KR920007452Y1 - Hot/cold-water supply system - Google Patents

Abstract

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Description

Separate cold and hot water machine

1 is a cross-sectional view of a conventional cold and hot water heater structure.

2 is a control circuit diagram of FIG.

3 is a cross-sectional view of the structure of a separate chiller according to the present invention.

4 is a detailed cross-sectional view of the main portion in FIG.

5 is a solenoid valve structure diagram in FIG.

6 is a control circuit diagram of FIG.

* Real names of symbols on the main parts of the drawings

1: Main tank 2: Sub tank

3: chiller pipe 4: warmer heater

5: Manual Valve 6: Solenoid Valve

7: plotter support 8: drinking water

9: plotter 10: magnet

11: proximity switch 12: spring

13: gasket 14: solenoid coil

15: water pipe 16: solenoid rod

17: cold and hot water control switch 18: hot and cold temperature controller

19: refrigeration temperature controller 20: overload protection device

21: compressor motor 22: relay

23: transistor 24, 25: resistor

The present invention relates to a cold and hot water machine, and in particular, to separate the hot and cold water tank into the main water tank and the auxiliary water tank to heat or refrigerate only the required amount of drinking water to separate the hot and cold water heater to shorten the temperature control time and to save power when switching the hot and cold water function. .

The prior art configuration is to wrap the cooler pipe (3) in the surgical lower portion of the water tank (1), as shown in Figure 1, mounted on the lower end of the water tank (1) to the lower side of the water tank (1) The water pipe 15 is connected, and the water pipe is equipped with a manual valve (5).

As shown in FIG. 2, the control circuit connects the 'C' terminal of the cold / hot water control switch 17 to one side of the power supply, and the refrigerator temperature controller 19 and the overload protection device 20 to the 'B' terminal. The motors 21 are connected in series, and the other end of the compressor motor 21 is connected to the opposite side of the power source.

'A' terminal of the cold, hot water control switch 17 is connected directly to the power supply after connecting the warm temperature controller 18 and the heater (4).

Therefore, when the user selects the refrigerating function by operating the cold / hot water control switch 17 of FIG. The water tank 1 cools and becomes low temperature.

At this time, when the temperature falls below a certain low temperature, the contact point of the refrigeration temperature controller 19 is 'off' so that the compressor motor 21 is stopped and the compressor motor 21 is intermittently fitted to meet the retention zone of the refrigeration temperature controller 19. The temperature of the drinking water (8) in the water tank (1) is kept at the refrigerating temperature.

If the user selects the contact function of the switch 17 as A and selects the heating function, the temperature of the drinking water 8 is increased by heating the heated heater 4 installed at the bottom of the water tank 1, and the temperature of the heated temperature controller 18 is increased. When the temperature reaches the holding temperature range, the contact point of the warm temperature controller 18 is turned off to stop the heating to maintain the temperature of the drinking water 8 according to the warm temperature.

However, such a conventional structure heats or cools the whole drinking water in the water tank (1) during refrigeration or warming, and the actual user needs a small amount of water to be taken out for a long time, thus unnecessary power consumption caused by temperature control of the whole drinking water. There was a problem that it takes a long time for the temperature conversion when switching between and warm and cold.

Accordingly, the present invention is intended to eliminate the above problems, as shown in FIG. 3, connecting the lower end of the main tank (1) and one side of the upper end of the auxiliary tank (2) with a water pipe (15) and the water pipe (15) The solenoid valve 6 is mounted in the middle to interrupt the amount of drinking water 8 flowing through the water pipe 15.

The auxiliary water tank 2 is installed at the lower part of the main water tank 1, and the cooler pipe 3 is wound around the side wall of the auxiliary water tank 2, and the warm water heater 4 is embedded at the bottom.

Inside the auxiliary water tank 2, a plotter support 7 is installed, a floater 9 is provided between the supports 7, a magnet 10 is embedded in the upper center of the floater 9, and an upper part of the plotter 9 is installed. A proximity switch 11 is installed on the inner wall of the auxiliary water tank 2.

The inner structure of the solenoid valve 6 is provided with a gasket 13 so as to extend a part of the water pipe 15 to prevent the flow of drinking water 8 therein, and the solenoid rod 16 and the solenoid coil therein as shown in FIG. The spring 12 is installed (14) and the gasket 13 is contracted or expanded according to the elasticity of the spring 12 and the excited state of the solenoid coil 14 to open and close the water pipe 15.

The control circuit connects the normal close contact (NC) of the solenoid 14 and the relay 22 to both ends of the power supply as shown in FIG. 6, one side of the coil of the relay 22 to the DC power supply VDD, and the other side to the transistor 23. Is connected to the collector (C) stage, and the emitter of the transistor 23 is grounded.

In addition, one end of the proximity switch 11 is connected to the DC power supply (VDD) and the opposite side is directly connected to the resistors 24 and 25. Then, the resistor 25 is grounded and the connection point between the resistor 24 and the resistor 25 is a transistor. The transistor 23 is 'on' or 'off' according to the contact state of the proximity switch 11 by being connected to the base of (23).

The other circuit is the same as the conventional one.

Therefore, when the initial power is turned on, the contact of the proximity switch 11 is "opened" by the position (life height) of the plotter 9 inside the auxiliary tank 2 as shown in the detail of FIG. Or "lung".

That is, when the drinking water of the auxiliary water tank 2 is input by a certain level, since the plotter 9 is in close contact with the proximity switch 11, the contact of the proximity switch 11 is "on" and the magnet 10 On ') When the water level is low, since the plotter 9 and the proximity switch 11 are spaced apart, the contact point of the proximity switch 11 is turned off.

If the contact of the proximity switch 11 is 'on', that is, if the water level reaches a certain level in the circuit diagram of the present invention shown in FIG. The collector and emitter of the circuit are conducting and the coil of the relay 22 is excited so that the contact is moved from normal cross (NC) to normal open (NO) and no current flows in the solenoid coil 14 (FIG. 5). Since the gasket 13 is pushed downward by the spring 12 elasticity of the spring 12 and the water pipe 15 is blocked, the flow of the drinking water 8 is stopped, so that the water in the main tank 1 is not supplied to the auxiliary tank 2.

Then, when the user opens the manual valve (5) and draws out the drinking water by the required amount, the water level of the auxiliary structure (2) gradually decreases and decreases more than a predetermined amount. The contact of (11) is 'off'.

As such, when the water level is lower than the predetermined level, the contact of the proximity switch 11 is 'off' and the contact of the proximity switch 11 is 'off' at the sixth, so that the collector and the emitter of the transistor 23 are not allowed to communicate with the relay 22. Since no current flows through the coil of), the contact is moved from normal open (NO) to normal cross (NC), so that current flows through the solenoid coil 14 and is pushed up to the upper side of the solenoid rod 16 of FIG. As the gasket 13 is contracted and the water pipe 15 is opened, the drinking water 8 of the main water tank 1 comes out of the auxiliary water tank 2 due to the potential energy difference, and the water level of the auxiliary water tank 2 rises. (9) also rises, the drinking water moves until the proximity of the switch 11 is turned on.

By repeating the above process, the auxiliary tank 2 is always adjusted to a certain amount of water level.

Temperature control of the drinking water of the auxiliary tank (2) is the same as the conventional method, the temperature of the main water tank (1) is determined by the ambient temperature, and only the auxiliary water tank (2) is cooled or heated.

The separate cold / hot water heater according to the above-mentioned innovation prevents unnecessary power loss by controlling the amount of drinking water without cooling or heating the water in the tank as a whole, and the temperature control of the drinking water is only in the auxiliary tank, so the function is switched between hot and cold. When the temperature of drinking water can be adjusted quickly.

Claims (2)

In the cold and hot water machine, the auxiliary water tank (2) is installed in the lower part of the main water tank (1), but connects between the lower end of the water tank (1) and one side of the upper end of the auxiliary water tank (2) by the water pipe (15), the water pipe (15) The solenoid valve 6 is installed in the middle to interrupt the drinking water flowing through the water pipe 15, and the cooler pipe 3 is wound on the outside of the side wall of the auxiliary water tank 2, and the warm heater 4 is buried under the inside. Plotter support (7) is installed in the above, so that the floater 9 installed between the support (7) can move up and down according to the water level, and the magnet (10) is embedded in the upper center of the floater (9) up and down the flutter (9) A proximity type cold / hot water heater, characterized in that the proximity switch (11) installed on the inner wall of the upper portion of the floater (9) is controlled by movement to control the amount of drinking water of the auxiliary tank to be cooled / heated. The solenoid valve 6 which regulates drinking water is opened and closed by the transistor 23 and the relay 22 which interlock with the proximity switch 11, and supplies drinking water of the main water tank 1 to the auxiliary water tank 2. Separable cold and hot water supply, characterized in that supplied to.