setting the flow rate to be passed, and the fluid at a predetermined position in the pipe. Pressure detecting means for detecting the pressure of the fluid; adjusting means provided in a part of the conduit and capable of adjusting the passage opening of the fluid in the conduit; and opening detecting means for detecting the passage opening. And a calculating means for calculating the flow rate of the fluid passing through the pipeline based on the detected pressure of the pressure detecting means and the detected opening degree of the opening detecting means, and the calculated flow rate is set by the setting means. A flow rate adjusting device comprising: a control unit that controls the adjustment of the passage opening degree by the adjustment unit and the calculation by the calculation unit to be repeated so as to obtain a flow rate. 2. The storage means for storing the relationship between the passage opening and the flow rate corresponding to a reference pressure of the detected pressure, and the arithmetic means for calculating any of the detected pressures based on the stored relationship. A relation calculating means for calculating a relation between the corresponding flow rate and the passage opening degree, the control means corresponding to the set flow rate at the arbitrary detected pressure based on the calculated relation. The flow rate adjusting device according to claim 1, further comprising opening degree calculation means for calculating a passage opening degree. 3. The relation calculation means calculates the following equation: Q ₂ / Q ₁ = K (P ₂ / P ₁ ) ^1/2 P ₁ : the reference pressure P ₂ : the arbitrary detected pressure Q ₁ : the in the the reference pressure rate Q _2: the in the said any sensed pressure flow K: flow rate control apparatus according to claim 2 containing the constants. 4. A pipeline opening / closing means which is provided in a part of the pipeline and passes or stops the fluid in the pipeline, and the detected pressure in the stopped state, the detected pressure at the time of passage. Further comprising: a conversion means for converting into the above, and an instruction means for instructing the start of passage of the fluid in the pipeline, wherein the control means is responsive to the instruction by the instruction means, and the converted detected pressure. Is calculated as the arbitrary detected pressure, the passage opening is adjusted by the adjusting means so that the passage opening is calculated, and then the passage is started. The flow rate adjusting device according to claim 2, further comprising a function of controlling the opening / closing means. 5. The control means compares the flow rate calculated by the calculation means with the set flow rate, and when the calculated flow rate is larger than the set flow rate, the passage opening becomes smaller. The controller according to any one of claims 1 to 3, wherein the controller controls the adjusting unit such that when the calculated flow rate is smaller than the set flow rate, the passage opening increases. Flow controller. 6. The apparatus further comprises a casing forming a part of the conduit, wherein the adjusting means is housed in the casing so as to correspond to the valve opening formed in the casing and the valve opening. A valve body, The said pressure detection means is a flow control apparatus in any one of Claims 1-5 which is equipped with the structural wall of the said casing, and includes the pressure sensor which a pressure receiving part contacts the said fluid. 7. The flow control device according to claim 6, wherein the valve body can close the valve port in a watertight state, and the pressure sensor is disposed upstream of the valve port. 8. A flow rate adjusting device for adjusting a flow rate of the fluid in a pipe through which the fluid passes, a setting means for setting the flow rate to be passed, and the fluid at a predetermined position in the pipe. Pressure detecting means for detecting the pressure of the fluid; adjusting means provided in a part of the conduit and capable of adjusting a passage opening of the fluid in the conduit; provided in a part of the conduit and A pipeline opening / closing means for passing or stopping the fluid in the pipeline, and a passage for calculating the passage opening based on the pressure detected by the pressure detecting means in the stopped state and the flow rate set by the setting means. Opening calculation means, and opening / closing control means for controlling the pipe opening / closing means so that the passage is started after the passage opening is adjusted by the adjusting means so as to become the calculated passage opening. And a flow control device comprising: