JPH094567A - Water feeding device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To realize a countermeasure when the pressure on the stable inflow side drops without frequently repeating the start and stop of a pump when the inflow side pressure is dropped in a direct connection type water feeding device. SOLUTION: A control means outputs the forcible stop signal to stop a pump when the condition in which the inflow pressure is lower than the preset pressure value P1 continues for the prescribed period T1 of time, and/or the alarm signal. When the condition in which the inflow pressure PS is higher than the preset pressure value P1 continues for the prescribed period T2 of time, the control means automatically releases the output of the forcible stop signal and/or the alarm signal, and the pump speed is gradually accelerated when the pump is started.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a water supply system, and more particularly to a so-called direct connection type water supply system in which a main water distribution pipe is directly connected to an end water supply system via a pressure pump.

[0002]

2. Description of the Related Art FIG. 1 shows an example of a system configuration of such a water supply device. The inflow side of the pump is provided with a water supply pipe 12 connected to a water distribution main pipe, and the discharge side of the pump 10 is provided with a discharge pipe 13 connected to a terminal water supply device. A check valve 18 is inserted on the discharge side of the pump 10 so that when the pump 10 is stopped, water does not flow back from the discharge side to the inflow side. In addition, the inflow side and the discharge side of the pump 10 are bypassed by the connecting pipe 19, and when the pressure of the water distribution main pipe increases and exceeds the target discharge pressure of the pump, the discharge pipe 13 is directly bypassed without the pump 10. It is designed to supply water. The connection pipe 19 is also provided with the check valve 18 for the same reason as described above. Pressure tanks 14, 15
Is provided to moderate pressure fluctuations on the inflow side and discharge side of the pump, and serves as a buffer for the water distribution main pipe and the terminal water supply equipment side.

The pump 10 is driven at a variable speed by a motor 11 having a frequency / voltage converter (inverter) 21 connected to a three-phase AC commercial power supply. Control unit 22
Sends a signal to the variable speed means 21 based on signals from the inflow pressure detector 16 and the discharge pressure detector 17 to control the speed of the pump 10 to accelerate or decelerate to an arbitrary speed.

A pressure detector 17 is provided on the discharge side of the pump 10 to detect the discharge pressure of the pump 10. The pump discharge pressure signal detected by the pressure detector 17 is transmitted to the control unit 22, and the motor 11 that drives the pump 10 is controlled by the inverter 21 at a variable speed. In other words, the control unit 22 controls the motor 11 at a variable speed so that a constant water pressure is always supplied to the terminal water supply device connected to the discharge side even if the pressure on the inflow side of the pump 10 fluctuates.

[0005] A pressure detector 16 is also provided on the inflow side of the pump 10 to constantly monitor the pressure on the inflow side of the pump 10.
In general, water distribution mains such as water supply branches into a number of water supply pipes, from which water is supplied to a number of terminal water supply equipment. For this reason, when the water pressure of the water distribution main pipe decreases, the water pressure of a large number of water supply pipes decreases, and problems such as insufficient water output at the terminal water supply equipment occur. For this reason, when the pressure of the water distribution main pipe is reduced, if the operation of the pump is continued, the water pressure on the inflow side of the pump is further reduced. In addition, when the pump inlet side has a negative pressure due to the operation of the pump, drainage, rainwater, and the like may enter the water supply pipe 12 from the outside. When the pressure on the pump inflow side drops below a certain value due to these circumstances, first, a decrease in this pressure is detected, and countermeasures are taken when the inflow side pressure drops, such as by stopping the pump.

JP-A-5-118280, JP-A-5-118280
According to JP-A-263444, JP-A-5-240186, etc., by keeping the pressure on the discharge side of the pressurizing pump constant, the pump can be constantly supplied to the terminal water supply equipment with a stable constant pressure. There is disclosed a technique for increasing and decreasing the speed. In addition, when the pressure on the inflow side of the pump decreases, the speed of the pump is reduced or stopped to prevent the pressure on the distribution main line from decreasing, so that the water pressure does not decrease in the distribution main line. And the like are disclosed.

The specification and drawings attached to Japanese Utility Model Application No. Hei 3-16602 (Japanese Utility Model Application No. 3-16602) disclose an example of a conventional control flow when the inflow-side pressure drops. In this control flow, the inflow pressure is detected first, and then the inflow pressure is compared with a set value. If the inflow pressure is higher than the set value, the operation is continued as it is because the inflow pressure is not at a level to be protected. If the inflow pressure is lower than the set value, it is at the inflow pressure protection level, so that an alarm signal is output and the pump is stopped.

[0008]

However, there is a phenomenon that the inflow pressure drops temporarily for several seconds when the pump is started. Conventionally, there has been a problem that the pump is stopped due to a temporary decrease in the inflow pressure when the pump is started. Even if the pump stop signal is automatically canceled when the pump inflow side becomes higher than the set pressure, the pump stops when the inflow pressure drops when the pump starts, and returns when the pump stops. Because the pump starts immediately. When the pump is started, there is a problem that the operation of stopping immediately after the inflow pressure is reduced is repeated.

The present invention has been made in view of the above circumstances, and in a direct connection type water supply device, when the inflow-side pressure is reduced, the pump is not frequently started and stopped repeatedly.
An object of the present invention is to provide a water supply device capable of taking a stable measure when the inflow-side pressure drops.

[0010]

A water supply device according to a first aspect of the present invention is an inflow pipe connected to a water distribution pipe, a pressurizing pump connected to the inflow pipe, and a discharge side of the pressurizing pump. A discharge pipe connected to the terminal water supply device, an inflow pressure detector for detecting the inflow pressure of a pressurizing pump connected to the inflow pipe, and a control means for controlling the pump,
The control means outputs a stop signal and / or an alarm signal for forcibly stopping the pump when the inflow pressure is lower than a predetermined pressure set value (P1) for a certain time (T1). After that, when the state where the inflow pressure is higher than the pressure set value (P1) continues for a certain time (T2), the operation of automatically releasing the output of the forced stop signal and / or the alarm signal is performed. The pump speed is slowly accelerated when the pump is started.

The water supply apparatus of the second aspect of the present invention is an inflow pipe connected to a water distribution pipe, a pressure pump connected to this inflow pipe, and a terminal water supply device connected to the discharge side of this pressure pump. A discharge pipe connected to the inflow pipe, an inflow pressure detector for detecting the inflow pressure of a pressurizing pump connected to the inflow pipe, and a control means for controlling the pump. Output a stop signal and / or an alarm signal for forcibly stopping the pump when the pressure is lower than a preset pressure setting value (P1) for a certain time (T1), and then the inflow pressure is increased. The operation of automatically releasing the output of the forced stop signal and / or the alarm signal when the state higher than the set value (P1) continues for a certain time (T2), and starts and stops the pump. Becomes more frequent When, characterized in that so as to slowly accelerate the pump speed when starting the pump.

According to the first aspect of the present invention, the temporary decrease in the inflow pressure when the pump is started is that the inflow pressure is lower than the inflow pressure set value (P1) for a certain period (T1). As a result, the forced stop signal of the pump or the alarm signal is output, so that the pump will not be stopped or the alarm will not be inadvertently issued.

Further, when the inflow pressure is recovered, if the inflow pressure continuously exceeds the inflow pressure set value (P1) for a certain time (T2) or more, the pump is forcibly stopped and / or an alarm signal is issued. Since the output is automatically released, the pump can be started or the alarm can be released when the inflow pressure is reliably recovered, and the problem that the pump is repeatedly started and stopped near the inflow pressure set value (P1) Is prevented.

Further, after the inflow pressure is recovered, the pump is accelerated more slowly than usual when it is started, so that the pressure is not temporarily decreased on the inflow side, and the pump can be repeatedly started and stopped. To be prevented.

Even under such a condition, when the amount of water used by the user is large, the inflow pressure lowered due to some reason does not return, the pump stops, and the inflow pressure returns when the pump stops. , Pump starts again. When the pump is started, the inflow pressure may not be recovered within the above-mentioned fixed time T1 and the pump may be stopped.

In a second aspect of the invention, the duration (T
Despite the setting of 1 and T2), when a repeated phenomenon of starting and stopping occurs, this is detected and the pump speed is slowly accelerated. By slowly starting the pump over time, it is possible to suppress the pressure drop on the inflow side, and even under such use conditions,
The pump can be restarted reliably by preventing repeated start and stop.

[0017]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to the accompanying drawings. The same reference numerals in the drawings indicate the same or corresponding parts.

Also in this embodiment, the system configuration in which the pressurizing pump 10 is directly connected to the water supply pipe 12 and water is directly connected to the terminal water supply equipment from the discharge pipe 13 is as shown in FIG.
The pressure of the pressurizing pump 10 is controlled by a variable speed means 21 such as an inverter so as to increase or decrease the pump rotation speed based on a signal from the discharge pressure detector 17 so that the supply water pressure on the pump discharge side is constant. In addition, when the inflow pressure is reduced, an inflow pressure control for warning or forcibly stopping the pump is performed as described below, when the pressure becomes lower than a predetermined set pressure so as not to adversely affect the water distribution main pipe.

FIG. 2 shows the configuration of the control portion of the water supply system according to the first embodiment of the present invention. The pressure Ps on the inflow side of the pressurizing pump 10 is input from the inflow pressure detector 16 to the control unit 22. The control times of the timers T1, T2 and the like are set in the control unit 22 in advance. Further, an inflow pressure set value P1 for forcibly stopping the pump and / or generating an alarm is set. The pressure set value P1 is, for example, a pressure of about 10 mAq which may adversely affect the water distribution main pipe.

The time T1 is a duration for outputting an alarm signal or a forced stop signal when the inflow pressure Ps lower than the first pressure setting value P1 continues, and in this embodiment, the time T1 is used. It takes about 30 seconds. And time T
Reference numeral 2 denotes a continuation time when the forced stop signal or the warning signal is automatically released when the state where the inflow pressure is higher than the pressure set value P1 continues, and is about 6 seconds in this embodiment.

As a means for slowly starting the pump, the soft start / soft stop timer of the inverter 21 is set to 3 to 5 seconds in a normal water supply apparatus. It is to accelerate slowly from the input of to accelerate to a predetermined speed.

FIG. 3 shows a control flow when the inflow pressure is reduced according to an embodiment of the present invention. First, the inflow pressure Ps is read from the inflow pressure detector 16. Then, it is compared whether the inflow pressure Ps is higher or lower than the set pressure P1. Set pressure P1
If it is lower than this, it is determined whether or not this state has continued for the time of the timer T1. If continued, "YES"
And a forced stop and / or an alarm signal is output. In the case of "NO", the forced stop and / or the alarm signal is not output.

Next, the inflow pressure is restored, and it is compared whether the inflow pressure Ps is higher or lower than the set pressure P1. If the inflow pressure Ps is higher than the set pressure P1, the timer T2
During this time, it is determined whether or not this state has continued. "Y
In the case of "ES", it is determined that the inflow pressure has recovered, and the pump is slowly started and / or the alarm signal is released. If not continued, the result is "NO" and the forced stop and / or The alarm signal is not canceled.

FIG. 4 shows the operating state of the pump when the inflow pressure drops according to the control flow described above. Inlet pressure Ps in some state at time t ₁ as illustrated is to suddenly decreases. In this case, it is confirmed whether or not the state in which the inflow pressure Ps is lower than the set pressure P1 has continued for the time of the timer T1. In this case, the inflow pressure returns,
Since the pressure exceeds the set pressure P1 within this time (T1), the state of Ps <P1 does not continue for the time of the timer T1, so that the pump is not forcibly stopped and / or an alarm signal is not output.

Next, it is assumed that at time t ₂ , the inflow pressure Ps drops and becomes lower than the set pressure P 1, and at time t ₃ the time of the timer T 1 has elapsed. Inlet pressure Ps, the state of being lower than the set pressure P1 was the duration T1, the pump suspended at time t _3, and or, an alarm signal is output. When the pump forced stop signal is output, the control unit 22 sends a stop signal to the inverter 21 to stop the pump. When an alarm signal is output, the control unit 22
Informs the observer of a drop in the inlet pressure by means such as sounding a buzzer from a control panel or turning on an alarm lamp. The observer determines the situation and takes measures such as forcibly stopping the pump.

Since the pump forced stop signal and the alarm signal have a relationship of and / or, both may be performed simultaneously,
Further, only one of them may be performed alone. This is appropriately selected according to the individual situation of the water supply device.

When the pump is stopped, the inflow pressure Ps is temporarily restored. However, when the decrease in the inflow pressure Ps is caused by the water distribution main pipe and continues thereafter, the inflow pressure Ps falls again below the set pressure P1. At time t _4, the inflow pressure Ps is set pressure P1
Therefore, the timer T2 is operated, and it is determined whether or not the inflow pressure Ps exceeds the set pressure P1 during this time. In this embodiment, since the inflow pressure Ps immediately returns to a state below the set pressure P1, the forced stop signal of the pump and / or the alarm signal is not canceled.

After that, the pressure in the water distribution main is recovered, the inflow pressure Ps of the pump is gradually increased, and the set pressure P1 is set to the time t.
Let's say we exceeded ₅ . Timer T2 is activated at time t _5, this time, whether the inflow pressure Ps exceeds the preset pressure P1 is determined. In this case, time of the timer T2, and the state where the inflow pressure Ps exceeds the set pressure T1 is certain that continues, slowly start the pump at the time t ₆ after the elapse of time T2, and or, Release the alarm signal. When the pump is started slowly, the problem of a temporary decrease in the inflow pressure does not occur, so that the problem of repeated start and stop of the pump does not occur.

Incidentally, in the conventional operation system, when the pressure becomes lower than the set pressure P1 at time t1, the pump is stopped, and when the inflow pressure is restored to the set pressure, the pump is started. When the pump starts, the pressure on the inflow side drops for a few seconds, and the pump stops again. Such a state in which the pump is repeatedly started and stopped has occurred. According to the above-described control flow, such a problem is prevented.

FIG. 5 shows the configuration of the control portion of the water supply system according to the second embodiment of the present invention. The pressure Ps on the inflow side of the pressurizing pump 10 is input from the inflow pressure detector 16 to the control unit 22. The control times of the timers T1, T2 and the like are set in the control unit 22 in advance. Further, a pressure set value P1 is set. The pressure set value P1 is, for example, 15 mAq to 5 m.
This is a set pressure for protecting the pump suction from about Aq. The timer time T1 outputs an alarm signal when the state where the inflow pressure Ps is lower than the pressure set value P1 continues for this time.
Alternatively, it is a continuation time for outputting the forced stop signal, which is about 6 seconds in this embodiment. The timer time T2 is a continuation time when the forced stop signal or the warning signal is automatically released when the state where the inflow pressure is higher than the pressure set value P1 continues, and is also about 6 seconds.

The control device 22 of this embodiment is provided with a start / stop frequency detecting means 23 and a means 24 for slowly accelerating the pump speed. That is, if the start and stop of the pump are frequently repeated, this is detected and the pump speed is slowly increased when the pump is started. For example, if the start / stop of the pump is repeated about 3 to 4 times per minute, the acceleration time is increased from the usual 3 to 5 seconds to about 10 to 20 seconds.

FIG. 6 shows a control flow when the inflow pressure is reduced according to the second embodiment of the present invention. First, the inflow pressure Ps is read. Then, it is compared whether the inflow pressure Ps is higher or lower than the set pressure P1. If the pressure is lower than the set pressure P1, it is determined whether or not this state has continued for the time of the timer T1. If continued, the determination is "YES" and a forced stop and / or an alarm signal is output. In the case of "NO", the forced stop and / or the alarm signal is not output. When the inflow pressure Ps becomes higher than the set pressure P1,
It is determined whether this state has continued for the time of the timer T2. If "YES", forced stop and / or
If the alarm signal is released and the alarm signal is not continued, the result is "NO", and the forced stop and / or the alarm signal is not released.

Up to the above, the control flow is the same as that of the first embodiment, but when the amount of water used is large, the start and stop of the pump may be repeated frequently. In this embodiment, the start / stop frequency is detected by the detection unit 23,
Compare with a fixed value (for example, 4 times per minute). If the start / stop frequency is equal to or more than a certain value, the delay time of the timer T1 is increased to, for example, about 10 seconds or more.

FIG. 7A shows the operating state of the pump when the inflow pressure drops according to the control flow of the conventional example.
Inlet pressure for any state at time t ₁ as illustrated is to suddenly decreases. In this case, the continuation time of the timer T1 is checked, during which the pump inlet pressure Ps
If has not recovered, the pump stops (time t ₂ ). Then, the pump inflow side pressure Ps recovers to the set pressure P1,
When the continuation time T2 has elapsed, the pump will start immediately (time t _3). When the pump is started, especially when the amount of water used is large, the pressure on the inflow side temporarily drops again. If the inflow side pressure Ps has not recovered again after the time T1, the pump stops. Thus, starting and stopping of the pump are repeated.

In the present embodiment shown in FIG. 7B, the frequency of starting and stopping this pump is measured. When a certain number of repetitions is detected, the start-up time of the pump is automatically extended. That is, the pump is started slowly by slowly increasing the pump speed. In this embodiment, the repetition of start and stop of the pump between times t ₄ from the time t ₂ is detected, the t ₅ from time t _4, the pump is started slowly. When the pump is started slowly, the temporary pressure drop on the inflow side is small, and does not drop below the set pressure P1 as shown. For this reason, repetition of subsequent start and stop is prevented.

The starting time for slowly starting the pump may be set in accordance with the magnitude of the start / stop frequency. Also, the length may be gradually increased until repetition of start-stop is suppressed, and finally, an appropriate length may be stored in the storage device to be used for the next pump inflow side pressure drop protection. Good.

In a normal water supply device, the inverter 21
The soft start / soft stop timer is normally set to 3 to 5 seconds. Prolonging this time prevents the inflow pressure from temporarily lowering when the pump is started up, but on the other hand gives the terminal water supply equipment an unpleasant feeling that the water pressure of the water supply does not increase. In each of the above-described embodiments, only in the case of the restart after the forced stop, the time for slowly rising is increased to 10 seconds or more. In this case, since the pump is once forcibly stopped, the length of time for which the user of the terminal water supply device stands up at the time of restart does not matter much.

Further, in the water supply device, when the amount of water to be supplied is small, a small water amount stop operation for temporarily stopping the pump may be performed in order to prevent the shutoff operation of the pump. However, in the restart from the forced stop of the pump as in the above-described embodiment, unlike the small amount of water stop operation, the faucet of the terminal water supply device is open and a large amount of water flows at the time of restart, and the inflow pressure is increased. There is a concern that it will temporarily decrease at the time of startup. Under such conditions, it is not necessary to supply water of sufficient pressure to the user as soon as possible, and it is also important for the user to start the pump slowly and restart the water supply slowly. It is also advantageous for the water supply device side.

Although the above embodiments have been described with respect to the water supply device connected to the terminal water supply equipment from the water supply mains of the water supply, the gist of the present invention is widely applicable to water supply control devices using pumps in general. It is a thing. Further, in the above-described embodiment, the example in which the discharge pressure control by the variable speed motor drive is used is described. However, the discharge pressure control does not necessarily need to be used in combination, and may be performed independently when the inflow pressure decreases. That is, of course.

[0040]

As described above, according to the first aspect of the present invention, in the direct connection type water supply device, when the inflow pressure decreases, an alarm is immediately output or the pump is stopped as in the conventional case. Instead, the pump is forcibly stopped or an alarm is output after the condition is maintained for a certain confirmation time. Therefore, even when the inflow pressure is reduced, the pump is not forcibly stopped inadvertently, so that stable water supply can be secured. Also, since the pump is slowly accelerated when starting from a forced stop, it is possible to avoid the problem that the inflow pressure temporarily drops when starting the pump, and to reliably restart the pump. Start up like
There are no troubles such as repeated stops.

In the second aspect of the present invention, when the pressure on the inflow side of the pump decreases when the amount of water used is large and the start and stop are repeated, the frequency of start and stop is detected to slowly move the pump. It is designed to be activated. This ensures that the pump can be restarted even when the amount of water used is large.

[Brief description of drawings]

FIG. 1 is an explanatory diagram of a system configuration of a direct connection type water supply device.

FIG. 2 is an explanatory diagram showing a configuration of a control unit according to the first embodiment of the present invention.

FIG. 3 is a control flow chart when the inflow pressure drops according to the first embodiment of the present invention.

FIG. 4 is a time chart showing the operation of the water supply device according to the control flow chart.

FIG. 5 is an explanatory diagram illustrating a configuration of a control unit according to a second embodiment of the present invention.

FIG. 6 is a control flow chart when the inflow pressure drops according to a second embodiment of the present invention.

FIG. 7A is a time chart of a conventional example,
(B) is a time chart showing the operation of the water supply device according to the control flow chart.

[Explanation of symbols]

 Reference Signs List 10 pump 11 motor 16 inflow pressure detector 21 inverter (variable speed means) 22 control unit Ps inflow side detection pressure P1 inflow side set pressure T1, T2 timer time

Claims (2)

[Claims] 1. An inflow pipe connected to a water distribution pipe, a pressurizing pump connected to the inflow pipe, a discharge pipe connected to a discharge side of the pressurizing pump and connected to an end water supply device, An inflow pressure detector for detecting an inflow pressure of a pressurizing pump connected to the inflow pipe and a control means for controlling the pump are provided, and the control means has a preset pressure value (P1) for the inflow pressure. A stop signal forcibly stopping the pump when the lower temperature continues for a certain time (T1), and /
Alternatively, an operation of outputting an alarm signal and then automatically canceling the output of the forced stop signal and / or the alarm signal when the state where the inflow pressure is higher than the pressure set value (P1) continues for a certain time (T2). A water supply device for performing the above, wherein the pump speed is slowly accelerated when the pump is started. 2. An inflow pipe connected to a water distribution pipe, a pressurizing pump connected to the inflow pipe, a discharge pipe connected to a discharge side of the pressurizing pump and connected to an end water supply device, An inflow pressure detector for detecting an inflow pressure of a pressurizing pump connected to the inflow pipe and a control means for controlling the pump are provided, and the control means has a preset pressure value (P1) for the inflow pressure. A stop signal forcibly stopping the pump when the lower temperature continues for a certain time (T1), and /
Alternatively, an operation of outputting an alarm signal and then automatically canceling the output of the forced stop signal and / or the alarm signal when the state where the inflow pressure is higher than the pressure set value (P1) continues for a certain time (T2). The water supply device according to claim 1, wherein the pump speed is slowly accelerated when the pump is started when the frequency of starting and stopping the pump is high.