JP2001065463A - Water feeding device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent the frequent repetition of start and stop of operation of a pump to increase the service life of the pump, reduce power consumption to improve energy saving, prevent a large current from flowing at the start of the pump to prevent a voltage drop from occurring to the other electric devices, and provide a sufficient noise suppressing function. SOLUTION: This water feeding device is formed so that an inverter 20 is provided for feeding a drive power to an electric motor 1M of a submerged pump 1, and the output frequency of the inverter 20 is controlled so that a feed water pressure becomes a specified constant value. In addition, a noise filter 12 is provided on the input side of the inverter 20, a reactor 13 is provided at the rectifying rear stage of the inverter 20, and a noise filter 14 is provided on the output side of the inverter 20.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a water supply device for supplying water to a shower or a water heater.

[0002]

2. Description of the Related Art In a water supply device for supplying water to a predetermined place by operating a pump, when water is used on a water receiving side, the pressure of water in a water supply pipe decreases. This pressure drop is detected by the operation of the pressure switch, and the operation of the pump is started.

[0003] When the use of the water on the receiving side ends, the flow rate of the water in the water supply pipe decreases. This flow decrease is detected by the operation of the flow switch, and the operation of the pump is stopped.

[0004]

As described above, merely controlling the operation of the pump in accordance with the pressure and flow rate of the water supply may cause the pump to repeatedly start and stop frequently, adversely affecting the life of the pump. is there. In addition, the repetition of the operation / stop causes an increase in power consumption, and greatly impairs energy saving. In addition, a large current flows when the pump is started, which may cause a voltage drop in other electric devices such as a home air conditioner, a refrigerator, and a vacuum cleaner.

[0005] The present invention has been made in view of the above circumstances,
Its purpose is to prevent frequent repetition of operation and stop of the pump, thereby improving the service life of the pump, reducing power consumption and improving energy saving, and further increasing the large current when starting the pump. Can be eliminated to prevent a voltage drop to other electrical devices,
Moreover, it is an object of the present invention to provide a water supply device having a sufficient function of suppressing noise generation.

[0006]

According to a first aspect of the present invention, there is provided a water supply apparatus for supplying water by operating a pump driven by an electric motor; an AC voltage is rectified and the rectified DC voltage is supplied. To an AC voltage having a predetermined frequency and outputting the AC voltage as drive power for the electric motor; control means for controlling the output frequency of the inverter so that the pressure of the feedwater becomes a predetermined value; and an input side of the inverter. A noise filter provided on the output side of the inverter; and a noise filter provided on the output side of the inverter.

According to a second aspect of the present invention, there is provided a water supply apparatus which uses a motor as a power source to suction and discharge water; a water supply pipe for sending water discharged from the pump to a predetermined place; A pressure accumulating means connected to a water supply pipe and accumulating a water supply pressure; a rectifier circuit for rectifying a voltage of an AC power supply; and a switching circuit for converting an output voltage of the rectifier circuit into an AC voltage having a predetermined frequency. A noise filter provided between the AC power supply and the rectifier circuit; a reactor provided between the rectifier circuit and the switching circuit; between an output terminal of the inverter and the motor. A noise filter provided in the water supply pipe; a pressure detection means for detecting a pressure of water in the water supply pipe; a flow rate detection means for detecting a flow rate of water in the water supply pipe; When the detected pressure of the stage becomes less than the set value, the operation of the inverter is started to gradually increase the output frequency of the inverter, and thereafter, the output frequency of the inverter is controlled so that the detected pressure of the pressure detecting means becomes a predetermined value. Control means for stopping the operation of the inverter when the flow rate detected by the flow rate detection means is less than a set value;
Is provided.

According to a third aspect of the present invention, in the water supply apparatus according to the first or second aspect, the electric motor is an induction motor, a permanent magnet rotary motor, or a permanent magnet rotary motor having no magnetic pole position detector. Either.

According to a fourth aspect of the present invention, in the water supply device according to the second aspect, the rectifier circuit includes a three-phase two-phase AC power supply.
The type differs depending on whether it is a 00V power supply, a single-phase 200V power supply, or a single-phase 100V power supply.

[0010]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to the drawings.

As shown in FIG. 1, a submersible pump 1 is put into the water of a well 3 formed on the ground 2. Submersible pump 1
Uses a motor 1M described later as a power source to suction and discharge water, and may be any of a dry type, a cand type, and the like. In addition, since the submersible pump 1 is used in a state of being immersed in water, there is a feature that noise during operation is small.

One end of a water supply pipe 4 is connected to a discharge port of the submersible pump 1, and the other end of the water supply pipe 4 is extended to a place where water is required to be received.

A check valve 5 is provided at one end of the water supply pipe 4, a flow detector 6 is provided at an intermediate portion, and a pressure tank (also referred to as an accumulator) is provided downstream of the flow detector 6.
7 is communicated. Further, a pressure detector 8 is attached downstream of the flow detector 6.

The flow rate detector 6 detects the flow rate F of water in the water supply pipe 4.
And outputs a logic "1" signal when the flow rate F is equal to or greater than the set value Fs, and outputs a logic "0" signal when the flow rate F is less than the set value Fs.

The pressure tank 7 functions as pressure accumulating means for accumulating the supply water pressure. The pressure detector 8 detects the pressure P of water in the water supply pipe 4. The CPU outputs a logic "1" signal when the pressure P is equal to or higher than the set value Ps, and outputs a logic "0" signal when the pressure P is lower than the set value Ps. Judge as output.

The submersible pump 1, the flow detector 6, and the pressure detector 8 are connected to the control unit 10. Control unit 1
Numeral 0 controls the whole of the water supply device, and has a configuration shown in FIG.

That is, a three-phase AC power supply (three-phase 200 V)
11 is connected to an inverter 20 via a noise filter 12. The inverter 20 includes a rectifier circuit 30 for rectifying an AC voltage, a smoothing capacitor 21 for smoothing a DC voltage output from the rectifier circuit 30, and switching for converting a DC voltage passed through the smoothing capacitor 21 to an AC voltage having a predetermined frequency. The circuit 40 is configured.

The rectifier circuit 30 includes a series circuit of rectifier diodes 31 and 32 corresponding to each phase of the three-phase AC voltage, a series circuit of rectifier diodes 33 and 34, and a rectifier diode 3.
It consists of 5,36 series circuits, and has a three-phase AC voltage (200
V) is rectified. The rectified DC voltage (280 V) is supplied to the switching circuit 40 via the smoothing capacitor 21.

The switching circuit 40 includes a series circuit of transistors 41 and 42 which are switching elements,
Series circuit of transistors 43 and 44, transistor 4
5 and 46 series circuits. A damper diode D for preventing back electromotive force is connected in parallel between the collector and the emitter of each transistor, and the rectified DC voltage (28
0V) is converted into an AC voltage of a predetermined frequency by turning on / off each transistor and output. This output is supplied to an electric motor 1M built in the submersible pump 1 via an electric cable (not shown). The electric motor 1M is a power source of the submersible pump 1, and may be any of an induction motor, a permanent magnet rotary motor, a permanent magnet rotary motor without a magnetic pole position detector, and the like.

The inverter 20 having such a configuration is used.
, The reactor 13 is provided at a stage subsequent to the rectifier circuit 30. Further, a noise filter 14 such as a zero-phase reactor is provided on an electric cable from the output terminal of the switching circuit 40 to the electric motor 1M.

On the other hand, the CPU 15 which is a main control unit
Is connected to the flow rate detector 6, the pressure detector 8, and the switching drive circuit 16. Switching drive circuit 16
Drives the transistors of the switching circuit 40 on and off at a timing according to a command from the CPU 15.

The CPU 15 has the following means [1] to [4] as main functions.

[0023] [1] detecting the pressure P of the pressure detector 8 is less than the set value Ps ₂ (output a logic "0" of the pressure sensor 8), means for initiating the operation of the inverter 20.

[2] Means for gradually increasing the output frequency of the inverter 20 when the operation of the inverter 11 is started.

[0025] [3] When the sensed pressure P of the pressure detector 8 becomes the set value Ps ₁ or more (the output of the pressure sensor 8 is a logic "0"
When the output pressure of the inverter 10 at that time is once held, the output frequency is decreased by a predetermined value ΔF every predetermined time, and when the detected pressure P becomes less than the set value Ps (the pressure detector 8 is switched to the logic “1”). Means for increasing the output frequency by a predetermined value .DELTA.F at predetermined time intervals.

[4] Means for stopping the operation of the inverter 20 when the detected flow rate F of the flow rate detector 6 becomes smaller than the set value Fs (the output of the flow rate detector 6 is logic "0").

Next, the operation of the above configuration will be described.

When no water is used on the water receiving side, the pressure P of the water in the water supply pipe 4 is higher than the set value Ps due to the accumulation of the pressure in the pressure tank 7. The submersible pump 1 is stopped.

When water is used, the supply of water is provided by the pressure accumulation in the pressure tank 7. When the pressure accumulation in the pressure tank 7 decreases after the use of water, the pressure P of the water in the water supply pipe 4 decreases accordingly. When the pressure P decreases to less than the set value Ps _2, the output of the pressure detector 8 is switched to a logic "0" from logic "1".

When the output of the pressure detector 8 becomes logic "0", the inverter 20 is operated, and the operation of the submersible pump 1 is started by the output. By the operation of the submersible pump 1, water in the well 3 is sucked and supplied to the water receiving side by the water supply pipe 4.

When starting the submersible pump 1, the inverter 2
The output frequency of 0 gradually increases, and the pressure P of the water in the water supply pipe 4 increases accordingly.

The set value P at which the pressure P becomes the target pressure constant control
It becomes the s ₁ or more, the output of the pressure detector 8 is switched to a logic "1" from a logical "0". At this time, the output frequency of the inverter 20 is once held, and thereafter, if the output of the pressure detector 8 is logic "1", the output frequency is reduced by a predetermined value ΔF at predetermined time intervals. When the output of the pressure detector 8 becomes logic "0", the output frequency changes to a predetermined value .DELTA.
It is increased by F.

Due to the increase or decrease of the output frequency, the pressure P is increased regardless of the depth position of the submersible pump 1 in the well 3.
There is maintained substantially constant at the set value Ps _1. That is, fluctuations in the water supply pressure P are suppressed, and stable water supply with little temperature fluctuations is possible when using a shower or a water heater. Problems such as low-temperature hot water not reaching the required temperature and hot water higher than the required temperature are prevented.

As described above, by employing the inverter 20, frequent repetition of operation / stop of the submersible pump 1 can be avoided, the service life of the submersible pump 1 can be improved, and the power consumption can be reduced. Energy saving is improved.

When the submersible pump 1 is started, the output frequency of the inverter 20 gradually increases, so that a situation in which a large current flows at the time of starting can be eliminated. Therefore, other electric devices such as a home air conditioner and a refrigerator , A voltage drop to a vacuum cleaner or the like can be prevented.

As a countermeasure against noise, the inverter 20
A noise filter 12 on the input side, a reactor 13 after the rectification, and a noise filter 14 such as a zero-phase reactor on the output side. Can have. In particular, since the submersible pump 1 is put into the well 3, the electric cable from the inverter 20 to the submersible pump 1 tends to be long, and there is a fear that radiation noise may be generated from the electric cable. The noise can be suppressed by a noise filter 14 such as a zero-phase reactor.

Although the case where the power supply is the three-phase 200V three-phase AC power supply 11 has been described as an example, the present invention can be similarly carried out when the power supply is a single-phase 200V or single-phase 100V single-phase AC power supply. FIG. 3 shows an application to a single-phase AC power supply (single-phase 200 V) 51, and a single-phase noise filter 52 is provided instead of the noise filter 12 on the input side of the inverter 20.

FIG. 4 shows a single-phase AC power supply (single-phase 100 V) 53
The single-phase noise filter 52 is provided on the input side of the inverter 20 instead of the noise filter 12. Further, instead of the rectifier circuit 30, a voltage doubler rectifier circuit 60 including a series circuit of rectifying diodes 61 and 62 and a series circuit of capacitors 63 and 64 is provided.

That is, the type of the rectifier circuit in the inverter 20 is selected according to whether the AC power supply is three-phase 200V, single-phase 200V, or single-phase 100V. In other words, by changing the type of the rectifier circuit in the inverter 20, it is possible to cope with various types of AC power supplies, and it is not necessary to change the motor 1M, and the versatility is excellent.

The present invention is not limited to the above embodiment, but can be variously modified without changing the gist.

[0041]

As described above, according to the present invention, an inverter is provided for supplying drive power to the electric motor of the pump, and the output frequency of the inverter is controlled so that the pressure of the water supply becomes constant at a predetermined value. A noise filter is provided on the input side, a reactor is provided after the rectifier of the inverter, and a noise filter is provided on the output side of the inverter. This prevents frequent repetition of operation and stop of the pump, thereby improving the life of the pump. At the same time, power consumption can be reduced to improve energy savings.Moreover, the situation in which a large current flows when the pump is started can be eliminated to prevent a voltage drop to other electric devices, and it is sufficient for noise generation. It is possible to provide a water supply device having a sufficient suppression function.

[Brief description of the drawings]

FIG. 1 is a diagram showing an overall configuration of an embodiment.

FIG. 2 is a diagram showing a specific configuration of a control unit according to one embodiment.

FIG. 3 is a diagram showing a modification of FIG. 2;

FIG. 4 is a diagram showing another modification of FIG. 2;

[Description of Signs] 1 ... Submersible pump 1M ... Motor 4 ... Water supply pipe 6 ... Flow detector 7 ... Pressure tank (accumulator) 8 ... Pressure detector 10 ... Control unit 11 ... Three-phase AC power supply 12 ... Noise filter 13 ... Reactor 14 Noise filter 20 Inverter 30 Rectifier circuit 21 Smoothing capacitor 40 Switching circuit

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Koji Toyoda 1 Oyorita, Hashime-cho, Okazaki-shi, Aichi F-term in Okazaki Plant of Kawamoto Manufacturing Co., Ltd. 3H045 AA09 AA12 AA23 AA40 BA20 BA32 BA35 BA40 CA03 CA06 DA07 5H007 AA01 BB06 CA01 CB05 CC09 DA03 DB12 HA02 5H576 AA05 BB05 DD04 HA02 HB01

Claims (4)

[Claims] 1. A water supply device for supplying water by operating a pump using a motor as a power source, wherein the AC voltage is rectified, and the rectified DC voltage is converted into an AC voltage having a predetermined frequency, and the rectified DC voltage is supplied to the motor. An inverter that outputs power, a control unit that controls an output frequency of the inverter so that the pressure of the feedwater becomes a predetermined value, a noise filter that is provided on an input side of the inverter, and a rectification stage that is provided after the inverter. A water supply device comprising: a reactor; and a noise filter provided on an output side of the inverter. 2. A pump that uses an electric motor as a power source to suck and discharge water, a water supply pipe for sending water discharged from the pump to a predetermined place, and a water supply pipe that communicates with the water supply pipe to reduce water supply pressure. An accumulator, an inverter configured to output driving power to the electric motor, comprising: a rectifier circuit for rectifying a voltage of the AC power supply; and a switching circuit for converting an output voltage of the rectifier circuit to an AC voltage having a predetermined frequency. A noise filter provided between the rectifier circuit and the rectifier circuit; a reactor provided between the rectifier circuit and the switching circuit; a noise filter provided between an output terminal of the inverter and the electric motor; Pressure detection means for detecting the pressure of water in the pipe; flow rate detection means for detecting the flow rate of water in the water supply pipe; and a detection pressure of the pressure detection means being less than a set value. Then, the operation of the inverter is started and the output frequency of the inverter is gradually increased. Thereafter, the output frequency of the inverter is controlled so that the pressure detected by the pressure detecting means becomes a predetermined value, and the flow rate detecting means is controlled. Control means for stopping the operation of the inverter when the detected flow rate becomes less than a set value. 3. The water supply device according to claim 1, wherein the electric motor is any one of an induction motor, a permanent magnet rotary motor, and a permanent magnet rotary motor without a magnetic pole position detector. Characterized water supply device. 4. The water supply device according to claim 2, wherein the rectifier circuit is of a type depending on whether the AC power supply is a three-phase 200V, a single-phase 200V, or a single-phase 100V. A water supply characterized by being different.