JP2023084908A - water supply system - Google Patents

Abstract

To provide a water supply system capable of simplifying periodic inspection of a water supply device.SOLUTION: An inspection control unit 72 uses a difference between a power supply voltage used when previous deterioration inspection control was executed and a power supply voltage used when current deterioration inspection control is executed to determine a timing of executing next deterioration inspection control. As a result, it is possible to determine the deterioration of power supply units 77 to 79, which are one of important devices, at an appropriate timing. In addition to the above, a worker who performs maintenance work can repair or replace the power supply units 77 to 79 before the power supply units 77 to 79 actually fail.SELECTED DRAWING: Figure 1

Description

The present disclosure relates to water supply systems.

In order to stably operate the water supply system, it is essential to perform regular inspections and maintenance as described in Patent Document 1, for example. In other words, it is desirable that important equipment that interferes with the operation of the electric pump be periodically inspected and repaired or replaced before the equipment actually breaks down.

JP 2016-217073 A

This disclosure discloses an example of a water supply system in view of the above points.

The water supply system desirably includes, for example, at least one of the following components. That is, the constituent elements include an electric pump (3) for water supply, a power supply unit (77) that outputs a predetermined voltage, and a signal indicating the output voltage of the power supply unit (77) (hereinafter referred to as power supply voltage (Vp ) is input to the inspection control unit (72), and the inspection control unit ( 72), the inspection control unit (72) utilizes the difference between the power supply voltage (Vp) used when executing the previous deterioration inspection control and the power supply voltage (Vp) used when executing the deterioration inspection control this time. Therefore, it is desirable to be able to execute execution timing determination control for determining the timing for executing the next deterioration inspection control.

As a result, in the water supply system, the deterioration determination of the power supply unit (77), which is one of the important devices, can be performed at appropriate timing. As a result, the maintenance worker can repair or replace the power supply unit (77) before the power supply unit (77) actually breaks down.

Incidentally, the symbols in each parenthesis above are examples showing the correspondence with the specific configurations and the like described in the embodiments described later, and the present disclosure is not limited to the specific configurations and the like indicated by the symbols in the parentheses. .

It is a figure showing a water supply system concerning a 1st embodiment. It is a figure which shows the water supply apparatus which concerns on 1st Embodiment. It is an example of the flowchart which shows 2nd transmission control. It is an example of the flowchart which shows 3rd transmission control. It is an example of the flowchart which shows degradation check control etc. It is a figure showing a water supply system concerning a 1st embodiment.

The following "embodiment of the invention" shows an example of an embodiment belonging to the technical scope of the present disclosure. In other words, the matters specifying the invention described in the claims are not limited to the specific configurations, structures, etc. shown in the following embodiments.

At least one component such as a device or member described with at least a reference numeral is provided unless specified as "one". That is, unless there is a notice such as "one", two or more of the components may be provided. The water supply system and water supply apparatus shown in this disclosure include at least the components and the like labeled and described.

(First embodiment)
<1. Overview of the water supply system>
In this embodiment, for example, an example of the water supply system according to the present disclosure is applied to a water supply system applied to buildings such as condominiums and commercial buildings. As shown in FIG. 1, the water supply system according to this embodiment includes at least one remote control device 1, at least one water supply device 2, and the like.

In addition, in this embodiment, the water supply system is configured by one remote control device 1 and a plurality of water supply devices 2 . The remote control device 1 and each water supply device 2 can communicate with each other through wireless communication or wired communication (including communication combining wireless communication and wired communication).

<1.1 Overview of water supply equipment>
Each water supply device 2 includes at least an electric pump 3, a pressure accumulator 5, a control panel 7, a water level detector 9, a pressure sensor Ps, a flow rate sensor Fs, and the like, as shown in FIG. The electric pump 3 is a water supply pump having a pump section, a motor section, and the like.

In addition, in this embodiment, a plurality of electric pumps 3 having the same specifications are provided. The discharge side of each electric pump 3 is connected to the water pipe side of the building. Each electric pump 3 supplies the water stored in the water receiving tank 11 to the building through the water pipe.

The pressure accumulator 5 is connected to the discharge side of each electric pump 3 and maintains the water supply pressure when all the electric pumps 3 are stopped. Note that the pressure accumulator 5 maintains the water supply pressure when all the electric pumps 3 are stopped by the internal pressure of the gas chamber filled with the inert gas.

A pressure sensor Ps detects the water supply pressure on the discharge side of the electric pump 3 . A flow rate sensor Fs detects the discharge flow rate of the electric pump 3 . In this embodiment, the same number of flow sensors Fs as the number of electric pumps 3 are provided, and each flow sensor Fs detects the flow rate at the discharge port of the corresponding electric pump 3 .

The water level detector 9 detects the amount of water stored in the water receiving tank 11, that is, the water level. The water level detector 9 according to the present embodiment includes a common electrode 9A and a plurality of water level electrodes 9B-9D. A predetermined voltage (for example, 12 V) is applied between the common electrode 9A and each of the water level electrodes 9B to 9D.

The control panel 7 is a casing that houses a pump control section 71, an inspection control section 72, and the like. In addition to the pump control unit 71 and the inspection control unit 72, the control panel 7 includes a first communication unit 73, a second communication unit 74, a water receiving control unit 75, a main power supply device 76, a first power supply unit 77, A second power supply section 78, a third power supply section 79, and the like are accommodated.

<First Communication Unit and Second Communication Unit>
The first communication unit 73 is a communication circuit for communicating with the remote management device 1 . The second communication unit 74 is a communication circuit for communicating mainly with short-range wireless communication devices such as portable wireless communication devices.

<Water receiving control part>
The water receiving control unit 75 grasps the water level in the water receiving tank 11 by using the energized state between the common electrode 9A and the water level electrodes 9B to 9D, and operates the electric inflow valve 13 according to the grasped water level. control the opening and closing of the

The water receiving control unit 75 is composed of a microcomputer having a CPU, a ROM, a RAM, and the like. The above operations are executed by executing water control software in the water control unit 75 .

<Pump controller>
The pump control unit 71 controls the operation of each electric pump 3 using the detected values of the pressure sensor Ps and the flow sensor Fs. The pump control unit 71 is composed of a microcomputer having a CPU, ROM, RAM, and the like.

The operation of the electric pump 3 is controlled by executing pump control software in the pump control unit 71 . The pump control unit 71 controls stop and operation of the electric pump 3 via the driving device 4 .

The driving device 4 is composed of an inverter-type driving circuit. The water supply device 2 according to this embodiment has the same number of drive devices 4 as the electric pumps 3 . Each driving device 4 includes an inverter circuit 41, a converter section 42, and the like.

Each inverter circuit 41 supplies drive current to the motor portion of the corresponding electric pump 3 . Each converter unit 42 supplies DC power to the corresponding inverter circuit 41 . That is, the converter unit 42 converts commercial power into DC power and supplies the DC power to the inverter circuit 41 .

Then, each driving device 4 supplies a driving current having a frequency (hereinafter referred to as output frequency) corresponding to the command frequency output from the pump control section 71 to the motor section. As a result, the rotation speed of the electric pump 3 is variably controlled by the pump controller 71 .

The pump control unit 71 uses the pressure sensor Ps to perform activation control and target pressure control. Activation control is control for activating the electric pumps 3 when the water supply pressure becomes equal to or less than a predetermined value while all the electric pumps 3 are stopped. It should be noted that the pump control unit 71 activates an electric pump 3 different from the electric pump 3 activated last time when executing the activation control.

The target pressure control is control for adjusting the rotation speed of the electric pump 3 so that the water supply pressure becomes a target pressure (hereinafter referred to as target pressure). Note that the target pressure is, for example, a predetermined value or a value determined as a function of the water supply amount or the command frequency.

The pump control unit 71 uses the flow rate sensor Fs to execute the small water amount stop control. The small water amount stop control is a control to stop the electric pump 3 when the flow rate detected by the flow rate sensor Fs, that is, the water supply amount becomes equal to or less than a predetermined flow rate.

<Main power supply unit, first power supply section to third power supply section>
The first power supply section 77 supplies DC power of a predetermined first voltage (for example, 3.3 V) to the control sections 71, 72, 75, and the like. The second power supply unit 78 supplies DC power of a predetermined second voltage (eg, 5 V) to the flow rate sensor Fs, the communication units 73 and 74, the display/operation unit (not shown), and the like. .

The third power supply section 79 supplies DC power of a predetermined third voltage (for example, 12V) to the pressure sensor Ps, the inflow valve 13, the water level detector 9, and the like. The main power supply device 76 supplies electric power to the first power supply section 77 , the second power supply section 78 and the third power supply section 79 .

<2. Inspection control unit>
The inspection control unit 72 executes at least deterioration inspection control, execution timing determination control, and information transmission control for each of the first power supply unit 77 to the third power supply unit 79 . Hereinafter, any power supply unit among the first power supply unit 77 to the third power supply unit 79 will simply be referred to as "power supply unit".

The inspection control unit 72 is composed of a microcomputer having a CPU, ROM, RAM, and the like. The inspection control unit 72 is realized by executing the inspection control software in the inspection control unit 72 .

<2.1 Overview of deterioration inspection control>
Deterioration inspection control is control that exerts a function of judging deterioration of the power supply unit by using at least a signal indicating the output voltage of the power supply unit (hereinafter referred to as power supply voltage Vp).

Specifically, the inspection control unit 72 determines the difference between the power supply voltage Vp(n) used when executing the previous deterioration inspection control and the power supply voltage Vp(n+1) used when executing the current deterioration inspection control (hereinafter referred to as change Δv) is greater than a predetermined threshold value Vc.

That is, the inspection control unit 72 regards that the deterioration of the power supply unit has progressed when {Vp(n)-Vp(n+1)}>Vc. In other words, the inspection control unit 72 determines that the deterioration of the power supply unit has progressed when the amount of change Δv exceeds the range of variation that can be considered normal.

<2.2 Overview of execution timing determination control>
The execution timing determination control is control for determining the timing for executing the next deterioration inspection control using the change amount Δv. Hereinafter, the interval between the timing at which the deterioration inspection control is executed and the timing at which the next deterioration inspection control is executed is referred to as an execution interval Int.

That is, in principle, the inspection control unit 72 executes deterioration inspection control at each predetermined execution interval Int. However, when the change amount Δv becomes larger than the threshold value Vc, the inspection control unit 72 makes the execution interval Int shorter than the previous execution interval Int until the next deterioration inspection control is executed.

Specifically, when the amount of change Δv is less than the threshold Vc, the inspection control unit 72 sets the execution interval Int to the execution interval Int corresponding to six months of operating time, and when the amount of change Δv becomes greater than the threshold Vc sets the execution interval Int to an operating time equivalent to one month.

<2.3 Outline of information transmission control>
The inspection control unit 72 can execute first transmission control, second transmission control, and third transmission control as information transmission control. Hereinafter, a power supply unit in which the amount of change Δv is larger than the threshold value Vc is defined as a deteriorated power supply, and the power supply voltage of the deteriorated power supply is referred to as a deteriorated voltage Vd.

<First transmission control>
The first transmission control includes identification information indicating a power supply unit, information indicating a power supply voltage Vp of the power supply unit (hereinafter referred to as voltage information), and whether or not the power supply unit is a deteriorated power supply when deterioration inspection control is executed. This is a control for transmitting information indicating deterioration (hereinafter referred to as deterioration information) to the remote management device 1 .

Then, the inspection control unit 72 stores the voltage information and the deterioration information transmitted to the remote management device 1 in a storage unit (not shown) such as a RAM. Therefore, the voltage information when it is determined that the power supply is deteriorated is the deteriorated voltage Vd. Note that the inspection control unit 72 overwrites the previous voltage information and deterioration information to store the current voltage information and deterioration information.

<Second transmission control>
The second transmission control is a control for acquiring immediately before shutdown parameters and transmitting the acquired immediately before shutdown parameters to the remote management apparatus 1 together with identification information indicating the power supply unit.

The parameter immediately before stopping refers to the driving parameter immediately before the electric pump 3 is stopped by the small water amount stop control. The drive parameter is a general term for the output frequency and output current of the inverter circuit 41 and the DC voltage of the converter section 42 .

For this reason, as shown in FIG. 3, the inspection control unit 72 acquires the immediately before stop parameter (S2) each time the small water amount stop control is executed (S1: YES), and The parameters are stored in a storage unit (not shown) such as RAM (S3).

Then, when deterioration inspection control is executed, the inspection control unit 72 transmits the parameter immediately before shutdown stored in the storage unit to the remote management device 1 together with the identification information indicating the power supply unit. Note that the inspection control unit 72 overwrites the parameters immediately before the previous stop and stores the parameters immediately before the stop this time.

<Third transmission control>
The third transmission control is control executed when a signal (hereinafter referred to as an entry signal) is received from the mobile wireless communication device.

That is, as shown in FIG. 4, when the inspection control unit 72 receives the entry signal (S5: YES), it acquires the power supply voltage Vp of the deteriorated power supply, that is, the deteriorated voltage Vd (S6). Next, the inspection control unit 72 transmits the acquired deteriorated voltage Vd and the already acquired deteriorated voltage Vd immediately before the acquisition to the portable wireless communication device (S7).

In other words, upon receiving the entry signal, the inspection control unit 72 transmits the deteriorated voltage Vd acquired when the entry signal was received and the already acquired deteriorated voltage Vd stored in the storage unit to the portable wireless communication device. The entry signal contains at least identification information indicating the deteriorated power supply.

<2.4 Details of deterioration inspection control, etc.>
FIG. 5 is a control flow showing, for example, deterioration inspection control executed by the first power supply unit 77. As shown in FIG. The control is started when a power switch (not shown) of the water supply device 2 is turned on, and stopped when the power switch is turned off.

When the control is activated, the inspection control unit 72 determines whether or not the target power supply unit (in this example, the first power supply unit 77) is a deteriorated power supply (S11). Note that the inspection control unit 72 according to the present embodiment makes the determination based on whether or not a flag indicating a deteriorated power supply is stored in the storage unit.

When it is determined that the target power supply unit is not a deteriorated power supply (S11: YES), the inspection control unit 72 determines whether or not the operating time since the previous deterioration inspection control has exceeded six months (S12). Then, when the operating time exceeds six months (S12: YES), the inspection control unit 72 acquires the power supply voltage Vp of the target power supply unit and stores the acquired power supply voltage Vp (S13).

Next, the inspection control unit 72 calculates the difference between the power supply voltage Vp acquired in the previous degradation inspection control and the power supply voltage Vp acquired in S13, that is, the amount of change Δv (S14). It is determined whether or not it is equal to or less than the threshold value Vc (S15).

If the change amount Δv is equal to or less than the threshold value Vc (S15: YES), the inspection control unit 72 transmits identification information indicating the power supply unit, voltage information, deterioration information, and parameters immediately before shutdown to the remote management device 1 (S17 ).

If the amount of change Δv is greater than the threshold value Vc (S15: NO), the inspection control unit 72 regards the target power supply unit as a deteriorated power supply, stores a flag to that effect (S16), and then executes S17. do.

Further, when it is determined in S11 that the target power supply unit is a deteriorated power supply (S11: NO), the inspection control unit 72 checks whether or not the operating time since the previous deterioration inspection control has exceeded one month. It judges (S18).

Then, when the operation time exceeds one month (S18: YES), the inspection control unit 72 acquires the power supply voltage Vp of the target power supply unit, and after storing the acquired power supply voltage Vp (S19), Execute S17.

<3. Features of Water Supply System According to Present Embodiment>
In the water supply system according to this embodiment, the deterioration determination of the power supply unit, which is one of the important devices, can be performed at appropriate timing. As a result, maintenance workers can repair or replace the power supply before it actually breaks down.

In other words, periodic inspections that require personnel to perform inspection work can be limited to, for example, once a year, making it possible to reduce manual inspection items. Since it is automatically checked at intervals, it is possible to replace degraded parts before the power supply unit fails.

When the deteriorated power supply unit is repaired or replaced (hereinafter referred to as "repair etc."), the power supply voltage Vp and deterioration information before the repair etc. are executed are reset to initial values or null values. Therefore, after the repair or the like is performed, the inspection control unit 72 regards the repaired power supply unit as a power supply unit without deterioration.

The water supply system acquires the deteriorated voltage Vd when receiving the entry signal from the portable wireless communication device, and stores the acquired deteriorated voltage Vd and the already acquired deteriorated voltage Vd immediately before the acquisition in the portable wireless communication device. type wireless communication device.

As a result, when a person who performs periodic inspections (hereinafter referred to as a serviceman) transmits an entry signal from a mobile wireless communication device such as a smartphone to the water supply device 2, the serviceman can obtain the deteriorated voltage Vd and the acquired deterioration voltage Vd. It is possible to automatically obtain the deterioration voltage Vd that has already been obtained immediately before.

By extension, the serviceman can judge the degree of deterioration and carry out repair or replacement work. The serviceman inspects the water supply device 2 when deterioration information indicating that a deteriorated power source has occurred is transmitted to the remote control device 1 or at predetermined regular intervals.

By the way, immediately before the electric pump 3 is stopped by the small water amount stop control, the electric pump 3 is operating stably. Therefore, changes over time in the output voltage, output frequency, and output current of the inverter circuit 41 are considered to be signs of wear of movable parts such as the impeller, or an abnormality in the power system circuit of the inverter circuit 41 itself.

In addition, since the DC voltage of the converter unit 42 is generated by an electrolytic capacitor, which is a consumable part, if the DC voltage drops due to an increase in ripple, it will lead to a trip during operation, so it is necessary to replace the parts early.

Therefore, by transmitting the parameters just before stopping to the remote management device 1 when executing deterioration inspection control, it is possible to repair or replace the electric pump 3 and the driving device 4 before an abnormality actually occurs.

(Second embodiment)
As shown in FIG. 6, the water supply device 2 according to this embodiment includes an abnormality determination section 8 that determines whether or not an abnormality has occurred in the pump control section 71 . Then, the inspection control unit 72 transmits the judgment result of the abnormality judgment unit 8 to the remote management device 1 when the deterioration inspection control is executed.

The abnormality determination unit 8 is also composed of a microcomputer having a CPU, ROM, RAM, and the like. The abnormality determination is performed, for example, by the following method.

That is, the abnormality determination unit 8 outputs a random number generated by a random number generator in the microcomputer as an analog voltage from the DA output port, inputs the analog voltage to the AD port of the pump control unit 71, and inputs the analog voltage to the pump. Digital conversion is performed by the control unit 71 .

Next, the abnormality determination unit 8 compares the numerical value digitally converted by the pump control unit 71 with the random number generated by itself. The abnormality determination unit 8 determines that an abnormality has occurred in the pump control unit 71 if they do not match, and determines that an abnormality has not occurred in the pump control unit 71 if they match.

As a result, it becomes possible to detect a hardware abnormality that is not caused by software, such as a minute current leak that occurs in the internal circuit of the pump control unit 71 . Through the above process, it is verified whether the bit output voltage is proper and whether the bit input voltage determination circuit is normal.

In addition, the same code|symbol as the above-mentioned embodiment is attached|subjected to the same component as the above-mentioned embodiment. Therefore, redundant description is omitted in this embodiment.

(Other embodiments)
In the above-described embodiment, the inspection control section 72 is provided in the water supply device 2 . However, the present disclosure is not so limited. That is, the disclosure may be, for example, a configuration in which the inspection control unit 72 is provided in the remote management device 1 .

In the above-described embodiment, once the execution interval Int is shortened, the execution interval Int is not shortened thereafter. However, the present disclosure is not so limited. That is, in the disclosure, for example, even after the execution interval Int is shortened, if the change amount Δv is equal to or greater than the second threshold, the execution interval Int is shortened again. good.

In the above-mentioned embodiment, it was a water supply apparatus provided with three types of power supply units. However, the present disclosure is not so limited. That is, the disclosure may be, for example, a water supply device that includes one type or four or more types of power supply units.

In the above-described embodiment, the identification information indicating the power supply unit, the voltage information, the deterioration information, and the parameters immediately before shutdown are transmitted to the remote management device 1 at the timing when the deterioration inspection control is executed. However, the present disclosure is not so limited. That is, the disclosure may be configured such that, for example, only one of the information is transmitted at a timing different from the timing at which deterioration inspection control is executed.

Furthermore, the present disclosure is not limited to the embodiments described above as long as it conforms to the gist of the disclosure described in the embodiments described above. Therefore, in the configuration in which at least two of the above-described embodiments are combined, or in the above-described embodiments, any one of the illustrated constituent elements or the constituent elements described with reference numerals is abolished. It may be configured as

DESCRIPTION OF SYMBOLS 1... Remote control apparatus 1... Water supply system 2... Water supply apparatus 3... Electric pump 4... Drive device 5... Accumulator 7... Control board 9... Water level detector 11... Water tank 13... Inflow valve 41... Inverter circuit 42... Converter part 71... Pump control unit 72... Inspection control unit 73... First communication unit 74... Second communication unit 75... Water receiving control unit 76... Main power supply unit 77... First power supply unit 78... Second power supply unit 79... Third power supply Department

Claims (8)

an electric pump for water supply,
a power supply that outputs a predetermined voltage;
an inspection control unit capable of executing deterioration inspection control for determining deterioration of the power supply unit using a signal indicating the output voltage of the power supply unit (hereinafter referred to as power supply voltage),
The inspection control unit utilizes the difference between the power supply voltage used when executing the previous deterioration inspection control and the power supply voltage used when executing the current deterioration inspection control (hereinafter referred to as the amount of change) to determine the next deterioration inspection. A water supply system capable of executing execution timing determination control for determining timing for executing control. When the interval between the timing at which deterioration inspection control is executed and the timing at which the next deterioration inspection control is executed is the execution interval,
2. The water supply system according to claim 1, wherein said inspection control unit makes the execution interval shorter than the previous execution interval when the amount of change is greater than a predetermined value. comprising a plurality of power supply units,
The water supply system according to claim 2, wherein the inspection control unit performs degradation inspection control and execution timing determination control for each of the plurality of power supply units. Equipped with a communication unit capable of communicating with a remote management device by wireless communication or wired communication,
The water supply system according to claim 3, wherein the inspection control unit transmits identification information indicating the power supply unit and information indicating the power supply voltage of the power supply unit to the remote management device when deterioration inspection control is executed. comprising a second communication unit for communicating with a portable wireless communication device;
When, among the plurality of power supply units, a power supply unit having a change amount larger than a predetermined value is regarded as a deteriorated power supply, and the power supply voltage of the deteriorated power supply is regarded as a deteriorated voltage,
The inspection control unit acquires the deteriorated voltage when receiving a signal from the portable wireless communication device, and transmits the acquired deteriorated voltage and the deteriorated voltage already acquired immediately before the acquisition to the portable wireless communication device. 5. The water supply system according to claim 4, which transmits to a communication device. An inverter circuit that drives the motor portion of the electric pump, and a converter portion that supplies DC power to the inverter circuit,
The output voltage, the output frequency and the output current of the inverter circuit, and the DC voltage of the converter unit are collectively referred to as drive parameters, and the drive immediately before the electric pump stops when the water supply amount becomes equal to or less than a predetermined water supply amount. When the parameter is the parameter immediately before stopping,
6. The water supply system according to claim 4 or 5, wherein the inspection control unit acquires a parameter immediately before shutdown and transmits the acquired parameter immediately before shutdown to the remote management device when deterioration inspection control is executed after the acquisition. . a pump control unit that controls the operation of the electric pump;
an abnormality determination unit that determines whether an abnormality has occurred in the pump control unit;
7. The water supply system according to any one of claims 4 to 6, wherein the inspection control unit transmits the determination result of the abnormality determination unit to the remote management device when deterioration inspection control is executed. 8. The water supply system according to claim 7, wherein the inspection control section is housed in a control panel housing the pump control section.

Images