JPH04105994U - automatic water supply device - Google Patents

Abstract

(57) [Summary] [Purpose] Even if a water supply pump malfunctions, another water supply pump can be operated in place of the malfunctioning pump, giving the malfunctioning pump a chance to recover and affecting the equipment. The goal is to prevent [Configuration] Failure of N water supply pumps is detected by a pumping failure detection unit 71 provided in each of the water supply pumps, and the pumping failure detection unit 71 detects whether or not a predetermined period of time has elapsed since the failure of the water supply pump occurs using a pumping failure counter 72. Count with this counter 7
2, when a predetermined period of time has been counted, the water supply pump is stopped under the control of the rotary operation control section 67, and when the number of failures reaches a specified number, the automatic operation possible machine setting section 73 determines that the water pump is stopped. I'm trying to exclude water pumps.

Description

[Detailed explanation of the idea]

0001

[Industrial application field]

The present invention uses N water supply pumps connected in parallel between a water source and a water demand source. This invention relates to an automatic water supply device that automatically increases or decreases depending on the demand state.

0002

[Conventional technology]

For example, four water supply pumps are installed in parallel between the water source and the water demand source, and the water demand is An automatic water supply system that controls the number of water pumps in operation according to the demand status of the water supply source. It has been known.

0003

[Problem that the idea aims to solve]

In such an automatic water supply system, for example, if the pump has suction specifications, the suction piping If the pump is unable to pump water due to air entering the tank or a defective foot valve, , the pressure of the pump decreases and the discharge amount of the pump becomes "0", so The problem is that the pump runs idle, causing the pump casing and motor to overheat. There is an issue.

0004 This invention was made in view of the above points, and its purpose is to N water supply pumps connected in parallel are automatically increased or decreased depending on the demand status of the water demand source. Even if the water supply pump malfunctions in an automatic water supply system that operates automatically, Try to run another water supply pump in place of the faulty pump and fix the faulty pump. It provides an opportunity for recovery and prevents any damage to the equipment. Our objective is to provide an automatic water supply device.

[0005]

[Means to solve the problem]

This invention consists of a water source and N water supply pumps connected in parallel between this water source and the water demand source. The system automatically increases or decreases the number of water supply pumps depending on the water demand status of the above water demand sources. In the automatic water supply system, each of the above N water supply pumps is provided with a water supply pump. A failure detection means for detecting a failure of the water supply pump, and a failure detection means for detecting a failure of the water supply pump. A failure state timing means for detecting whether a predetermined period of time has elapsed, and a control means for controlling the operation of the water supply pump. The failure state measured by the pump operation control means that controls the pump operation control means and the failure state timing means described above. means to stop the operation of the water supply pump after a predetermined period of time has elapsed; The system counts the number of times a water pump malfunction detected by the state timing means has elapsed for a predetermined period of time. If the specified number of times is counted by this number of times counting means, A command hand that instructs the pump operation control unit to exclude the water supply pump from operation. This is an automatic water supply device characterized by comprising steps. It is an automatic water supply device.

[0006]

[Effect]

Failure detection means installed in each of the N water supply pumps to detect failures of the water supply pumps Detects whether a predetermined period of time has elapsed due to failure of the water supply pump using failure state timing means. When the failure condition measured by this failure condition timing means has elapsed for a predetermined period of time, The operation of the pump is stopped by the operation stop means, and the water supply pump is stopped by the failure state timing means. The number of times that a failure has elapsed for a predetermined period of time is counted by a number counting means, and this number counting means When the specified number of times is counted, the pump is removed from operation. There is.

[0007]

【Example】

An automatic water supply device according to an embodiment of the present invention will be explained below with reference to the drawings. . Figure 1 is a block diagram showing the control system of this automatic water supply device, and Figure 2 shows four units connected in parallel. Figure 3 shows the installation positions of the connected pump, pressure switch, and flow rate switch. A conceptual diagram showing the water supply system of an apartment where an automatic water supply device is adopted. Figure 4 shows the flow rate. Figure 5 shows the main parts of the switch, Figure 5 shows the main parts of the paddle type flow rate switch, Figure 6 7 is a diagram showing the main parts of the pressure switch, and FIG. 7 is a water supply characteristic diagram of the same embodiment.

[0008] First, in FIG. 3, 11 is a water tank. At the upper end of this water tank 11 is a water supply. A pipe 12 is connected, and a pump 13 is connected to the lower end thereof. This pump 1 3 has four pumps connected in parallel, as will be explained later with reference to Figure 2. . The discharge side of this pump 13 is connected to each floor of the apartment 15 via piping 14. Connected to water demand source (faucet).

[0009] The configuration of the pump 13 will be explained with reference to FIG. 2. In the figure, P1 to P4 are pumps with the same characteristics. Suction ports of these pumps P1 to P4 I1 to I4 are combined into one pipe and connected to the outlet 11O of the water receiving tank 11. Ru. In addition, the discharge ports O1 to O4 of the pumps P1 to P4 face vertically upward, The respective discharge ports O1 to O4 are connected via a connecting pipe 21. And this connecting pipe One end of 21 is connected to a pressure tank 22. Also, one end of this connecting pipe 21 and A pressure switch 23 is disposed at a connecting portion of the pressure tank 22. This pressure The configuration of the switch 23 will be described later with reference to FIG.

0010 In addition, pressure switches f1 to f for detecting the inability to pump water are installed in the pumps P1 to P4, respectively. 4 is built-in. These pressure switches f1 to f4 are the pumps in pumps P1 to P4. Pumps P1 to P4 are not operating and the water pressure is normal. A microswitch is turned on when the value falls below a certain value.

[0011] Further, an L-shaped pipe 24 is provided at the intermediate point between the pumps P3 and P4 of the connecting pipe 21. It is connected. The detailed configuration of the bent portion of the pipe 24 will be described later using FIG. A flow rate switch 25 is provided. Further, at one end of the L-shaped pipe 24, a It has a built-in paddle type flow rate switch 26 whose detailed configuration will be described later using Fig. 5. A pipe 27 is connected thereto. The opening side of this pipe 27 is connected to the above pipe 14. ing.

0012 In other words, the water supplied from the water tank 11 is driven by one of the pumps P1 to P4. It is led to the connecting pipe 21 through the pump, and further through the pipes 24, 27, 14. water is supplied to water demand sources (e.g. faucets) on each floor.

[0013] Next, the structure of the flow rate switch 25 will be explained with reference to FIG. This flow rate Switch 25 has two built-in contacts FS1 and FS2 consisting of reed switches. There is. Then, the float 31 with a built-in magnet moves up and down in accordance with the increase and decrease of the flow rate. When the float 31 rises to the position of contact FS1 or FS2, the reed switch is activated. When closed, the FS1ON signal or FS2ON signal is obtained.

[0014] On the other hand, if the float 31 comes to a position away from the contact FS1 or FS2, the leak will occur. The switch is opened and the FS1OFF signal or FS2OFF signal is obtained. Ru.

[0015] For example, the above FS1OFF signal has a flow rate of 10 liters/min, and the above FS1OFF signal The 1ON signal has a flow rate of 12 liters/min, and the above FS2OFF signal has a flow rate of 180 liters/min. liters/min, and the above FS2ON signal is obtained at a flow rate of 200 liters/min. The mounting position of the reed switch and the biasing force of the spring 32 are adjusted accordingly.

[0016] Next, the structure of the flow rate switch 26 will be explained with reference to FIG. This flow rate The switch 26 is a paddle 4 that rotates around a shaft 41 according to the flow rate flowing in the pipe 27. 2, a permanent magnet 43 attached to the other end of this paddle 42, and this permanent magnet It is composed of reed switches 44 and 45 that are closed when approached. example For example, when the flow rate is 400 liters/min, the reed switch 44 is closed and the FS3ON signal is activated. The reed switch 45 is closed when the flow rate is 600 liters/min. FS4ON signal is output.

[0017] Next, the detailed configuration of the pressure switch 23 will be described with reference to FIG. 6. this The pressure switch 23 has a photo interrupter, and connects the connecting pipe 21 and the pressure tank 22. A diaphragm 51 that moves up and down depending on the magnitude of the pressure between A light shielding plate 52 that moves up and down in conjunction with the photointerrupter 51 is located between the photointerrupters. Depending on whether or not the PS1 ON signal or OFF signal can be obtained. .

For example, when the water pressure becomes less than 3.0 kgf/cm ² , the light shielding plate 52 lowers to a position where it does not block the light from the photointerrupter, so a PS1ON signal is obtained, and the water pressure becomes less than 3.0 kgf/cm 2 . When the value exceeds 1 kgf/cm ² , the light shielding plate 52 rises to a position where it blocks the light from the photointerrupter, so that a PS1OFF signal is obtained.

Next, the configuration of this automatic water supply device will be explained with reference to FIG. In FIG. 1, 23 is pressure detection means. This pressure detection means 23 is the pressure switch 23 as described above with reference to FIG. 4, and this pressure switch 23 outputs the PS1ON signal when the pressure on the discharge side of the water supply pump decreases to 3.0 kgf/cm ² .

[0020] Further, 25 is the flow rate switch described above using FIG. 4, and 26 is the flow rate switch described above using FIG. It is a flow rate switch, and from contact FS1, contact FS2, contact FS3 and FS4. The output signal is input to the flow rate level counting section 61. This flow rate level counting section 6 1 counts ON signals from contacts FS1 to FS4. Therefore, the flow level meter The number part 61 contains a count value corresponding to the flow rate flowing to the discharge side of the water supply pump. become.

[0021] The count value counted by the flow rate level counting section 61 is output to the requested number of units setting section 62. It will be done. This required number setting section 62 receives an ON signal output from the pressure detection means 23. The number is entered.

[0022] The requested number determining unit 62 includes the pumps that are in operation among the pumps P1 to P4. The current number N of operating vehicles counted by the operating vehicle number counting section 63 is input. Further, the operating unit number counting unit 63 outputs the number of operating units N to the flow rate level counting unit 61. The flow rate level counting unit 61 performs its counting process when the number of units in operation is N≧1. carry out the principles.

[0023] This requested number setting section 62 includes the flow rate level counting section 61 and the operating number counting section 63. Set the requested number of units based on the data output from. For example, the number of operating vehicles “N=0 ” and the ON signal is input, “1” is set as the required number of devices. 64. This setting unit number setting section 64 is a setting unit indicating the current number of automatically operated cars. number is set. This setting unit number setting section 64 is set by the above-mentioned requested number setting section 62. The number of settled units is set to be equal to the requested number of units. Also, this setting table The number setting unit 64 detects the water level in the water tank 11 and indicates that the water level has fallen abnormally. A liquid level control unit 65 is connected which outputs a water shortage signal when detected.

[0024] The fixed number of machines set in the fixed number of machines setting section 64 is input to the increase/decrease number determining section 66. Ru.

[0025] This increase/decrease unit determining unit 66 selects the setting number set by the setting unit number setting unit 64 and the above-mentioned setting unit number. By comparing the number N of currently operating vehicles counted by the operating vehicle number counting unit 63, , decide whether to increase or decrease the number of pumps to be operated, and decide whether to increase or decrease the number of pumps to be operated. The stand signal is output to the rotary operation control section 67.

The rotary operation control unit 67 outputs start and stop signals to the pump control units 69 ₁ to 69 ₄ corresponding to each pump so that the pumps P1 to P4 enter rotary operation.

The pump control units 69 ₁ to 69 ₄ control the operation of the pumps P1 to P4, respectively.

[0028] By the way, the signals of the pressure switches f1 to f4 are input to the pumping failure detection section 71. At the same time, a start signal is output to which pump sent from the rotary operation control section 67. A pump signal is input indicating whether the This pumping failure detection section 71 is connected to the pump Check whether the water pressure of the activated pump indicated by the signal is increasing by pressing the pressure switch f1 ~ This is determined based on the f4 signal. and T1 hours after the pump is started (e.g. For example, if the pressure does not rise above the specified value after 1 minute, that is, the pressure switch When T1 time has elapsed while f1 to f4 are on, the pumping failure detection counter is activated. A "-1" signal is output to the data input terminal 72. This counter 72 corresponds to each pump. N (for example, 3) is set as the initial value. Ru.

[0029] At the same time, the detection unit 71 indicates that the automatic operation possible setting unit 73 indicates that pumping is not possible. To remove the pump from rotary operation for T2 time (e.g. 3 minutes), the control signal Output. This automatic operation possible machine setting section 73 is capable of pumping water among the pumps P1 to P4. The pump number is output to the rotary operation control section 67.

[0030] The rotary operation control section 67 also outputs a stop signal to the normal stop detection section 74. do. This normal stop detection unit 74 indicates that the pump to which the stop signal has been output has stopped normally. If it has stopped normally, a reset signal is output to the counter 72. Strengthen.

[0031] When the counter 72 reaches 0, the counter 72 sends a signal to the faulty machine. Output to 75. This malfunctioning machine discard unit 75 causes a malfunction in the rotary operation control unit 67. Outputs a signal to exclude the pump from rotary operation.

[0032] Next, the operation of an embodiment of the present invention configured as described above will be explained. child In this operation, the number of pumps being operated is increased from 0 → 1 → 2 → 3 → 4. The explanation will be given by taking as an example an example in which the number of units is reduced from 1 to 0.

First, as the demand for water increases in the apartment 15, the pressure on the discharge side of the pump 13 decreases. As a result, when the water pressure drops below 3.0 kgf/cm ² , the pressure switch 23 outputs a PS1ON signal to the required number setting section 62 . Since the number of operating machines N=0 is inputted to the required number of machines setting section 62 from the number of operating machines counting section 63, "1" is set as the required number of machines. The requested number setting unit 62 then outputs the requested number “1” to the settling number setting unit 64. Then, in this settling number setting section 64, "1" is set as the number of settling machines. Then, this set number of vehicles "1" is sent to the increase/decrease vehicle determining section 66.

Since "0" is inputted to this increase/decrease vehicle determining section 66 as the number N of operating vehicles from the operating vehicle number counting section 63, the increase/decrease vehicle determining section 66 outputs a vehicle increase signal to the rotary operation control section 67. do. This rotary operation control section 67 outputs a start signal to the pump control section 69 ₁ . The pump control section 69 ₁ outputs a drive signal to the pump P1 in response to this activation signal. This causes the pump P1 to operate. As a result, "1" is counted as the number of pumps being driven by the pump operation number counting section 63.

[0035] As a result, the flow rate on the discharge side of the pumps P1 to P4 increases, and the flow rate of the flow rate switch 25 increases. The contact FS1 is closed, and the flow rate level counter 61 counts "1".

[0036] By the way, the pump P1 is sent from the rotary operation control section 67 to the pump failure detection section 71. A signal indicating that is activated is output. This pumping failure detection unit 71 indicates that the pressure switch f1 is Determine whether it is turned on. Here, even if a start signal is output to pump P1, When the water pressure on the discharge side of pump P1 does not rise, pressure switch f1 is turned on. There is. Then, the pumping failure detection unit 71 determines the time period during which the pressure switch f1 is turned on. If the pressure switch f1 is on for T1 time (1 minute), A “-1” signal is output to the pumping failure detection counter 72. As a result, counter 7 The value of 2 is set to ``2'' by ``-1'' from the initial value ``3''.

[0037] Then, the pumping failure detection unit 71 outputs a signal to the automatically operable machine setting unit 73. Ru. As a result, this setting unit 73 removes pump P1 from automatic operation for T2 (3 minutes). A signal to be removed is output to the rotary operation control section 67.

[0038] As a result, the rotary operation control unit 67 starts pump P2 instead of pump P1. Output a signal. Below, the pump P2 is checked for pumping failure. The pump P2 continues to operate if it is not possible to pump water.

[0039] In this way, even if pump P1 is started, if water cannot be pumped for T1 time, , the pump P2 is excluded from automatic operation for the time T2 and is operated instead.

Then, when the demand increases and the amount of water increases and the contact FS2 of the flow rate switch 25 is closed, the signal is sent to the flow rate level counting section 61. As a result, the flow rate level counting section 61 counts "2". Then, "2" counted by the flow rate level counting section 61 is sent to the requested number of devices setting section 62, and "2" is set as the requested number of devices. Thereafter, "2" is set as the number of settled vehicles in the same manner, and is output to the increase/decrease vehicle determining section 66. Since the operating vehicle number N is set to “1” in the operating vehicle number determining unit 66 from the operating vehicle number counting unit 63, the increasing/decrease vehicle determining unit 66 outputs a vehicle increase signal to the rotary operation control unit 67. As a result, the rotary operation control section 67 outputs a start signal to the pump control section 69 ₃ . As a result, pump P3 is also operated.

[0041] Below, when the demand for water increases further, the contacts FS3 and FS4 of the flow rate switch 26 are being closed one after another. As a result, "3" and "4" are displayed in the flow rate level counting section 61. are counted sequentially. Thereafter, pumps P4 and P1 are operated in the same manner.

By the way, when the activation signal is output again to the pump control unit 69 ₁ of the pump P 1 and the state in which water cannot be pumped continues for a time T 1 , a “-1” signal is output to the counter 72 . As a result, the counter 72 counts "1". Furthermore, a signal to exclude pump P1 from automatic operation is output to automatic operation setting section 73. As a result, the rotary operation control unit 67 executes rotary operation excluding pump P1.

[0043] Thereafter, the rotary operation control unit 67 outputs the start signal to the pump P1 again, and the pump If the pump P1 is unable to pump water, the pump P1 is unable to pump water, and the counter 72 is set to "-1" from the pump P1. A signal is output. As a result, the counter 72 counts "0". In other words, If pump P1 is started three times and fails to pump water all three times, the failure occurs. A signal is output to the failure device erasing unit 75, and the pump P1 is deleted from automatic operation.

[0044] On the other hand, the rotary operation control unit 67 again outputs the start signal to the pump P1, and the pump Pump P1 is determined to be able to pump water, and a stop signal is issued to pump P1 due to a subsequent decrease in demand. Once output, the stop signal is output to the normal stop detection section 74. And this When the normal stop detection unit 74 determines that the pump P1 has been stopped normally, , this normal stop detection section 74 outputs a reset signal to the counter 72. child As a result, the initial value "3" is set in the counter 72.

[0045] As described above, you can increase the number of pumps operated when water demand increases. In that case, if there is a pump that cannot pump water, skip that pump. I am trying to make rotary operation by doing this.

[0046] Next, after the four pumps have been operated, as the demand for water decreases, the flow rate decreases. I'll come. As a result, the contact FS4 of the flow rate switch 26 is first turned off. This F The S4OFF signal is input to the flow rate level counting section 61 and has been counted up until now. "4" is incremented by "-1" and becomes "3".

[0047] Hereinafter, "3" is set in the requested number setting section 62, and "3" is set in the settling number setting section 64. is set. The increase/decrease unit determining unit 66 has “3” as the set number of units, and the operating unit number counting unit Since the number of operating vehicles N = "4" counted in 63 is input, the vehicle reduction signal is not logged. output to the primary operation control section 67.

As a result, the rotary operation control section 67 outputs a stop signal to the pump control section 69 ₁ in order to stop the pump P1 which has been in operation for the longest time. Therefore, pump P1 is stopped.

[0049] Below, the water demand decreases and contacts FS3, FS2, and FS1 are turned off in turn. Ku. As a result, "2", "1", and "0" are sequentially counted in the flow rate level counting section 61. To go.

Thereafter, "2", "1", and "0" are sequentially counted as the requested number of machines in the requested number of machines setting section 62, and "2", "1", and "0" are sequentially set in the settling number of machines setting section 64. It will be done. Then, the unit increase/decrease determination unit 66 sequentially outputs a unit reduction signal to the rotary operation control unit 67, and a stop signal is output to the pump control units 69 ₂ , 69 ₃ , and 69 ₄ in this order, and the pumps P 2 , P 3 , and P 4 in that order. Pump is stopped.

[0051] In addition, in the above example, the case where four water supply pumps are operated in parallel is taken as an example. However, the same method can be applied to a larger number of water supply pumps.

[0052] As mentioned above, if the pump is unable to pump water, it will first be removed from automatic operation for T2 hours. If it is removed and the pump fails to pump water three times, it will be removed from automatic operation. subordinate So, in a temporary case such as a foreign object clogging the pump, there is a chance to restore it to 3 times. Therefore, the burden on the administrator can be reduced.

[0053] According to the above embodiment, the inability of each pump to pump water is determined by the pressure switches f1 to f4. In this embodiment, the detection is performed using a flow rate switch.

[0054]

[Effect of the idea]

As detailed above, according to the present invention, N The water supply pumps on the machines are now automatically increased/decreased depending on the demand status of the water demand source. In automatic water supply equipment, even if a water supply pump malfunctions, a replacement for the failed pump will be provided. Instead, start operating other water supply pumps to give the failed pump a chance to recover. Automatic water supply that can prevent the automatic water supply from affecting the automatic water supply device. equipment can be provided.

[Brief explanation of drawings]

FIG. 1 is a block diagram showing one embodiment of the present invention.

FIG. 2 is a diagram showing the installation positions of the pump, pressure switch, and flow rate switch in the same embodiment.

FIG. 3 is a conceptual diagram showing the water supply system of the same embodiment.

FIG. 4 is a diagram showing the main parts of a flow rate switch.

FIG. 5 is a diagram showing the main parts of a paddle-type flow rate switch.

FIG. 6 is a diagram showing the main parts of a pressure switch.

FIG. 7 is a water supply characteristic diagram of the same example.

[Explanation of symbols]

23...Pressure detection means, 25, 26...Flow rate switch, 61
...Flow rate level counting section, 62...Required number of units setting section, 63...Number of operating units counting section, 64...Settling number of units setting section, 66...Increase/decrease number setting section, 67...Rotary operation control section, 71...Pumping failure detection section, 72... Pumping failure detection counter, 73...Automatically operable machine setting section, 74...Normal stop detection section, 75...Faulty machine deletion section.

Claims (1)

[Scope of utility model registration request] Claim 1: A water source, N water supply pumps connected in parallel between the water source and a water demand source, and automatically increasing the number of water supply pumps according to the water demand state of the water demand source, In the automatic water supply system that is being reduced in number, a failure detection means is provided for each of the N water supply pumps to detect a failure of the water supply pump, and a failure state is detected by the failure detection means to detect whether a failure of the water supply pump has elapsed for a predetermined period of time. a timing means, a pump operation control means for controlling the operation of the water supply pump, and an operation stop means for stopping the operation of the water supply pump after a predetermined period of time has elapsed in the failure state measured by the failure state timer;
a frequency counting means for counting the number of times a predetermined period of time has elapsed due to a failure of the water supply pump detected by the failure state timing means;
An automatic water supply device comprising command means for instructing the pump operation control section to exclude the water supply pump from operation when the number of times counting means counts a specified number of times.