JPH10203595A - Drink supply device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To minimize water-leak damage by composing so that a second control means stops water feed based on a signal indicating the elapse of second time, in case of the occurrence of an abnormal condition in a first control means due to, for example, program runaway. SOLUTION: If an abnormal condition occurs in a control system, such as program runaway, after the start of water feed, a control part 6 becomes unable to control the opening/closing of all solenoid valves and a current continues to flow in the relay coil 2b of a first electromagnetic relay 2. However, a monitor timer 4 closes a constant-open contact 4b after a value obtained by counting elapsed time exceeds a second limit energization time. As a result of it, a current flows in the relay coil 3c of a second electromagnetic relay 3, the constant-close contact 3a of the second electromagnetic relay 3 is opened, and a current to an electromagnetic valve 12 in a water inlet is shut off, so that the solenoid valve 12 in the water inlet is closed. By the flow of the current in the relay coil 3c a constant-open contact 3b is closed, and the constant-close contact 3a is kept open.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a beverage dispenser applied to a beverage dispenser and the like, and more particularly to a beverage dispenser which minimizes damage caused by water leakage.

[0002]

2. Description of the Related Art FIG. 3 shows an example of a piping system of a beverage dispenser to which a beverage supply device is applied. Tap water from the city water is supplied to the first divider 13A via the street water filter 11 and the water inlet solenoid valve 12 piping P _1. First
Of tap water supplied to the distributor 13A of the water tank 1
4 and a coil unit 15 disposed in the aquarium water in the aquarium 14. Tap water supplied to the water tank 14 side, the pipe P ₂ via the street aquarium water supply electromagnetic valve 16 and flows into the water tank 14. Tap water supplied to the coil unit 15 side is pressurized piping P ₃ are as pressure pump 17, is supplied to the second distributor 13B through the coil unit 15. The tap water supplied to the second distributor 13B is, here, a multi-valve 18 side, a carbonator 19 side arranged in the cooling water of the water tank 14 to produce carbonated water,
It branches into four, one on the side of the vesting pump 20A and the other on the side of the vesting pump 20B. Supplied to the multi-valve 18 side water flows into the multi-valve 18 to the pipe P ₄ via the street flow control valve 21 and the cold water solenoid valve 22, is discharged to the cup C as cold water. Is supplied to the carbonator 19 side water is fed to the carbonator 19 through a street carbonator water supply electromagnetic valve 23 to the pipe P _5, becomes carbonated water capture carbon dioxide from the carbon dioxide gas cylinder 24,
The carbonated water flows into the multi-valve 18 via the flow control valve 25, the coil unit 15, and the carbonated water electromagnetic valve 26, and is discharged to the cup C. Verista pump 20A, 2
The water supplied to the 0B side passes through the pipes P ₆ and P _7, and through the flow regulating valves 27A and 27B, the verister pumps 20A and 2B.
0B, and is discharged to the cup C as diluting water via the diluting water solenoid valves 20a and 20b in the verister pumps 20A and 20B. On the other hand, the syrup tanks 28A, 28B, 28C,
The syrups I, II, III, and IV pumped from 28D are supplied to the coil unit 15 and the syrup solenoid valves 29A, 29B, 2
It flows into the multi-valve 18 via 9C and 29D and is discharged to the cup C.

[0003] Fig. 4 shows a conventional beverage supply device for controlling the piping system configured as described above. This beverage supply device 10
Has a control unit 30 provided with a timer 30a for counting the time elapsed since the opening of each solenoid valve.
The above water inlet solenoid valve 12, water tank water supply solenoid valve 16, pressurizing pump 17, dilution water solenoid valves 20a and 20b, cold water solenoid valve 2
2. Carbonator water supply solenoid valve 23, carbonated water solenoid valve 26,
The syrup solenoid valves 29A, 29B, 29C, 29D and the verista pumps 20A, 20B are respectively connected to each other to detect the upper and lower water levels of the aquarium water in the aquarium 14 and the carbonated water in the carbonator 19. Carbonate float switches 32 for detecting the upper limit water level and the lower limit water level are connected respectively. The control unit 30 previously stores the solenoid valve opening time at the time of sale (for example, 5 to 10 seconds).
Are each water inlet solenoid valve 12, dilution water solenoid valves 20a, 20b,
Chilled water solenoid valve 22, carbonated water solenoid valve 26, syrup solenoid valve 2
9A, 29B, 29C, 29D, and a water inlet solenoid valve 1 for preventing the damage caused by water leakage from spreading.
A limit energization time of 2 (for example, 10 minutes) is set.

[0004] The beverage supply apparatus 10 configured as described above.
, When the sales signal is input, the control unit 30 opens the solenoid valve required for supplying the beverage, counts the elapsed time since opening the solenoid valve by the timer 30a, and sets the count value of the timer 30a. When the set solenoid valve opening time has elapsed, each solenoid valve is closed, and the count value of the timer 30a is cleared. When the switches 31 and 32 detect the lower limit water level, the control unit 30 opens the water inlet solenoid valve 12, the water tank water supply solenoid valve 16 or the carbonator water supply solenoid valve 23 until the switches 31 and 32 detect the upper limit water level, and the water tank 14 Alternatively, water is supplied to the carbonator 19. Usually, replenishment is completed in about 1 to 2 minutes. When water is supplied to the water tank 14 or the carbonator 19, the switches 31 and 32 are used.
When the switches 31 and 32 cannot detect the upper limit water level due to the failure and the count value by the timer 30a exceeds the set limit energizing time, the control unit 30 closes the water inlet solenoid valve 12. As described above, the energization time of the water inlet solenoid valve 12 is monitored by the so-called soft timer of the timer 30a in the control unit 30, so that the water inlet solenoid valve can be operated even when the water supply is continuously performed due to the failure of the switches 31, 32 and the like. The valve 12 can be closed to prevent the damage from the water leak from spreading.

[0005]

However, according to the conventional beverage supply device 10, if an abnormality occurs in the control system due to a program runaway or the like after the start of water supply, the solenoid valve of the piping system remains energized. And a water leak accident occurred,
There is a problem that the damage caused by water leakage increases.

Accordingly, it is an object of the present invention to provide a beverage supply device that can minimize damage caused by water leakage.

[0007]

According to the present invention, there is provided a beverage supply apparatus having a water supply system for supplying water to a plurality of water supply units from a common water inlet solenoid valve. Signal generation means for outputting a water supply stop signal when the amount of water supplied to one of the water supply units has reached a predetermined value; and time measurement of a first time period when water supply to the one water supply unit is started. A first timer means for starting water supply, a second timer means for starting time measurement of a second time period that is larger than a first time period when water supply to the one water supply unit is started, and the water supply stop signal. Alternatively, a first control unit that stops water supply to the one water supply unit based on the first time measurement end signal, and when an abnormality occurs in the first control unit,
There is provided a beverage supply apparatus comprising: a second control unit that stops water supply to the one water supply unit based on a time end signal of the second time period. According to the above configuration, when an abnormality occurs in the signal generation unit due to a sensor failure or the like, the first control unit stops supplying water to one water supply unit based on the time measurement end signal of the first time period. Further, when an abnormality occurs in the first control means due to a program runaway or the like, the second control means stops water supply based on the timing end signal of the second time period.

[0008]

Embodiments of the present invention will be described below in detail with reference to the drawings. FIG. 1 is a configuration diagram of a beverage supply device according to an embodiment of the present invention. The beverage supply device 1 is applied to the piping system of the beverage dispenser shown in FIG. 3, and includes AC 100V AC lines L ₁ and L _2.
The water inlet solenoid valve (SV) 12, the normally open contact 2a of the first electromagnetic relay 2, and the normally closed contact 3a of the self-holding second electromagnetic relay 3 shown in FIG. Solenoid valve 1
2, a timer coil (T) 4a of a monitoring timer 4 as a time limit relay is connected in parallel, and a DC line L of 24V DC is connected.
Normally open contact 3b of the second electromagnetic relay 3 between the relay ₃ and GND
And the relay coil (R ₂ ) 3c, and the normally open contact 4b of the monitoring timer 4 is connected to the normally open contact 3b of the second electromagnetic relay 3.
Are connected in parallel, an LED lamp 5 is connected in parallel to a relay coil (R ₂ ) 3c of the second electromagnetic relay 3, and a DC2
The relay coil (R ₁ ) 2 b of the first electromagnetic relay 2 is connected between the DC line L _{3 of} 4 V and the control unit 6.

Further, the beverage supply device 1 includes a control unit 6
A relay coil (R ₁ ) 2b of the first electromagnetic relay 2;
Tank water supply solenoid valve 16, pressurizing pump 17, dilution water solenoid valve 2
0a, 20b, cold water solenoid valve 22, carbonator water supply solenoid valve 23, carbonated water solenoid valve 26, syrup solenoid valve 29A, 2
9B, 29C, 29D, water tank float switch 31,
The float switch 32 for carbonator and the veristor pumps 20A and 20B are connected to each other.

The monitoring timer 4 is provided with the second
Limit energizing time (for example, 11 minutes) t _ThreeCan be set
And the energization time of the water inlet solenoid valve 12 is the second limit.
Field conduction time t_ThreeIs passed, the timer coil (T) 4a
Is configured to close the normally open contact 4b.
As such a monitoring timer 4, for example, a CR oscillation meter
Equation timer, CR time constant timer, etc. can be used.
You.

The controller 6 preliminarily stores the solenoid valve opening time (for example, 5 to 10 seconds) t ₁ at the time of sale at each water inlet solenoid valve 12, the dilution water solenoid valves 20a and 20b, the cold water solenoid valve 22, Solenoid valve 26, syrup solenoid valves 29A, 29B, 29C, 2
Set corresponding to 9D, furthermore, the first limit conduction time of the water inlet solenoid valve 12 to prevent the spread of damage water leakage (for example, 10 minutes) t ₂ is adapted to be set.
Further, the control unit 6 controls the solenoid valve opening time t as the first time period.
_1, a timer (software timer) 6a for performing a first measurement of the critical current supply time t _2, the energization time of the water inlet solenoid valve 12 is designed to monitor the timer 6a. The first electromagnetic relay 2 and the control unit 6 constitute first control means, and the second electromagnetic relay 3 and the monitoring timer 4 constitute second control means.

Next, the operation of the apparatus 1 will be described with reference to the timing chart of FIG. (1) Supply of carbonated beverage (see (a) of FIG. 2) When the carbonated beverage sales signal S _S is input to the control unit 6, the control unit 6 drives the pressurizing pump 17 and performs the water inlet electromagnetic control. valve 12, the cold water solenoid valve 22, carbonated water solenoid valve 26 and the syrup electromagnetic valve 29A,, 29B, and opened and closed according 29C, the solenoid valve opening time t ₁ which is preset 29D, carbonated water, cold water, syrup I , II, III, IV with multi valve 18
To the cup C. The flows of the carbonated water, the cold water, and the syrup are as described in FIG.
With respect to the water inlet solenoid valve 12, the control section 6 applies a current to the relay coil (R ₁ ) 2b of the first electromagnetic relay 2 to close the normally open contact 2a, and allows a current to flow to the water inlet solenoid valve 12 to supply water. with open inlet solenoid valve 12, an elapsed time after opening the water inlet solenoid valve 12 counted by the timer 6a, the count value of the timer 6a has elapsed the solenoid valve opening time t _1, the first
The supply of current to the relay coil (R ₁ ) 2b of the electromagnetic relay 2 is stopped, the normally open contact 2a is opened, and the water inlet electromagnetic valve 12
And shut off the water inlet solenoid valve 12.

[0013] (2) When the selling signal S _S of the supply (see FIG. 2 (a)) to the control unit 6 noncarbonated beverages noncarbonated beverage is input,
Control unit 6 drives the pressurizing pump 17, the water inlet solenoid valve based on the solenoid valve opening time t ₁ which is set in advance 1
2 and the diluting water solenoid valves 20a and 20b are opened and closed, the diluting water is discharged from a nozzle (not shown) to the cup C, and the vests pumps 20A and 20B are driven to discharge syrup from the syrup tank (not shown) to the cup C. The flows of the dilution water and the syrup are as described in FIG. The opening / closing control for the water inlet solenoid valve 12 is the same as the above (1) in the case of supplying the carbonated beverage.

(3) Water supply to the water tank 14 (see FIG. 2 (b)) When the water in the water tank 14 decreases due to evaporation or the like, and the water tank float switch 31 detects the lower water level, the lower water level detection signal S _L is sent to the control unit 6. Control unit 6 opens the water inlet solenoid valve 12 and the water tank water supply electromagnetic valve 16 on the basis of the lower limit level detection signal S _L from the aquarium float switch 31. For the water inlet solenoid valve 12, the first electromagnetic relay 2
A current flows through the relay coil (R ₁ ) 2b of
a is closed, a current is supplied to the water inlet solenoid valve 12, and the water inlet solenoid valve 12 is opened. Tap water from a municipal water is supplied to the first divider 13A via the street water filter 11 and the water inlet solenoid valve 12 a pipe P _1, further piping P ₂ via the street aquarium water supply electromagnetic valve 16 Water is supplied to the water tank 14. The tank water in the tank 14 increases, and the float switch 31 for the tank is used.
Sends an upper limit water level detection signal _SU to the controller 6 when the upper limit water level is detected. The control unit 6 includes a water tank float switch 31.
Based on the upper limit water level detection signal S _U from the water inlet solenoid valve 1
2 and the tank water supply solenoid valve 16 are closed. Water inlet solenoid valve 1
2, the relay coil (R
₁ ) The supply of current to 2b is stopped, the normally open contact 2a is opened, the current to the water inlet solenoid valve 12 is cut off, and the water inlet solenoid valve 12 is closed.

(4) Water supply to the carbonator tank (FIG. 2)
Of (b) refer) reduces carbonated water carbonator 19. by the supply of carbonated water, the float switch 32 detects the lower limit level for the carbonator, send a lower limit level detection signal S _L to the control unit 6.
Control unit 6 drives the pressure pump 17 based on the lower limit level detection signal S _L from the carbonator float switch 32, opens the water inlet solenoid valve 12 and the carbonator water supply electromagnetic valve 23. Tap water from a municipal water is supplied to the first divider 13A via the street water filter 11 and the water inlet solenoid valve 12 a pipe P _1, further, the pipe P
₃ street pressure pump 17 is supplied to the coil unit 15 and a second divider 13B, further, the pipe P ₅ through the streets carbonator water supply electromagnetic valve 23 carbonator 19
Water is supplied to When carbonated water is produced from the supplied water and carbon dioxide gas, the carbonated water in the carbonator 19 increases, and the float switch 32 for carbonator detects the upper limit water level.
Send an upper limit water level detection signal S _U to the control unit 6. The control unit 6
Stops the driving of the pressure pump 17 based on the upper limit level detection signal S _U from carbonator float switch 32 closes the water inlet solenoid valve 12 and the carbonator water supply electromagnetic valve 23. The opening / closing control of the water inlet solenoid valve 12 is the same as the above (3) in the case of supplying water to the water tank 14.

(5) Water supply when the first abnormality occurs (see FIG. 2C) When the switches 31 and 32 fail as the first abnormality, water is supplied to the water tank 14 or the carbonator 19. Although the switches 31 and 32 cannot detect the upper limit water level,
The count value of the timer 6a has passed the first critical current supply time t _2, the control unit 6, a first electromagnetic relay 2 relay coil (R ₁₎ by stopping the supply of current to 2b normally open contacts 2a Is opened, the current to the water inlet solenoid valve 12 is shut off, and the water inlet solenoid valve 12 is closed.

(6) Water supply when a second abnormality occurs (see (d) in FIG. 2) When a control system abnormality such as a program runaway occurs as a second abnormality after water supply is started. The control unit 6 cannot perform the opening / closing control of all the solenoid valves, and the current continues to flow through the relay coil (R ₁ ) 2 b of the first solenoid relay 2.
Monitoring timer 4, the count value of the elapsed time since the current flows in the timer coil (T) 4a has passed the second limit current supply time t _3, to close the normally open contact 4b. As a result, FIG.
As shown in (d), a current flows through the relay coil (R ₂ ) 3 c of the second electromagnetic relay 3, the normally closed contact 3 a of the second electromagnetic relay 3 is opened, and the current to the water inlet electromagnetic valve 12 is reduced. Shut off and close the water inlet solenoid valve 12. Relay coil (R ₂₎ 3c
, The normally open contact 3b is closed, and the open state of the normally closed contact 3a is maintained. At the same time, the LED lamp 5 is turned on to notify the operator that an abnormality has occurred.

According to the above-described apparatus 1, the following effects can be obtained. (B) In addition to the so-called soft timer, the monitoring timer 4 monitors the energization time of the water inlet solenoid valve 12 to ensure double safety. Even if an abnormality occurs, damage from water leakage can be minimized. In addition, since monitoring is performed from both the software and hardware sides, damage from water leakage can be more reliably minimized. (B) Since the abnormality is reported by the LED lamp 5,
Repair of a failed part can be performed promptly. (C) Since the energization time of the common water inlet solenoid valve 12 provided on the upstream side of the piping system is monitored by the soft timer and the monitoring timer 4, a circuit for monitoring all the solenoid valves of the piping system is individually provided. The configuration can be simplified as compared with the configuration provided in the above, and an increase in cost can be avoided. (D) Even if the normally open contact 2a of the first electromagnetic relay 2 keeps energizing the water inlet electromagnetic valve 12 due to a contact failure or the like, the energization of the water inlet electromagnetic valve 12 can be released by the monitoring timer 4.

The present invention is not limited to the above-described embodiment, and various embodiments are possible. For example, LED
The notification by the lamp 5 may be performed by another method such as a buzzer sound. Further, instead of the monitoring timer 4, the energization time of the water inlet solenoid valve 12 may be monitored by a soft timer by the second control unit.

[0020]

As described above, according to the beverage supply apparatus of the present invention, even if an abnormality occurs in the first control means due to a runaway of a program after water supply is started, the second control means does not. Since water supply can be stopped, damage from water leakage can be minimized. Also, by monitoring the energization time of the common water inlet solenoid valve provided on the upstream side of the water supply system, the configuration can be simplified as compared with monitoring all the solenoid valves of the water supply system. .

[Brief description of the drawings]

FIG. 1 is a configuration diagram of a beverage supply device according to the present invention.

FIG. 2 is a time chart of the beverage supply device according to the present invention.

FIG. 3 is a diagram showing a piping system of a beverage dispenser to which the beverage supply device is applied.

FIG. 4 is a block diagram of a conventional beverage supply device.

[Explanation of symbols]

REFERENCE SIGNS LIST 1 beverage supply device 2 first electromagnetic relay 2 a normally open contact 2 b relay coil (R ₁ ) 3 second electromagnetic relay 3 a normally closed contact 3 b normally open contact 3 c relay coil (R ₂ ) 4 monitoring timer 4 a timer coil (T) 4b normally open contact 5 LED lamp 6 control unit 6a timer 11 water filter 12 water inlet solenoid valve (SV) 13A first distributor 13B second distributor 14 water tank 15 coil unit 16 water tank water supply electromagnetic valve 17 pressurizing pump 18 Multi valve 19 Carbonator 20A, 20B Verista pump 20a, 20b Dilution water solenoid valve 21, 25, 27A, 27B Flow control valve 22 Chilled water solenoid valve 23 Carbonator water supply solenoid valve 24 Carbon dioxide gas cylinder 26 Carbonated water solenoid valve 28A, 28B, 28C, 28D syrup tank 29A, 29B, 29C, 29D syrup Solenoid valve 31 Float switch aquarium float switch 32 carbonator C Cup L _1, L ₂ ac line L ₃ DC line _{P 1, P 2, P 3} , P 4, P 5, P 6, P 7 pipe S _L lower limit level detection signal S _S sales signal S _U upper water level detection signal t ₁ solenoid valve opening time t ₂ the first limit energization time t ₃ the second limit energization time

Claims (7)

[Claims] 1. A beverage supply device comprising a water supply system for supplying water from a common water inlet solenoid valve to a plurality of water supply units, wherein the amount of water supplied to one of the plurality of water supply units is a predetermined amount. Signal generation means for outputting a water supply stop signal when the water supply value is reached; first timer means for starting timing of a first time period when water supply to the one water supply section is started; and the one water supply section When water supply is started, a second timer means for starting time measurement of a second time period larger than the first time period, and the first timer based on the water supply stop signal or the time end signal of the first time period. To stop water supply to two water supply units
And a second control unit for stopping water supply to the one water supply unit based on the time end signal of the second time period when an abnormality occurs in the first control unit. A beverage supply device characterized by the above-mentioned. 2. The method according to claim 1, wherein the second timer means starts counting time of the second time period assuming that water is started to be supplied to the one water supply unit when current is supplied to the water inlet solenoid valve. 2. The beverage supply device according to claim 1, wherein the second control unit stops supplying water to the one water supply unit by interrupting a current supplied to the water inlet solenoid valve. 3. 3. The first control means stops water supply to the one water supply unit under the control of a CPU, and the second timer means and the second control means operate the second water supply means by a time relay. The beverage supply device according to claim 1, wherein the time measurement of the time limit is started and water supply to the one water supply unit is stopped. 4. The apparatus according to claim 1, wherein said first and second control means include a CPU.
The beverage supply device according to claim 1, wherein the water supply to the one water supply unit is stopped by the control of (1). 5. The water supply unit is a water tank that cools a drink with the supplied water, and the signal generation unit detects at least an upper limit water level of the water in the water tank and outputs the water supply stop signal. The beverage supply device according to claim 1, wherein the beverage supply device is a float switch configured to output an upper limit water level detection signal. 6. The one water supply section is a carbonator for producing carbonated water from the supplied water and carbon dioxide gas, and the signal generating means detects at least an upper limit water level of carbonated water in the carbonator. The beverage supply device according to claim 1, wherein the beverage supply device is a float switch configured to output an upper limit water level detection signal as the water supply stop signal. 7. The apparatus according to claim 1, wherein said second control means includes a notifying means for notifying an abnormality of said signal generating means or said first control means when stopping water supply to said one water supply section. A beverage supply control device according to claim 1.