JP2004108356A - Liquid transfer unit - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent the occurrence of an air lock phenomenon caused by the air intake of a liquid transfer pump or rapidly dissolve the air lock phenomenon, and prevent the idling of a liquid transfer unit when liquid in a storage tank is transferred by using the liquid transfer pump. <P>SOLUTION: This liquid transfer unit 20 is provided with a liquid transfer pipe passage 21 connected to the storage tank for storing the liquid, an opening and closing valve 23 arranged on the tip of the liquid transfer pipe passage 21, and the liquid transfer pump 24 arranged midway of the liquid transfer pipe passage 21. A circulation pipe passage 22 for circulating a part of the liquid flowing in the liquid transfer pipe passage 21 into the storage tank is provided midway of the liquid transfer pipe passage 21. Air sucked by the liquid transfer pump 24 is delivered through the circulation pipe passage 22 together with a part of the liquid flowing in the liquid transfer pipe passage 21 during the driving of the liquid transfer pump 24. Thus, the occurrence of the air lock phenomenon can be prevented and the idling of the liquid transfer pump 24 caused by the air storage phenomenon can be prevented. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a liquid sending unit for sending a liquid in a storage tank for storing a liquid, such as water or various aqueous solutions, to a place of use.
[0002]
[Prior art]
As one type of the liquid sending unit, a liquid sending pipe connected to a storage tank for storing a liquid such as water or various aqueous solutions, an opening / closing valve arranged at a distal end of the liquid sending pipe, and a liquid sending pipe. Non-return pump disposed between the liquid supply pump and the on-off valve in the liquid supply pipe line and disposed upstream of the on-off valve in the channel, and a non-return valve disposed between the liquid supply pump and the on-off valve in the liquid supply pipe line to regulate the flow of liquid to the liquid supply pump There is a liquid sending unit of a type including a valve (see Patent Document 1).
[0003]
In this type of liquid sending unit, in the liquid sending operation, the liquid sending pump is driven in accordance with the opening operation of the open / close valve, and functions to flow the liquid in the storage tank through the open / close valve. During the liquid feeding operation, it is important to regulate the idle operation of the liquid feeding pump to prevent a failure caused by the idle operation of the liquid feeding pump. For this reason, in this type of liquid sending unit, the amount of liquid stored in the storage tank is kept within a predetermined range, and air is sucked into the liquid sending pump, which is likely to occur when the stored amount falls below the predetermined range. For preventing the liquid feed pump from running idle (idling operation restricting means).
[0004]
[Patent Document 1]
JP 2000-303962 A
[0005]
[Problems to be solved by the invention]
By the way, in the liquid feeding unit of this type, even when the idling operation restricting means of the liquid feeding pump described above is employed, air is sucked into the liquid feeding pump for various reasons, and the air is sucked into the liquid feeding pump. Stays, so-called Eyakami phenomenon may occur. The above-mentioned idle operation restricting means of the liquid feeding pump employed in the liquid feeding unit of this type is intended to eliminate the cause of suction of air into the liquid feeding pump, The means can only eliminate one of the causes of suction of air into the liquid feed pump, and the idle operation restricting means alone is not enough to prevent the occurrence of the eclipse phenomenon of the liquid feed pump. It is not enough to prevent the liquid pump from running idle.
[0006]
In the liquid transfer unit of this type, if the liquid supply pump during the liquid supply operation becomes idle due to air turbulence and smooth liquid supply becomes impossible, the operation of the liquid supply pump is temporarily stopped. Then, a means for restarting the operation after the Eyakami phenomenon is eliminated is adopted. In this case, when the liquid head of the liquid sending unit is high, the liquid in the pipe at the rising portion of the downstream lifting part of the liquid sending pump must be once discharged in order to eliminate the ejaculation phenomenon. Not very troublesome.
[0007]
Accordingly, an object of the present invention is to prevent the occurrence of an eclipse phenomenon of a liquid supply pump in a liquid supply unit of the type, or to solve the eclipse phenomenon promptly at a mild stage when an eclipse phenomenon occurs. Another object of the present invention is to promptly return the liquid feed pump to a normal operation state to prevent the liquid feed pump from running idle.
[0008]
[Means for Solving the Problems]
The present invention relates to a liquid sending unit. A liquid sending unit to which the present invention is applied includes a liquid sending line connected to a storage tank for storing a liquid, an on-off valve disposed at a distal end of the liquid sending line, and the liquid sending line. A liquid feed pump disposed upstream of the on-off valve and a liquid supply pump disposed between the liquid supply pump and the on-off valve in the liquid supply line to flow the liquid toward the liquid supply pump. A liquid sending unit including a check valve for regulating, and driving the liquid sending pump in response to an opening operation of the open / close valve to cause the liquid in the storage tank to flow out through the open / close valve.
[0009]
Thus, in the liquid sending unit according to the present invention, in the liquid sending unit of the above-described type, the inside of the liquid sending line is provided between the liquid sending pump and the check valve in the liquid sending line. A recirculation pipe is provided for recirculating a part of the flowing liquid into the storage tank.
[0010]
In the liquid supply unit according to the present invention, the pressure is provided between the check valve and the on-off valve in the liquid supply line and operates when the liquid pressure in the liquid supply line is equal to or lower than a set pressure. A switch, an electromagnetic control valve disposed in the return line to control the flow of liquid in the return line, and driving the liquid supply pump based on the operation of the pressure switch, and the electromagnetic control valve. A configuration may be provided that includes control means for controlling the opening.
[0011]
In the liquid sending unit, a flow switch is provided between the check valve and the liquid sending pump in the liquid sending line and operates when a predetermined amount of liquid in the liquid sending line flows. And a control means for controlling the liquid supply pump to stop driving and to close the electromagnetic control valve based on the non-operation of the flow rate switch.
[0012]
Further, in the liquid feed unit according to the present invention, the liquid feed unit is disposed between the check valve and the liquid feed pump in the liquid feed line and operates when the liquid in the liquid feed line flows by a set amount. A flow switch, an electromagnetic control valve disposed in the return line for controlling the flow of liquid in the return line, stopping the operation of the liquid supply pump based on the non-operation of the flow switch, and A configuration may be provided that includes control means for controlling the electromagnetic control valve to close.
[0013]
In each of the liquid sending units having a flow switch in the liquid sending pipe, the reflux pipe may be branched from a portion of the liquid sending pipe upstream of the flow switch.
[0014]
[Action and Effect of the Invention]
In the liquid sending unit according to the present invention, during the liquid sending operation, the liquid in the storage tank is sent to a predetermined place through the opening / closing valve via the liquid sending pipe by driving the liquid sending pump. During this liquid sending, a part of the liquid flowing in the liquid sending pipe flows back into the storage tank through the reflux pipe located downstream of the liquid sending pump.
[0015]
Reflux of a part of the liquid being fed into the storage tank is performed continuously while the liquid feeding pump is being driven, and the air sucked into the liquid sending pump is turned into liquid discharged from the liquid sending pump. The mixed liquid flows out gradually or promptly and is discharged together with the liquid to be returned into the storage tank through the return line.
[0016]
That is, in the liquid feeding unit according to the present invention, the air sucked into the liquid feeding pump during the liquid feeding operation is discharged into the storage tank along with a part of the liquid to be discharged (the liquid that returns). For this reason, in the liquid feed pump, even if air is sucked in during its operation, the sucked air does not stay in the liquid feed pump, so that there is no occurrence of an eclipse phenomenon.
[0017]
Further, in the liquid sending unit according to the present invention, even if a large amount of air is sucked into the liquid sending pump and the air temporarily stays in the liquid sending pump to cause a light-emitting phenomena, this eccentricity may occur. The phenomenon is quickly eliminated by the refluxing liquid. As a result, the occurrence of idle operation of the liquid feed pump is completely or quickly eliminated, and it is possible to prevent a failure in the liquid feed pump caused by the continuous idle operation of the liquid feed pump.
[0018]
In the liquid supply unit having such an effective function, a pressure switch that operates when the liquid pressure in the water supply line is equal to or lower than a set pressure is provided between the check valve and the on-off valve in the liquid supply line. A control means for providing an electromagnetic control valve for controlling the flow of liquid in the reflux pipe in the return pipe, and for driving the liquid feed pump and opening the electromagnetic control valve based on the operation of the pressure switch By providing the above, it is possible to obtain a configuration that can further exert the effect. In this case, a configuration may be adopted in which a flow switch that operates when a predetermined amount of liquid in the liquid feed line flows between the check valve and the liquid feed pump in the liquid feed line.
[0019]
Further, in the liquid sending unit having such an effective function, a flow rate switch that operates when a predetermined amount of liquid in the liquid sending line flows between the check valve and the liquid sending pump in the liquid sending line. And an electromagnetic control valve for controlling the flow of liquid in the return line is provided in the return line, and the drive of the liquid feed pump is stopped and the electromagnetic control valve is closed based on the non-operation of the flow rate switch. By providing the control means for controlling to achieve this, it is possible to obtain a configuration in which the effect can be further exhibited.
[0020]
In each of these liquid sending units, the liquid sending operation of the liquid sending unit can be interrupted if the liquid sending pump of the liquid sending unit falls into an idle operation state. Further, even if the liquid feed pump is unnecessarily continuously driven due to a failure of the pressure switch or the flow rate switch, the liquid is forced to be sent by the liquid feed pump. It functions to allow liquid to escape. Thus, the occurrence of the failure of the liquid feeding pump in this case can be compensated for a short period of time.
[0021]
In each of the liquid sending units according to the present invention, a return pipe branching from the middle of the liquid sending pipe is provided, and a part of the liquid in the middle of the liquid sending is returned to the storage tank, whereby the idle pump of the liquid sending pump is operated. The main purpose is to prevent the occurrence of phenomena. In the case where such a means is adopted, the air sucked into the liquid sending pump can be discharged more efficiently as the reflux amount of the liquid during the liquid sending increases. For this reason, in the liquid sending unit, depending on the idle operation of the liquid sending pump, there is a case where it is desired to increase the reflux amount of the liquid being fed into the storage tank from a preset reflux amount. In this case, if the liquid sending unit is of a type having a flow switch, the operation flow set value of the flow switch may be a problem.
[0022]
In order to cope with such a problem, in the liquid sending unit according to the present invention having the flow switch, the reflux line is branched from the upstream side of the flow switch in the liquid sending line. This makes it possible to eliminate the relationship between the flow rate of the liquid into the storage tank and the set value of the operation flow rate of the flow switch, and changes the set value of the operation flow rate of the flow switch according to the change in the flow rate of the liquid. It becomes unnecessary. That is, the troublesome work of changing the operation flow set value of the flow switch can be eliminated.
[0023]
BEST MODE FOR CARRYING OUT THE INVENTION
The present invention relates to a liquid sending unit, and a liquid sending unit according to the present invention will be described below with reference to the drawings. FIG. 1 shows an electrolyzed water generator 10 employing a water supply unit which is one embodiment of a liquid supply unit according to the present invention. The electrolyzed water generation device 10 is configured the same as the electrolyzed water generation device disclosed in the publication disclosed at the beginning except for the liquid sending units 20a and 20b.
[0024]
The electrolyzed water generator 10 is for generating alkaline water and acidic water by electrolyzing a dilute saline solution, and includes a water supply unit 20a for supplying alkaline water and a water supply unit 20b for supplying acidic water. Equipped. The apparatus main body 10a of the electrolyzed water generation apparatus 10 is assembled and accommodated in a case 10c assembled on a base 10b. The apparatus main body 10a includes an electrolytic cell 11 and a concentrated salt water tank 12.
[0025]
The electrolytic cell 11 includes a pair of electrolytic chambers 11b and 11c partitioned by a diaphragm 11a. Electrodes 11d and 11e are provided in the electrolytic chambers 11b and 11c, respectively. A DC voltage is applied to each of the electrodes 11d and 11e. The control device 16 controls application and stop of the DC voltage to each of the electrodes 11d and 11e, and switching of the positive and negative polarities of each of the electrodes 11d and 11e. Each of the electrolysis chambers 11b and 11c of the electrolysis tank 11 is connected to a concentrated salt water tank 12 and a water softener 14 through a water supply pipe 13a, and is connected to an aqueous water storage tank 15a and an acid water tank 15a through outflow pipes 13b and 13c. Each of them is connected to a water storage tank 15b. The outflow pipes 13b and 13c are connected to the inflow holes 15c of the water storage tanks 15a and 15b, and the outflow pipes 13b and 13c are connected to the electrolysis chambers 11b and 11c via the flow path switching valve 13d. It is selectively switched to the electrolytic chambers 11b and 11c, and is controlled by the control device 16 in accordance with the switching of the positive and negative polarities of the electrodes 11d and 11e.
[0026]
The concentrated salt water tank 12 is connected to a supply pipe 12a of tap water and connected to a water supply pipe 13a via a supply pump 12b. And tap water supplied through the supply pipe 12a to generate a saturated saline solution. The generated saturated saline solution is supplied to the water supply pipe 13a through the supply pump 12b. Soft water is supplied from the water softener 14 to the water supply pipe 13a, and the supplied soft water is uniformly mixed with the saturated saline solution in the water supply pipe 13a, so that the saturated saline solution has a predetermined concentration of less than 1%. Prepare in dilute saline. The diluted saline is supplied to each of the electrolysis chambers 11b and 11c of the electrolysis tank 11 as electrolyzed water.
[0027]
The operating state of the apparatus main body 10a in the electrolyzed water generating apparatus 10 is all controlled by the control device 16. However, the operation of the apparatus main body 10a and the method of generating electrolyzed water by the apparatus main body 10a are known, and each of the electrolysis chambers 11b , 11c, the alkaline water is selectively supplied to a water storage tank 15a dedicated to alkaline water, and the acidic water is selectively supplied to a water storage tank 15b dedicated to acidic water.
[0028]
The water supply unit 20a and the water supply unit 20b have the same configuration and are arranged symmetrically, although there is a difference between an object to be supplied and alkaline water or acidic water. Therefore, in the description of these two water supply units 20a and 20b, the symbols of the two water supply units 20a and 20b are set to 20 for convenience, and their constituent parts, constituent members, and Regarding the components and the like, the same components will be described with the same reference numerals.
[0029]
The water supply unit 20 includes a water supply line 21, a reflux line 22, an on-off valve 23, a water supply pump 24, a check valve 25, a pressure switch 26a, a flow rate switch 26b, an air chamber 26c, and a branch line 27. In addition, a control means 28 is provided. In addition, the control means 28 is integrally formed in the control device 16 constituting the electrolyzed water generation device 10.
[0030]
The water supply pipe line 21 is formed by connecting a supply pipe 21a and a discharge pipe 21b via a connector 21c, and a base end of the water supply pipe 21a is connected to an outlet hole 15d of a water storage tank to stand up and discharge. The tube 21b extends to a predetermined height. A water supply pump 24, a flow rate switch 26b, a check valve 25, a pressure switch 26a, and an air chamber 26c are provided in this water supply line 21 at a position in the middle of the supply pipe 21a from the base end side in this order. In addition, an opening / closing valve 23 is provided at a tip end portion of the pouring pipe 21b.
[0031]
The reflux line 22 constitutes a main part of the present invention, and is connected to a portion of the supply pipe 21a of the water supply line 21 between the flow rate switch 26b and the check valve 25, and the distal end thereof is connected to the water storage tank 15a. , 15b. An electromagnetic control valve 22a is interposed in the return line 22 on the way.
[0032]
The water supply pump 24 constituting the water supply unit 20a functions to supply the alkaline water in the water storage tank 15a through the dedicated water supply line 21 for the alkaline water, and the water supply pump 24 constituting the water supply unit 20b stores the water. It functions to supply the acidic water in the tank 15b through a dedicated water supply line 21 for the acidic water. The check valve 25 regulates the flow of water to the upstream side of the flow switch 26b in the water supply line 21. When the on-off valve 23 is closed to stop water supply, the check valve 25 opens and closes. It functions to maintain the water pressure between the valve 23 and the check valve 25. The flow switch 26b operates to close (ON) when the flow rate of water flowing in the supply pipe 21a is equal to or higher than a set value, and to open (OFF) when the flow rate falls below the set value. It functions to detect the flow rate of flowing water.
[0033]
The pressure switch 26a opens (turns off) when the water pressure in the supply pipe 21a is equal to or higher than a set pressure, and closes (turns on) when the water pressure falls below a set value, and detects the water pressure in the supply pipe 21a. To work. The air chamber 26c releases excessive pressure temporarily generated when the water pump 24 is stopped by closing the on-off valve 23, and functions similarly to a general accumulator. The return line 22 returns a part of the alkaline water or the acidic water (electrolysis water) flowing in the water supply line 21 during the operation of the water supply pump 24 to each of the water storage tanks 15a and 15b through the electromagnetic control valve 22a. Works to shed. The opening and closing of the electromagnetic control valve 22 a is controlled in accordance with the opening and closing operation of the opening and closing valve 23.
[0034]
The control means 28 is constituted by a microcomputer, and includes a CPU and a drive circuit as shown in FIG. During the operation of the water supply unit 20, the control means 28 drives the water supply pump 24 and opens and closes the electromagnetic control valve 22a as shown in the flowchart of FIG. 3 according to the opening and closing operations of the pressure switch 26a, the flow rate switch 26b, and the like. Control. In the drive circuit of FIG. 2, PLS indicates a pressure switch 26a, FLS indicates a flow rate switch 26b, TM indicates a timer, PM indicates a water supply pump 24, V indicates an electromagnetic control valve 22a, and X1 and X2 indicate relays.
[0035]
The branch conduit 27 is composed of a water intake pipe 27a branched from the supply pipe 21a and a water intake valve 27b. The water intake pipe 27a faces the concentrated salt water tank 12. The branch line 27 enables water to be taken in order to measure the pH value of the water sent from the water storage tanks 15a and 15b, and is taken by opening the water intake valve 27b. Water that spills during water intake and water that leaks from the intake valve 27b are received in the concentrated salt water tank 12, and block the contact of the electrolyzed water with each component and component of the electrolyzed water generator 10, These rusts and corrosion are prevented.
[0036]
In the water supply unit 20, the discharge pipe 21b constituting the water supply conduit 21 is connected to the upper end of the supply pipe 21a via the connector 21c, and extends further upward from the supply pipe 21a to use the electrolytically produced water. Open to the location. In the water supply unit 20, the on-off valve 23 is located at the upper end of the discharge pipe 21b, in other words, at the highest level of the water supply line 21 (the head of the water supply pump 24, that is, the height difference from the water supply pump 24 is about 6 m). It is arranged in. The pressure switch 26a is disposed at the upper end of the supply pipe 21a, in other words, at the highest level of the supply pipe 21a (the height difference from the water supply pump 24 is about 1.5 m).
[0037]
In the water supply unit 20, when the power is turned on, the water supply operation is enabled. When the on-off valve 23 is opened while the power is turned on, the pressure switch 26a is turned on to detect a decrease in pressure in the supply pipe 21a, and the control means 28 sends a water pump based on the on operation of the pressure switch 26a. 24, the electromagnetic control valve 22a is opened, and alkaline water and acidic water (electrolysis water) in the water storage tanks 15a and 15b are supplied through the respective on-off valves 23. During this time, a part of the electrolyzed water flowing in the supply pipe 21a in the middle of the water supply returns to the water storage tanks 15a and 15b from the return line 22 through the electromagnetic control valve 22a. The recirculation amount of the electrolyzed water to be recirculated through the electromagnetic control valve 22a is set to a flow rate that does not hinder the amount of water supply through the on-off valve 23 during a normal water supply operation, and to a flow rate at which the flow switch 26b can operate. ing.
[0038]
When the on-off valve 23 is closed to interrupt the water supply, the flow switch 26b is turned off to detect a decrease in the flow rate of the electrolyzed water in the supply pipe 21a, and the control unit 28 turns off the flow switch 26b. Based on this, the driving of the water supply pump 24 is stopped, and the electromagnetic control valve 22a is closed to terminate the water supply operation. During this time, the control means 28 executes a control program for driving the water pump 24 and opening and closing the electromagnetic control valve 22a based on the flowchart in FIG.
[0039]
In this control method, when the water pump 24 runs idle during the water feeding operation, it detects that the water pump is idle and stops driving the water pump 24. The microcomputer as the control means 28 The operation is started by opening the valve 23, and in step 31, the water pump 24 is driven and the electromagnetic control valve 22a is opened based on the ON operation of the pressure switch 26a.
[0040]
The microcomputer then determines the operation state of the flow switch 26b in step 32, and if it determines that the flow switch 26b is in the ON operation state, the microcomputer determines that the water supply pump 24 is in the normal driving state and executes the program in step 32. The process proceeds to step 33, and in step 33, the operation state of the pressure switch 26a is determined. If the microcomputer determines in step 33 that the pressure switch 26a is in the ON operation state, it determines that the on-off valve 23 is maintained in the open state, and drives the water pump 24 and controls the electromagnetic control valve 22a. The open state is maintained, the program returns to step 32, and the program is circulated and executed. If the microcomputer determines in step 33 that the pressure switch 26a is in the off-operation state, the microcomputer determines that the on-off valve 23 has been operated in the closed state and stops driving the water supply pump 24 in step 34. Then, the electromagnetic control valve 22a is closed to terminate the water supply operation.
[0041]
On the other hand, when the microcomputer determines in step 32 that the flow rate switch 26b is in the OFF operation state, the microcomputer proceeds to step 35 assuming that the water supply pump 24 is in the abnormally driven state, and proceeds to step 35 to execute the timer. Is driven, and after a lapse of a predetermined time (1 min) set by the timer, the operation state of the flow switch 26b is determined in step 36. If the microcomputer determines in step 36 that the flow switch 26b is in the ON operation state, the microcomputer returns the program to step 33 assuming that the drive state of the water supply pump 24 has returned to normal, and continues the water supply operation. .
[0042]
If the microcomputer determines in step 36 that the flow rate switch 26b is in the OFF operation state, the microcomputer determines that the driving state of the water supply pump 24 has not returned to normal and is in an idle operation state. Is returned to step 34, and in step 34, the driving of the water supply pump 24 is stopped, and the electromagnetic control valve 22a is closed to interrupt the water supply operation.
[0043]
As described above, in the water supply unit 20, when the water supply pump 24 falls into the idle operation state, the driving of the water supply pump 24 is stopped to interrupt the water supply operation. The operation state is set to a very short time to protect the water pump 24, and further, a means for preventing air from staying in the water pump 24, which is a major factor in causing the water pump 24 to run idle, is employed. ing.
[0044]
That is, in the water supply unit 20, the return pipe 22 is provided in the supply pipe 21 a constituting the water supply pipe 21, and a part of the electrolytically generated water flowing in the supply pipe 21 a during the water supply is supplied to the electromagnetic control valve 22 a. A means is provided for allowing the water to flow back into each of the water storage tanks 15a and 15b. In the return line 22, the air sucked into the water supply pump 24 is gradually or promptly discharged in a state of being mixed with the electrolysis water discharged from the water supply pump 24, and is integrated with the electrolysis water. Through the storage tanks 15a and 15b. For this reason, in the water supply pump 24, even if air is sucked in during its operation, the sucked air does not stay in the water supply pump 24, thereby preventing the occurrence of an eclipse phenomenon.
[0045]
FIG. 4 shows an electrolyzed water generator 10A employing a water supply unit which is another embodiment of the liquid supply unit according to the present invention. The electrolyzed water generator 10A generates alkaline water and acidic water by electrolyzing a diluted saline solution, and includes a water supply unit 20c for supplying alkaline water and a water supply unit 20d for supplying acidic water. Equipped. The electrolyzed water generator 10A has the same configuration as the electrolyzed water generator 10 shown in FIG. 1, and each of the water supply units 20c and 20d has the same configuration.
[0046]
Each water supply unit 20c, 20d has a different configuration from each water supply unit 20a, 20b shown in FIG. For this reason, in the following description of each water supply unit 20c, 20d, each component is denoted by the same reference numeral as that of each water supply unit 20a, 20b, and detailed description thereof is omitted, and each water supply unit 20a , 20b will be mainly described. In addition, each of the water supply units 20c and 20d is referred to as a water supply unit 20A when there is no need to distinguish and explain them.
[0047]
Like the water supply unit 20, the water supply unit 20A includes a water supply line 21, a reflux line 22, an on-off valve 23, a water supply pump 24, a check valve 25, a pressure switch 26a, a flow rate switch 26b, an air chamber 26c, It has a branch conduit 27 and a control means 28. Thus, in the water supply unit 20A, the reflux line 22 branches off from a portion between the water supply pump 24 and the flow rate switch 26b in the water supply line 21 and faces an upper portion in the water storage tanks 15a and 15b. I have.
[0048]
The other configuration of the water supply unit 20A is the same as the configuration of the water supply unit 20. Therefore, the water supply unit 20A operates in the same manner as the water supply unit 20 and operates due to the branching point of the return line 22. Except for the effects, the same operation and effects as those of the water supply unit 20 are achieved.
[0049]
In each of the water supply units 20 and 20A according to the present invention, a return line 22 is provided which branches off from a part of the liquid supply line 21 so that a part of the liquid during the liquid supply is returned to the storage tanks 15a and 15b. This prevents or largely suppresses the occurrence of idle operation of the liquid feed pump 24. In this case, the air sucked into the liquid sending pump 24 can be more efficiently discharged as the amount of reflux of the liquid during the liquid sending increases.
[0050]
For this reason, in the liquid sending units 20 and 20A, the amount of reflux of the liquid in the middle of liquid sending to the storage tanks 15a and 15b is determined based on the occurrence of idle operation in the liquid sending pump 24, and the predetermined amount of reflux is set. There may be cases where it is desired to increase the number. In this case, since the liquid sending units 20 and 20A include the flow rate switch 26b, the operation flow rate set value of the flow rate switch 26b may be a problem.
[0051]
For example, when the return line 22 is branched from the downstream side of the flow switch 26b in the liquid transfer line 21 like the water supply unit 20, the operation flow set value of the flow switch 26b corresponds to the reflux amount. It is necessary to change the set value to increase, and the change of the recirculation amount requires a troublesome operation of changing the operation flow set value of the flow switch 26b.
[0052]
However, in the water supply unit 20A, since the return line 22 is branched from a portion of the liquid supply line 21 upstream of the flow switch 26b, the amount of liquid reflux and the operating flow set value of the flow switch 26b are set. The relationship with is lost. Therefore, in the water supply unit 20A, the troublesome operation of changing the operation flow rate set value of the flow rate switch 26b with the change of the liquid reflux amount can be eliminated.
[Brief description of the drawings]
FIG. 1 is a schematic diagram showing the overall configuration of an electrolyzed water generating apparatus equipped with a water supply unit as an example of a liquid supply unit according to the present invention.
FIG. 2 is a block diagram (a) of a control unit of the water supply unit and a drive circuit (b) of the control unit.
FIG. 3 is a flowchart for executing a program for controlling a water supply operation of a water supply unit by the control means.
FIG. 4 is a schematic diagram showing an overall configuration of an electrolyzed water generation apparatus equipped with a water supply unit which is another example of the liquid supply unit according to the present invention.
[Explanation of symbols]
10, 10A: electrolyzed water generator, 10a: apparatus main body, 10b: base, 10c: case, 11: electrolytic cell, 11a: diaphragm, 11b, 11c: electrolytic chamber, 11d, 11e: electrode, 12: concentrated salt water tank, 12a ... tap water supply pipe, 12b ... supply pump, 13a ... water supply pipe, 13b, 13c ... outflow pipe, 13d ... flow path switching valve, 14 ... water softener, 15a, 15b ... water storage tank, 15c ... inflow hole, 15d ... Outflow hole, 16 ... Control device, 20a, 20b (20), 20c, 20d (20A) ... Water supply unit, 21 ... Water supply line, 21a ... Supply pipe, 21b ... Outflow pipe, 21c ... Connector, 22 ... Reflux Pipe line, 22a ... electromagnetic control valve, 23 ... open / close valve, 24 ... water supply pump, 25 ... check valve, 26a ... pressure switch, 26b ... flow switch, 26c ... air chamber, 27 ... branch pipe line, 27 ... intake pipes, 27b ... water intake valve, 28 ... control means.

Claims (5)

A liquid sending pipe connected to a storage tank for storing the liquid, an on-off valve provided at a distal end of the liquid sending pipe, and an upstream / downstream valve provided in the liquid sending pipe. A liquid supply pump, a check valve disposed between the liquid supply pump and the on-off valve in the liquid supply pipe line to regulate the flow of liquid to the liquid supply pump side; A liquid supply unit that drives the liquid supply pump in response to the opening operation to cause the liquid in the storage tank to flow out through the on-off valve; and wherein the liquid supply line includes an arrangement of the liquid supply pump and the check valve. A liquid feeding unit, comprising: a reflux pipe for returning a part of the liquid flowing in the liquid feeding pipe to the storage tank between the installation portions. 2. The liquid sending unit according to claim 1, wherein the liquid sending unit is disposed between the check valve and the on-off valve in the liquid sending line, and a liquid pressure in the liquid sending line is set. A pressure switch that operates when the pressure is equal to or lower than a set pressure, an electromagnetic control valve that is disposed in the return line and controls the flow of liquid in the return line, and the liquid transfer pump based on the operation of the pressure switch. A liquid sending unit comprising a control means for driving and opening the electromagnetic control valve. 3. The liquid sending unit according to claim 2, wherein the liquid sending unit is disposed between the check valve and the liquid sending pump in the liquid sending pipeline, and the liquid in the liquid sending pipeline is disposed. A flow switch that operates when a set amount of fluid flows, and control means for controlling the liquid supply pump to stop driving and closing the electromagnetic control valve based on non-operation of the flow switch. Liquid sending unit. 2. The liquid sending unit according to claim 1, wherein the liquid sending unit is disposed between the check valve and the liquid sending pump in the liquid sending line so that the liquid in the liquid sending line is provided. A flow switch that operates when a set amount of fluid flows, an electromagnetic control valve that is disposed in the return line and controls the flow of liquid in the return line, and the liquid feed pump based on the non-operation of the flow switch A liquid sending unit comprising control means for stopping the driving of the device and controlling to close the electromagnetic control valve. The liquid sending unit according to claim 3 or 4, wherein a reflux line constituting the unit is branched from a portion of the liquid sending line upstream of the flow rate switch. unit.

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