JP2001005530A - Flow rate adjusting tank and constant outflow rate adjusting method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To make easily and inexpensively realizable certain flow rate adjustment with high reliability. SOLUTION: At first, the height of the low edge of the opening of a slide plate 122 is set so as to be made almost coincident with the height of the scale position of a scale board 15 corresponding to a target flow rate from the bottom face. Then, water at a larger fixed flow rate than the target flow rate are allowed to inflow from an inflow port 1a, and while the flow rate value of the water is viewed by using the scale board 15 in this state, the opening area of the opening is set by decreasing the level of the opening from the prescribed opened state by lowering a slide board 13 so that the flow rate of water to outflow from an outflow port 1b can be made stable so as to be set about the target flow rate.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a flow rate adjusting tank for adjusting a flow rate of waste water to a substantially constant value, and a method for adjusting a constant flow rate.

[0002]

2. Description of the Related Art As shown in FIG. 21, a pump (however, a pump having the characteristics shown in FIG. 21 is a sewage submersible pump, and a prime mover is a three-phase 200 [V], 50 [Hz], synchronous speed 3000]
[1 / min] and the output is 0.25 [kW]. Since the discharge amount changes with the head, the discharge amount varies depending on the water level of the storage tank. Therefore, when the pump sends wastewater to a purification treatment facility, the amount of water varies, especially when the amount of water suddenly increases. There are times when you can not.

[0003] For this reason, as a method of controlling the discharge amount, a method of connecting a DC motor or a variable-speed AC motor to a pump to change the number of revolutions, a method of returning a part of the discharge amount to a storage tank through a bypass, and supplying water is performed. For example, a method of controlling the bypass valve to adjust the return amount so as to match the processing capacity of the other side is adopted.

[0004]

However, all of the above methods require expensive control equipment and the like, and have a problem that the configuration is complicated and the cost is increased. In addition, a malfunction may occur, and it is necessary to replace components related to control with the lapse of time, and a precise periodic inspection is indispensable.

Accordingly, the present invention provides a flow control tank and a constant flow control method which can perform a reliable and reliable flow control and can be easily maintained and managed, despite being simple and inexpensive. The purpose is to do.

[0006]

According to a first aspect of the present invention, there is provided a flow rate adjusting tank for discharging a liquid to a predetermined supply destination. And a weir-shaped flow control unit that is disposed on the main flow path from the inflow port to the outflow port and has a throttle mechanism for adjusting the flow rate of the passing liquid,
An overflow adjusting unit having a barrier for overflowing a liquid exceeding a predetermined overflow height out of the liquid flowing from the inflow port, and a throttle amount in a throttle mechanism of the flow rate adjusting unit; The downstream flow rate of the main flow path is set to the target flow rate by adjusting the overflow height at the barrier of the section.

According to another aspect of the present invention, there is provided a flow control tank having an inlet for receiving an inflowing liquid and an outlet for discharging a liquid to a predetermined supply destination. An overflow port for overflowing and discharging a part of the liquid once introduced, and a restrictor mechanism arranged on a main flow path from the inflow port to the outflow port to adjust a flow rate of the passing liquid. Weir-shaped flow rate adjustment unit, and arranged on a diversion path leading to the overflow port by splitting on the upstream side of the place where the flow rate adjustment unit is arranged on the main flow path, of the liquid flowing from the inflow port An overflow adjusting unit having a barrier for overflowing a liquid exceeding a predetermined overflow height, and a flow rate measuring unit for measuring a flow rate on the downstream side of the main flow path. In addition, based on the flow rate measured by the flow rate measuring means, by adjusting the throttle amount of the throttle mechanism of the flow rate adjusting unit and the overflow height at the barrier of the overflow adjusting unit, the flow rate in a predetermined range The flow rate on the downstream side of the main flow path when the liquid flows from the inflow port is set to be a flow rate within a target range including a target flow rate.

According to a third aspect of the present invention, there is provided a flow regulating tank according to the second aspect, wherein the flow measuring means has a predetermined shape disposed upstream of the outlet. And a weir having a size, disposed on the upstream side of the weir, based on at least a predetermined relationship between the flow rate and the liquid level corresponding to the shape and size of the weir, the liquid level height And a measuring scale plate on which a corresponding flow value is displayed, and the overflow height at the barrier of the overflow adjusting unit is set to a liquid level corresponding to the target flow rate on the measuring scale plate. The flow rate measured by the measurement scale plate is adjusted so as to substantially match, and the amount of throttle in the throttle mechanism of the flow rate adjustment unit is adjusted in a state where the overflow height at the barrier of the overflow adjustment unit is adjusted. Flow rate within target range Sea urchin and adjusting.

According to a fourth aspect of the present invention, there is provided a flow rate adjusting tank according to the second or third aspect,
The throttle mechanism of the flow rate adjusting unit is a first fixing unit that allows a liquid to pass through an opening provided on the bottom, and a second fixing unit that is slidably attached to the first fixing unit and opens and closes the opening. And the first slide portion is displaced with respect to the first fixed portion, whereby the opening area of the opening changes and the flow rate of the liquid passing therethrough is adjusted. The overflow adjustment unit includes a second fixing unit, and a second sliding unit that is slidably attached to the second fixing unit and causes the liquid to overflow at an upper portion,
When the second slide portion is displaced with respect to the second fixed portion, an overflow height at an upper portion of the second slide portion changes, and an overflow amount is adjusted. .

[0010] In order to solve the above-mentioned problem, the invention according to claim 5 sets the discharge flow rate to a target value by adjusting first and second flow rate adjustment units provided on a path from an inlet to an outlet. A method for adjusting a constant flow amount to be set, wherein the first adjusting section is an overflow adjusting section, the second adjusting section is a weir-shaped adjusting section, and the relative adjustment of the first and second flow rate adjusting sections. Setting the discharge flow rate to a target value.

According to a sixth aspect of the present invention, a discharge flow rate is adjusted to a target value by adjusting first and second flow rate adjustment sections provided on a path from an inlet to an outlet. A method for adjusting a constant outflow amount to be set, wherein the first adjusting unit is an overflow adjusting unit having a barrier for overflowing a liquid exceeding a predetermined overflow height, and the second adjusting unit is configured to adjust a passing liquid. When a weir-shaped adjustment unit having a throttle mechanism for adjusting the flow rate of the liquid and a liquid in a predetermined range of flow rate flows in from the inflow port while monitoring the discharge flow rate in the vicinity of the outflow port while obtaining the discharge flow rate. Adjusting the overflow height at the barrier of the first adjustment unit and the throttle amount in the throttle mechanism of the second adjustment unit so that the discharge flow rate is within the target range. Features.

[0012]

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

Embodiment 1 FIG. FIG. 1 is a plan view showing a configuration of a flow control tank according to Embodiment 1 of the present invention, FIG. 2 is a cross-sectional view taken along line AA of FIG. 1, and FIG. 3 is a view taken along line BB of FIG. FIG. 4 is a sectional view taken along the line CC of FIG.
FIG. 6 is a cross-sectional view taken along the line D-D of FIG. 1, FIG. 6 is a front view showing a fixed plate and a slide plate of an outflow amount adjusting section constituting the flow rate adjusting tank, and FIG. FIG. 8 is a front view showing a fixing plate and a slide plate of the adjustment unit,
It is a figure which shows typically the structure of the drainage system to which the same flow control tank is applied.

The flow control tank 1 according to the first embodiment is
As shown in FIG. 8, wastewater such as sewage stored in the storage tank 2 is pumped by a submersible pump 3 installed in the storage tank 2, and is disposed on a path that is sent to, for example, a processing tank 4 of a purification facility. Then, a part of the waste water sent from the submersible pump 3 through the water supply pipe 5 is returned into the storage tank 2 through the bypass pipe 6, whereby the flow rate of the waste water sent from the submersible pump 3 is changed. Regardless, wastewater having a predetermined fixed flow rate is sent to the treatment tank 4 via the water pipe 7.

As shown in FIGS. 1 to 7, the flow control tank 1 has an inlet 1 a for receiving waste water sent from the storage tank 2, and sends a substantially constant flow of waste water to the treatment tank 4. Is an approximately rectangular parallelepiped water tank having an outflow port 1b disposed on the side of the inflow port 1a, and an overflow port 1c connected to a bypass pipe 6 for returning a part of drainage once flowing into the storage tank 2.

The flow regulating tank 1 is provided at a position near the inlet 1a on the main flow path from the inlet 1a to the outlet 1b.
A flow rate adjusting unit 11 is provided for adjusting the amount of drainage from the outlet 1b to a predetermined substantially constant value,
In a part of the main flow path that is slightly upstream of the overflow port 1c on the branch path that branches off upstream of the place where the flow rate adjusting unit 11 is arranged and reaches the overflow port 1c, drainage flowing from the outlet 1a is Among them, an overflow adjusting unit 12 is provided for overflowing the drainage exceeding the height (overflow height) of the lower edge of the opening of the slide plate described later.

A flow regulating plate 13 having an opening 13a at the bottom is provided on the upstream side of the flow regulating unit 11, and a weir plate 14 having a predetermined shape is provided between the flow regulating unit 11 and the outlet 1c. Is arranged.

The flow rate adjusting unit 11 is provided with a flow control plate 111 having an opening 111a through which a liquid passes at the bottom.
a fixed plate 112 having an opening 112a of substantially the same shape and size as a is attached so as to overlap both openings,
Further, a slide plate 113 is attached to the fixed plate 112 so as to be slidable.
2 with respect to the opening 1
The opening area of 12a (111a) is changed, and the flow rate of the drainage is adjusted.

Further, a scale plate 15 for indicating a current flow rate value of the drainage is attached to a predetermined portion of the current plate 111.

The overflow adjusting unit 12 includes a fixing plate 12
1, a slide plate 122 having an opening 122a is slidably mounted, and the slide plate 122 is vertically displaced with respect to the fixed plate 121.
The height (overflow height) of the lower edge of the opening 122a changes, the position (height) at which overflow starts or stops changes, and the overflow amount in the overflow adjusting unit 12 is adjusted.

The weir plate 14 forms a triangular weir having a V-shaped notch, and the apex angle of the notch is set to 60 degrees. Further, the depth of the notch, the height from the bottom surface to the lower edge of the notch, the width of the weir (that is, the width of the water channel), and the like are also set to predetermined values.

The scale plate 15 has a water level based on a predetermined relationship between the water level and the flow rate corresponding to the apex angle of the notch of the weir plate 14 and the width of the weir plate 14 as given by the equation (1). The flow rate value corresponding to the value is marked on the scale, and the flow rate value can be known by directly reading the value of the scale corresponding to the water surface position.

That is, the flow rate Q is given by Equation 1.

[0024]

(Equation 1) In Equation 1, Q is the flow rate “m ³ / Hour”, z is the head of the weir [m], and K is the flow coefficient given by Equation 2.

[0025]

(Equation 2) In Equation 2, W is the width [m] of the channel, and R is a coefficient given by Equation 3.

[0026]

(Equation 3) In Equation 3, ν is the kinematic viscosity coefficient [cm ² / sec], and when the fluid is water, it is approximately 0.01 [cm ² / sec].

In this embodiment, the dimensions and structure of each component are designed according to the range of the expected flow rate of the inflowing waste water, the range of the required set flow rate (target flow rate), the adjustment accuracy, and the like. For example, the fluctuation range (target range) of the flow rate on the outlet side is designed to be within about 10% of the fluctuation range of the flow rate on the inlet side.

The set flow rate of the waste water at the outlet 1b is set so as to match the water treatment capacity of the equipment downstream of the flow control tank 1. Based on the set flow rate, the lower edge of the opening 122a is determined. And the opening area of the opening 112a are set in advance before the flow rate adjusting tank 1 is actually operated.

The height (overflow height) of the lower edge of the opening 122a of the slide portion 122 is set so as to substantially match the height from the bottom of the scale position of the scale plate 15 corresponding to the set outflow amount. I do. Further, the opening area of the opening 112a is set such that a substantially constant flow rate of water, which is larger than the set flow rate, flows in from the inflow port 1a. The slide plate 113 is slid so that the outflow amount of water is stabilized near the set outflow amount.

For example, when the set flow rate is 1.0 [m ³ / Hou]
r], first, 1.0 [m ³
/ Hour], the slide plate 122 is slid and fixed so that the height of the lower edge of the opening 122a substantially matches the height of the scale position corresponding to the flow rate value of / Hour].

Next, after the opening 112a is brought into a predetermined opening state (for example, fully open), for example, water flows in from the inflow port 1a at a constant flow rate (set inflow amount) of about 3.0 [m ³ / Hour]. Let it. In this state, the slide plate 113 is gradually lowered while confirming the instruction on the scale plate 15 to open the opening 11.
We narrow down 2a.

The water level on the scale 15 is 1.0
When the position is stabilized at the scale position corresponding to the flow rate value of [m ³ / Hour], the slide plate 113 is fixed, and the opening area (aperture amount) of the opening 112a at this time is maintained.

For example, when the opening 112a is in the initial opening state (for example, fully open), the flow rate at the time of inflow is 1.0 [m ^3].
/ Hour], assuming that the opening 122a of the slide plate 122 is almost on the verge of overflow, the water passes through the opening 112a as it is, and reaches 1.0 [m ³ /
Hour].

At this time, the flow rate at the time of inflow is set to 1.0 [m ³ /
Hour], the opening 112a is squeezed from the above-mentioned initial opening state.
The flow rate of water passing through “a” decreases, and the flow rate of water corresponding to this decrease overflows from the opening 122 a of the slide plate 122.

The flow rate at the time of inflow is set to 1.0 [m ³ / Hour] while the opening portion 112a is kept in the initial opening state.
, The water at a predetermined flow rate overflows from the opening 122a of the slide portion 122 in accordance with the increase. There is also a slight increase in the flow rate of water passing through the opening 112a.

Here, when the opening 112a is narrowed from the initial opening state, the increase in the flow rate of water passing through the opening 112a when the flow rate at the time of inflow is increased is reduced in accordance with the throttle amount. At a predetermined throttle amount, even when the flow rate at the time of inflow varies, the variation in the flow rate can be suppressed within a desired range.

Thus, even if the flow rate at the time of inflow increases and fluctuates beyond the set flow rate at the time of outflow (for example, 1.0 [m ³ / Hour]), the flow rate at the time of outflow is substantially equal to the set flow rate. It will be stable within the target range centered on the quantity.

After the setting is completed, the flow control tank 1 is actually operated in a drainage system as shown in FIG. 8, for example.

The submersible pump 3 starts operating when the wastewater stored in the storage tank 2 reaches a predetermined water level, pumps this wastewater, and sends it to the flow control tank 1 via the water pipe 5. In the flow rate adjusting tank 1, the drainage flows from the inlet 1a.

Here, when the set flow rate of the drainage from the outlet 1b at the time of outflow is 1.0 [m ³ / Hour] as described above, for example, the drainage having a flow rate exceeding the set flow rate is set. When it flows in, the excess amount is used for overflow adjustment unit 1
2 and is discharged from the overflow port 1 c and returned to the storage tank 2 via the bypass pipe 6.

On the other hand, the portion which does not overflow is the outlet 1
It flows toward the b-side, substantially 1.0 [m ³ from the outlet 1b
/ Hour] at a predetermined flow rate in the vicinity.

If the flow rate of the wastewater flowing from the inlet 1a fluctuates, the overflow controller 12 responds accordingly.
The overflow flow rate of wastewater overflowing in
The wastewater discharged from the overflow port 1c and flowing out of the outlet 1b flows out at a flow rate within a predetermined range including 1.0 [m ³ / Hour], and has a temporally stable value.

Thus, a stable flow rate of wastewater flows into the treatment tank 4 of the purification facility via the water supply pipe 7.

When the flow rate of the waste water flowing from the inlet 1a is equal to or less than the set flow rate (for example, 1.0 [m ³ / Hour]), the waste water flows out of the outlet 1b as it is, but the target flow rate is Since it is set so as to be compatible with the water treatment capacity of the equipment at the subsequent stage of the flow rate adjusting tank 1, even if it changes abruptly, if it is within the range of the set outflow amount, it adversely affects the water treatment of the equipment. Never.

When the inventor actually performed a test using the flow rate adjusting tank 1 while changing the combination of the set outflow amount and the set inflow amount, the results shown in FIGS. 9 to 14 were obtained. Was.

First, the set outflow amount of water from the outflow port 1b (target outflow amount) is set to 1.0 [m ³ / Hour], and the height (over-height) of the lower edge of the opening 122a of the slide plate 122 is set. ) Was set to 191.3 [mm]. Next, in order to set the opening area, the amount of inflow of water (set inflow amount) from the inflow port 1a was substantially fixed at 3.0 [m ³ / Hour].
Then, in this state, the aperture 112a is squeezed,
The opening area is set while confirming the instruction of the scale plate 15, and the height of the upper edge of the opening, that is, the slide plate 113 is set.
The height of the lower edge (flow opening height of the flow control unit) is 9.15 [m
m]. Then, the outflow was measured while continuously changing the inflow of water.

As a result, as shown in FIG. 9, a curve showing a temporal change of the inflow amount and the outflow amount was obtained. In the figure, S11 is a curve showing a temporal change of the inflow amount, and S12 is a curve showing a temporal change of the outflow amount. Also, S13 indicates a set outflow amount, and S14 is a curve showing a temporal change of the outflow amount when there is no flow rate control unit for control.

Similarly, the set flow rate is set to 1.0 [m ³ /
Hour], the set inflow amount is 7.0 [m ³ / Hour], the overheight is set to 191.3 [mm], and the opening height of the flow control section is set to 6.3 [mm]. Then, the temporal change of the outflow amount was measured, and the result as shown in FIG. 10 was obtained.

In the figure, S21 is a curve showing a temporal change of the inflow amount, and S22 is a curve showing a temporal change of the outflow amount. S23 represents a target flow rate, and S24 is a curve showing a temporal change in the outflow rate when there is no flow rate control unit for control.

The set flow rate is set to 2.0 [m ³ / Hou
r], the set inflow amount is set to 7.0 [m ³ / Hour], the overheight is set to 204.6 [mm], and the flow control opening opening height is set to 12.1 [mm]. Then, the temporal change of the outflow amount was measured, and the result as shown in FIG. 11 was obtained.

In the figure, S31 is a curve showing the time change of the inflow amount, and S32 is a curve showing the time change of the outflow amount. S33 shows a set flow rate, and S34 is a curve showing a temporal change of the flow rate when there is no flow rate control unit for control.

Further, the set flow rate is set to 5.0 [m ³ / Hou
r], the set inflow amount is 10.0 [m ³ / Hour], the overheight is 218 [mm], and the inflow amount and outflow when the flow control opening height is 40.1 [mm]. The change of the amount with time was measured, and the result as shown in FIG. 12 was obtained.

In the figure, S41 is a curve showing a temporal change of the inflow amount, and S42 is a curve showing a temporal change of the outflow amount. In addition, S43 indicates a set outflow amount, and S44 is a curve indicating a temporal change of the outflow amount when there is no flow rate control unit for control.

The set flow rate is set to 5.0 [m ³ / Hou
r], the set inflow amount is 10.0 [m ³ / Hour], the overheight is 218 [mm], and the inflow amount and outflow when the flow control opening height is 40.1 [mm]. The change of the amount with time was measured, and the result as shown in FIG. 13 was obtained.

In the figure, S51 is a curve showing the time change of the inflow amount, and S52 is a curve showing the time change of the outflow amount. S53 represents a set flow rate, and S54 is a curve showing a temporal change of the flow rate when there is no flow rate control unit for control.

The set flow rate is set to 7.0 [m ³ / Hou].
r], the set inflow amount is 10.0 [m ³ / Hour], the overheight is set to 240.1 [mm], and the inflow amount and outflow when the flow control section opening height is set to 55 [mm]. The change of the amount with time was measured, and the result as shown in FIG. 14 was obtained.

In the figure, S61 is a curve showing a temporal change of the inflow amount, and S62 is a curve showing a temporal change of the outflow amount. Also, S63 indicates a set outflow amount, and S64 is a curve showing a temporal change of the outflow amount when there is no flow control unit for control.

FIGS. 9 to 1 obtained as a result of the experiment.
Based on the data of the temporal change of the inflow and the outflow shown in FIG. 4, the outflow change rate, which is the ratio of the deviation of the measured actual outflow from the set outflow to the set outflow, is shown for the corresponding inflow. I asked.

That is, the outflow rate change rate r [%] was obtained by Equation 4.

[0060]

(Equation 4) Where Qm is the measured actual outflow and Q0 is the set outflow.

From the outflow amount change rate, it is possible to know how far the actual outflow amount is from the set outflow amount. In other words, it can be seen that the closer the outflow rate change rate is to 0, the closer to the set outflow rate and the better the control is. Note that the outflow amount change rate is a positive value when the actual outflow amount changes in the increasing direction, and is a negative value when the actual outflow amount changes in the decreasing direction.

In each case shown in FIGS. 9 to 14,
The outflow rate change rate corresponding to the actual outflow rate was calculated using Equation 4, and the relationship between the corresponding inflow rate and outflow rate change rate, respectively, was obtained, as shown in FIGS. 15 to 20. The result was obtained.

In FIG. 15, S15 is a curve showing the relationship between the inflow rate and the outflow rate change rate when using the flow control tank according to the first embodiment, which is obtained based on the results shown in FIG.
Reference numeral 16 is a curve showing the relationship between the inflow rate and the outflow rate change rate when a tank without a flow rate control unit for control was used.

In FIG. 16, S 25 is a curve obtained based on the results shown in FIG. 10 and showing the relationship between the inflow rate and the outflow rate change rate when using the flow control tank according to the first embodiment. S26 is a curve showing the relationship between the inflow rate and the outflow rate change rate when a tank without a flow rate adjusting unit is used.

In FIG. 17, S35 is a curve showing the relationship between the inflow rate and the outflow rate change rate when the flow rate adjusting tank according to the first embodiment is used, obtained based on the results shown in FIG. S36 is a curve showing the relationship between the inflow amount and the outflow amount change rate when a tank without a flow rate adjusting unit is used.

In FIG. 18, S45 is a curve obtained based on the results shown in FIG. 12 and showing the relationship between the inflow amount and the outflow amount change rate when the flow regulating tank according to the first embodiment is used. S46 is a curve showing the relationship between the inflow amount and the outflow amount change rate when the tank without the flow rate adjusting unit is used.

In FIG. 19, S55 is a curve obtained based on the results shown in FIG. 13 and showing the relationship between the inflow rate and the outflow rate change rate when using the flow control tank according to the first embodiment. S56 is a curve showing the relationship between the inflow rate and the outflow rate change rate when a tank without a flow rate adjusting unit is used.

In FIG. 20, S65 is a curve obtained based on the results shown in FIG. 14 and showing the relationship between the inflow rate and the outflow rate change rate when using the flow control tank according to the first embodiment. S66 is a curve showing the relationship between the inflow rate and the outflow rate change rate when a tank without a flow rate adjusting unit is used.

According to the characteristic diagrams shown in FIGS. 15 to 20, in each case, the flow rate change rate when the flow rate adjusting tank according to the first embodiment having the flow rate adjusting section is used is determined by using the tank without the flow rate adjusting section. It can be seen that the width of the change rate of the outflow amount (the interval between the maximum change rate of the outflow amount and the minimum change rate of the outflow amount) is significantly smaller than the change rate of the outflow amount at the time of performing.

This is because the flow control tank according to the first embodiment suppresses the change in the outflow even when the inflow changes, that is, the outflow is kept substantially constant within a predetermined error. This indicates that control is performed so that

As described above, according to the first embodiment, the flow rate is adjusted by the initial setting of the flow rate adjusting unit 11 and the overflow adjusting unit 12, and the flow rate is obtained by directly reading the scale plate 15. Since there is no part that operates electrically and electronically, it is possible to perform a reliable and reliable flow rate adjustment that has a simple and inexpensive configuration and is less likely to cause a failure.

Also, once set, there is basically no need to make any changes and no power is required for control.
Also, replacement of parts is almost unnecessary, and as a maintenance check, the flow rate adjusting unit 11 and the overflow adjusting unit 12
In addition, only the cleaning of the V-notch plate of the weir plate 14 is required, and other work is hardly required. For this reason, the maintenance cost can be significantly reduced.

Although the embodiment of the present invention has been described in detail, the specific configuration is not limited to this embodiment.

For example, in the first embodiment described above, a case is described in which a triangular weir is used. However, the shape and the like of the weir plate are such that the apex angle is changed according to the range of the flow rate of the liquid to be handled. A relational expression between the water level and the flow rate corresponding to the above may be adopted.

The set flow rate is set to 1.0 [m ³ / Hour].
However, it is possible to design each component corresponding to the target flow rate, its adjustment accuracy, the inflow flow rate, and the like.For example, in addition to using a single flow rate adjustment tank, the same flow rate adjustment tank is used. May be connected in parallel to correspond to a larger inflow amount, or may be connected in series to increase accuracy.

The opening 122a of the slide portion 122
Although the case where the height of the lower edge is adjusted to the height corresponding to the target flow rate has been described, it is not always necessary to adjust to this height, for example, the height just before the overflow when flowing at a predetermined flow rate Good.

Further, the case has been described where the water is introduced at a set inflow amount of about 3.0 [m ³ / Hour] and the setting in the flow rate adjusting unit 11 is performed. It only needs to be understood that it is somewhat higher than the target flow rate.

Accordingly, although the flow rate on the inflow side is not necessarily measured, the flow rate is measured on the scale plate 15 with the lower edge of the opening 122a of the slide portion 122 sufficiently high. You can know by reading. Thereafter, the height of the lower edge of the opening 122a may be set, and the setting in the flow rate adjusting unit 11 may be performed.

The case has been described where the height of the lower edge of the opening 122a and the opening area of the opening 112a are set in advance before the flow regulating tank 1 is actually operated. Is possible.

Although the case where the setting of the opening area of the opening 112a is adjusted so as to be narrowed from the open state has been described, it is also possible to adjust the opening area from the narrowed state to open.

In addition, the case where the flow rate is obtained by using the weir has been described. However, the flow rate may be measured using another flow meter, or the flow meter may be provided separately.

Further, the shape of the opening of the fixed plate of the flow rate adjusting section does not necessarily have to be rectangular, and may be, for example, circular, V-shaped or trapezoidal.

Further, the fixed plate and the slide plate of the outflow amount adjusting unit may be directly attached to the most upstream clear stream plate. Further, the downstream straightening plate may be disposed so as to hang down.

The number of the inlet 1a, the outlet 1b, and the overflow 1c is not limited to one, but may be plural.

The liquid to be handled may be fresh water other than sewage, or liquid other than water.

[0086]

As described above, according to the first aspect of the present invention, the flow rate at the downstream side of the main flow path is based on the target flow rate, and the throttle amount in the throttle mechanism of the flow rate adjusting unit is
Since the flow rate is adjusted by setting the overflow height at the barrier of the overflow adjustment unit, a reliable and reliable flow rate adjustment with a simple and inexpensive configuration, which is unlikely to cause an obstacle, is performed. Can be.

Also, once set, there is in principle no need to make any changes and no control power is required.
Also, there is almost no need to replace parts, etc., and the maintenance work is reduced. For this reason, the maintenance cost can be significantly reduced.

According to the second aspect of the present invention, the throttle of the flow rate adjusting unit is controlled so that the flow rate on the downstream side of the main flow path measured by the flow rate measuring means is within a target range including the target flow rate. Since the flow rate is adjusted by setting the throttle amount in the mechanism and the overflow height at the barrier of the overflow adjustment unit, the flow rate on the outflow side can be accurately and accurately determined within a predetermined fluctuation range while having a simple and inexpensive configuration. It can be controlled reliably.

According to the third aspect of the present invention, the flow rate is adjusted by setting the flow rate adjusting section and the overflow adjusting section, and the flow rate value required at the time of setting is measured by using a weir. Since it is required by the display of the scale plate,
Since electrical and electronic control is not required, a more simple and inexpensive configuration can be achieved, and moreover, reliable and reliable flow control that does not easily cause a failure can be performed.

According to the fourth aspect of the present invention, in the flow rate adjusting section, the first slide section is displaced with respect to the first fixed section so that the opening of the first fixed section is opened. The flow rate of the liquid passing therethrough is adjusted by changing the area, and in the overflow adjusting section, the overflow height in the second slide section is reduced by displacing the second slide section with respect to the second fixed section. It changes and the amount of overflow is adjusted, so while having a simple and inexpensive configuration,
Setting can be performed easily and reliably, and highly reliable flow rate adjustment can be performed.

According to the fifth aspect of the present invention, the flow rate on the downstream side of the main flow path is based on the target flow rate, and the throttle amount in the throttle mechanism of the flow rate adjusting section, the overflow height in the barrier of the overflow adjusting section, Since the flow rate is adjusted by each setting, it is possible to perform a reliable and reliable flow rate adjustment that is simple and inexpensive but hardly causes trouble.

Further, once the settings are made, there is no need to modify them in principle, and no power is required for control.
Also, there is almost no need to replace parts, etc., and the maintenance work is reduced. For this reason, the maintenance cost can be significantly reduced.

[0093] According to the present invention, the throttle of the flow rate adjusting unit is controlled so that the flow rate on the downstream side of the main flow path measured by the flow rate measuring means is within a target range including the target flow rate. Since the flow rate is adjusted by setting the throttle amount in the mechanism and the overflow height at the barrier of the overflow adjustment unit, the flow rate on the outflow side is accurately and reliably controlled within a predetermined fluctuation range while being simple and inexpensive. be able to.

[Brief description of the drawings]

FIG. 1 is a plan view showing a configuration of a flow rate adjusting tank according to Embodiment 1 of the present invention.

FIG. 2 is a sectional view taken along line AA of FIG.

FIG. 3 is a sectional view taken along line BB of FIG. 1;

FIG. 4 is a sectional view taken along the line CC of FIG. 1;

FIG. 5 is a sectional view taken along the line DD of FIG. 1;

FIG. 6 is a front view showing a fixed plate and a slide plate of an outflow amount adjusting unit constituting the flow rate adjusting tank.

FIG. 7 is a front view showing a fixing plate and a slide plate of an overflow adjusting unit constituting the flow rate adjusting tank.

FIG. 8 is a diagram schematically showing a configuration of a drainage system to which the flow rate adjusting tank is applied.

FIG. 9 is a characteristic diagram showing a temporal change in an inflow amount and an outflow amount as a result of an actual test performed using the same flow rate adjustment tank.

FIG. 10 is a characteristic diagram showing a temporal change of an inflow amount and an outflow amount as a result of an actual test performed using the same flow rate adjustment tank.

FIG. 11 is a characteristic diagram showing a temporal change in an inflow amount and an outflow amount as a result of an actual test performed using the same flow rate adjustment tank.

FIG. 12 is a characteristic diagram showing a temporal change of an inflow amount and an outflow amount as a result of an actual test performed using the flow rate adjusting tank.

FIG. 13 is a characteristic diagram showing a temporal change in an inflow amount and an outflow amount as a result of an actual test performed using the same flow rate adjustment tank.

FIG. 14 is a characteristic diagram showing a temporal change of an inflow amount and an outflow amount as a result of an actual test performed using the same flow rate adjustment tank.

FIG. 15 is a characteristic diagram showing a relationship between the inflow amount and the outflow amount change rate obtained from the temporal change of the inflow amount and the outflow amount shown in FIG. 9;

FIG. 16 is a characteristic diagram showing a relationship between an inflow amount and an outflow amount change rate obtained from the temporal change of the inflow amount and the outflow amount shown in FIG.

FIG. 17 is a characteristic diagram showing a relationship between the inflow amount and the outflow amount change rate obtained from the temporal change of the inflow amount and the outflow amount shown in FIG.

FIG. 18 is a characteristic diagram showing a relationship between the inflow amount and the outflow amount change rate obtained from the temporal change of the inflow amount and the outflow amount shown in FIG.

FIG. 19 is a characteristic diagram showing a relationship between the inflow amount and the outflow amount change rate obtained from the temporal change of the inflow amount and the outflow amount shown in FIG.

FIG. 20 is a characteristic diagram showing a relationship between the inflow amount and the outflow amount change rate obtained from the temporal change of the inflow amount and the outflow amount shown in FIG.

FIG. 21 is an explanatory diagram for explaining a conventional technique,
It is a characteristic diagram which shows the relationship between the head of a pump and a discharge amount as a performance example of a pump.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Flow control tank 1a Inflow port 1b Outflow port 1c Overflow port 11 Outflow amount adjustment unit 111 Rectifier plate 112 Fixed plate (first fixed unit) 112a Opening 113 Slide plate (first slide unit) 12 Overflow adjustment unit 121 Fixed Plate (second fixed portion) 122 Slide plate (barrier, second slide portion) 122a Opening 13 Rectifier plate 13a Opening 14 Weir plate (flow rate measuring means, weir) 15 Scale plate (flow rate measuring means, measuring scale) Board)

Claims (6)

[Claims] 1. An inflow port for receiving an inflow liquid, an outflow port for discharging a liquid toward a predetermined supply destination, and a main flow path arranged from the inflow port to the outflow port and passing therethrough. A weir-shaped flow rate adjusting unit having a throttle mechanism for adjusting the flow rate of the liquid; and an overflow adjusting unit having a barrier for overflowing a liquid exceeding a predetermined overflow height, of the liquid flowing from the inflow port. By adjusting the throttle amount in the throttle mechanism of the flow rate adjusting unit and the overflow height at the barrier of the overflow adjusting unit, the downstream flow rate of the main flow path is set to the target flow rate. And a flow control tank. 2. An inflow port for receiving an inflowing liquid, an outflow port for discharging a liquid toward a predetermined supply destination, and an overflow port for overflowing and discharging a part of the liquid that has flowed in once. A weir-shaped flow control unit disposed on the main flow path from the inflow port to the outflow port and having a throttle mechanism for adjusting the flow rate of the passing liquid; and the flow control unit on the main flow path is disposed. An overflow, which is arranged on a branch path that branches to the overflow port on the upstream side of the divided portion and that overflows a liquid exceeding a predetermined overflow height among liquids flowing from the inlet. An adjusting unit, comprising: a flow rate measuring unit for measuring a flow rate on the downstream side of the main flow path, based on a flow rate measured by the flow rate measuring unit. hand,
By adjusting the throttle amount in the throttle mechanism of the flow rate adjusting unit and the overflow height at the barrier of the overflow adjusting unit, the liquid downstream of the main flow path when the liquid of a predetermined range flows from the inlet. A flow rate adjusting tank, wherein a side flow rate is set to be a flow rate within a target range including a target flow rate. 3. The weir having a predetermined shape and size arranged upstream of the outlet and a weir arranged upstream of the weir, and having at least the shape and size of the weir. A measurement scale plate on which a flow value corresponding to the liquid level is displayed, based on a predetermined relationship between the corresponding flow rate and the liquid level, and a barrier of the overflow adjusting unit. The overflow height at
Adjustment is made so as to substantially match the liquid level height corresponding to the target flow rate in the measurement scale plate, and the amount of throttle in the throttle mechanism of the flow rate adjustment unit is adjusted by adjusting the overflow height at the barrier of the overflow adjustment unit. The flow rate adjusting tank according to claim 2, wherein the flow rate measured by the measurement scale plate is adjusted to be a flow rate within the target range in the set state. 4. The throttle mechanism of the flow rate adjusting unit, wherein a first fixing unit through which liquid passes at an opening provided at a bottom portion, and the opening mechanism is slidably attached to the first fixing unit. And a first slide portion that opens and closes, and the first slide portion is displaced with respect to the first fixed portion, so that the opening area of the opening changes and the flow rate of the liquid passing therethrough. The overflow adjustment unit includes a second fixing unit and the second fixing unit.
A second slide part slidably attached to the fixed part of the second part and causing the liquid to overflow at the upper part. The second slide part is displaced with respect to the second fixed part, whereby the second part is displaced. 4. The flow control tank according to claim 2, wherein the overflow height at the upper part of the slide portion changes to adjust the overflow amount. 5. A constant outflow amount adjustment method for setting a discharge flow rate to a target value by adjusting first and second flow rate adjustment units provided on a path from an inlet to an outlet. Is an overflow adjusting section, the second adjusting section is a weir-shaped adjusting section, and the discharge flow rate is set to a target value by relative adjustment of the first and second flow rate adjusting sections. Constant flow adjustment method. 6. A constant outflow amount adjusting method for setting a discharge flow rate to a target value by adjusting first and second flow rate adjustment units provided on a path from an inlet to an outlet. The adjusting section is an overflow adjusting section having a barrier for overflowing the liquid exceeding a predetermined overflow height, and the second adjusting section is a weir-shaped adjusting section having a throttle mechanism for adjusting the flow rate of the passing liquid. While obtaining the discharge flow rate in the vicinity of the outflow port and monitoring the discharge flow rate, so that the discharge flow rate when a liquid in a predetermined range of flow rate flows in from the inflow port is a flow rate within a target range, A constant outflow amount adjusting method, wherein an overflow height at a barrier of the first adjustment unit and a throttle amount of a throttle mechanism of the second adjustment unit are relatively adjusted.