CN214017157U - Water consumption control system for steam box of integrated stove - Google Patents

Abstract

The utility model discloses an integrated kitchen steam ager water consumption control system relates to integrated kitchen control technique, aims at solving when the water tank normal water volume of steam ager is not enough, then needs people manually to open the tap and carry out the moisture and supply to still need examine the water yield in the water tank when leading to people to use the steam ager, the too numerous and diverse problem of step, its technical scheme main points are: the water level detection circuit is used for respectively outputting a first water level signal and a second water level signal when the water level in the water tank is at a first reference water level and a second reference water level, and the level height of the first reference water level is higher than the second reference water level; and the first timing circuit is coupled with the output end of the water level detection circuit, triggers and starts timing after receiving the first water level signal, and outputs a first timing signal. The utility model discloses can supply the water yield in the water tank voluntarily, make things convenient for people to use the steam ager.

Description

Water consumption control system for steam box of integrated stove

Technical Field

The utility model relates to an integrated kitchen control technology, more specifically say, it relates to an integrated kitchen steam ager water consumption control system.

Background

The integrated kitchen range is a kitchen appliance integrating multiple functions of a range hood, a gas stove, a disinfection cabinet, a storage cabinet, a steam box and the like, is also called as an environment-friendly kitchen range or an integrated environment-friendly kitchen range in the industry, has the advantages of space saving, good oil fume extraction effect, energy saving, low consumption, environment friendliness and the like, the oil absorption rate of a common integrated kitchen range reaches 95%, the oil fume extraction rate is higher, the quality is better, and the oil fume extraction rate of some brands of integrated kitchen ranges reaches 99.95%.

Wherein the steam ager in the integrated kitchen mainly cooks the inside food of steam ager through steam generator, can set up the water tank usually in the integrated kitchen, need carry out the during operation at the steam ager and directly carry out steam generation through water pump extraction water from the water tank in, but when the water tank normal water volume of steam ager was not enough, then need the manual tap of opening of people to carry out the moisture and supply to still need to inspect the water yield in the water tank when leading to people to use the steam ager, the step is too complicated.

Therefore, a new solution is needed to solve this problem.

SUMMERY OF THE UTILITY MODEL

Not enough to prior art exists, the utility model aims to provide an integrated kitchen steam ager water consumption control system can supply the water yield in the water tank voluntarily, makes things convenient for people to use the steam ager.

The above technical purpose of the present invention can be achieved by the following technical solutions: an integrated kitchen steam box water consumption control system includes:

the water level detection circuit is used for respectively outputting a first water level signal and a second water level signal when the water level in the water tank is at a first reference water level and a second reference water level, and the level height of the first reference water level is higher than the second reference water level;

the first timing circuit is coupled with the output end of the water level detection circuit, triggers and starts timing after receiving the first water level signal, and outputs the first timing signal within the timing time;

the first switch circuit is coupled with the output end of the first timing circuit and coupled with the water treatment circuit, is coupled with the first timing circuit after responding to the conduction of the first timing signal and responds to the conduction of the first timing signal so as to supply power to the water softener;

the second timing circuit is coupled with the output end of the water level detection circuit, triggers and starts timing after receiving the second water level signal, and outputs a second timing signal;

and the second switching circuit is coupled with the output end of the second timing circuit and is coupled with the water injection circuit, and the water injection circuit injects water into the water tank within the timing time after the second switching circuit responds to the conduction of the second timing signal.

Through adopting above-mentioned technical scheme, when people need use this system, this system only need keep the state of circular telegram, can make water level detection circuit can detect the water yield in the water tank, and can come to handle in advance the water that gets into the water tank through water treatment circuit when the water yield is few, and after water treatment is good, then can come to carry out the water injection in the water tank through the water injection circuit, when the water yield in the water tank reaches standard, water level detection circuit then can control water treatment circuit and water injection circuit disconnection power consumption, thereby make the water yield in the water tank suitable, and need not people's manual adjustment.

The utility model discloses further set up to: the water level detection circuit comprises a first Hall sensor and a second Hall sensor which are fixedly connected to the outer peripheral wall of the water tank and a magnetic floating ball located in the water tank, the horizontal height of the first Hall sensor is higher than that of the second Hall sensor, the first Hall sensor and the second Hall sensor are respectively coupled with a first trigger circuit and a second trigger circuit, and the lifting track of the magnetic floating ball in the water tank is in a vertical linear shape.

The utility model discloses further set up to: the water tank is internally provided with a limiting assembly communicated with the inside of the water tank, and the magnetic floating ball is vertically and slidably connected with the inside of the limiting assembly.

The utility model discloses further set up to: the first Hall sensor and the second Hall sensor are both switch type Hall sensors.

The utility model discloses further set up to: a first inverter and a second inverter are respectively coupled between the first hall sensor and the first trigger circuit and between the second hall sensor and the second trigger circuit, and the first trigger circuit and the second trigger circuit are both monostable trigger circuits.

The utility model discloses further set up to: the first switch circuit comprises a first triode switch circuit which is conducted in response to the first timing signal, and a first relay switch circuit which is coupled with the first triode switch circuit and supplies power to the water softener when the first triode switch circuit is conducted.

The utility model discloses further set up to: the second switch circuit comprises a second triode switch circuit which is conducted in response to the second timing signal and a second relay switch circuit which is coupled with the second triode switch circuit and supplies power to the water pump when the second triode switch circuit is conducted.

To sum up, the utility model discloses following beneficial effect has:

when people need use this system, this system only need keep the state of circular telegram, can make water level detection circuit can detect the water yield in the water tank, and can come to handle in advance the water that gets into the water tank through water treatment circuit when the water yield is few, and after water treatment is good, then can come to carry out the water injection in the water tank through the water injection circuit, when the water yield in the water tank reaches standard, water level detection circuit then can control water treatment circuit and water injection circuit disconnection power consumption, thereby make the water yield in the water tank suitable, and need not the manual adjustment of people.

Drawings

FIG. 1 is a block diagram of the present invention;

fig. 2 is a circuit diagram of the middle water level detection circuit, the first trigger circuit, the second trigger circuit, the first switch circuit and the second switch circuit of the present invention;

FIG. 3 is a circuit diagram of the reclaimed water treatment circuit of the present invention;

fig. 4 is a circuit diagram of the injection circuit of the present invention.

In the figure: 1. a water level detection circuit; 2. a first timing circuit; 3. a second timing circuit; 4. a first switching circuit; 5. a second switching circuit; 6. a water treatment circuit; 7. a water injection circuit.

Detailed Description

The present invention will be described in detail with reference to the accompanying drawings and examples.

Example (b):

the utility model provides an integrated kitchen steam ager water consumption control system, refers to figure 1, includes water level detection circuit 1, first timing circuit 2, second timing circuit 3, first switch circuit 4, second switch circuit 5, water treatment circuit 6 and water injection circuit 7.

The water level detection circuit 1 is used for outputting a first water level signal and a second water level signal when the water level in the water tank is at a first water level and a second water level, and the level of the first water level is higher than the second water level.

For the first timing circuit 2 and the second timing circuit 3, the input terminals of the two are respectively coupled to the two output terminals of the water level detection circuit 1, the first timing circuit 2 triggers and starts timing after receiving the first water level signal, and simultaneously outputs the first timing signal, and the second timing circuit 3 triggers and starts timing after receiving the second water level signal, and outputs the second timing signal.

For the first switch circuit 4 and the second switch circuit 5, the input end of the first switch circuit 4 is coupled to the output end of the first timing circuit 2 and coupled to the water treatment circuit 6, the first switch circuit 4 is coupled to the output end of the second timing circuit 3 and coupled to the water injection circuit 7 after being turned on in response to the first timing signal, and the water treatment circuit 6 operates within the timing time, while the second switch circuit 5 is coupled to the output end of the first timing circuit 4 and coupled to the water injection circuit 7, and the water injection circuit 7 injects water into the water tank within the timing time after the second switch circuit 5 is turned on in response to the second timing signal.

Referring to fig. 2, the water level detection circuit 1 includes a first hall sensor H1, a second hall sensor H2 and a magnetic floating ball, the first hall sensor H1 and the second hall sensor H2 are both switch type hall sensors, the first hall sensor H1 and the second hall sensor H2 are fixedly connected to the outer peripheral wall of the same side of the water tank, the first hall sensor H1 is located above the second hall sensor H2, the second hall sensor H1 is located at a high water level, the second hall sensor H2 is located at a low water level, the pin 1 of the first hall sensor H1 is grounded, the pin 2 is connected to the power supply, the pin 3 is connected to the first timing circuit 2, the pin 1 of the second hall sensor H2 is grounded, the pin 2 is connected to the power supply, and the pin 3 is connected to the second timing circuit 3.

The bottom surface is close to the spacing subassembly of one side fixedly connected with of first hall sensor H1 and second hall sensor H2 in the water tank, and the magnetic force floater is located spacing subassembly to receive spacing of spacing subassembly, thereby make the lift orbit of magnetic force floater in the water tank be vertical line.

The limiting assembly comprises a pipe body fixedly connected to the bottom surface in the water tank, and a gap communicating the inside of the pipe body with the inside of the water tank is formed in the pipe body.

The first timing circuit 2 comprises a first phase inverter CMOS1, a first 555 time-base chip, a resistor R1 and a capacitor C1, wherein the input end of the first phase inverter CMOS1 is connected with a pin 3 of a first Hall sensor H1, the output end of the first phase inverter CMOS1 is connected with a pin 2 of the first 555 time-base chip, a pin 4 and a pin 8 of the first 555 time-base chip are connected with a power supply, a pin 1 of the first 555 time-base chip is grounded, a pin 6 is connected with a pin 7, the pin is connected with VCC after being connected with R1 in series, the pin 6 is connected with the capacitor C1 in series and then grounded, the first 555 time-base chip is connected to form a monostable trigger, and the pin 3 is an output end.

The first switch circuit 4 comprises a resistor R2, a triode V T1, a first relay K2 and a diode VD1, one end of the resistor R2 is connected with the 3 pins of the first 555 time base chip, the other end of the resistor R2 is connected with the base electrode of the triode V T1, the emitter electrode of the triode V T1 is grounded, the collector electrode of the triode V VD1 is connected with a power supply through the first relay K2, and the diode V VD1 is connected with the first relay K2 in parallel.

Referring to fig. 3, the water treatment circuit 6 includes a water softener connected to a power source through a first normally open contact K2-1, a first normally open contact K2-1, and the first normally open contact K2-1 is controlled by a first relay K2.

The second timing circuit 3 comprises a second phase inverter CMOS2, a second 555 time-base chip, a resistor R4 and a capacitor C2, wherein the input end of the second phase inverter CMOS2 is connected with a pin 3 of the second Hall sensor H2, the output end of the second phase inverter CMOS2 is connected with a pin 2 of the second 555 time-base chip, pins 4 and 8 of the second 555 time-base chip are connected with a power supply, a pin 1 of the second 555 time-base chip is grounded, pins 6 and 7 are in short circuit, the short circuit positions are respectively connected with the power supply through a resistor R4 and grounded through a C2, the second 555 time-base chip is connected to form a monostable trigger, and the pin 3 is an output end.

The second switch circuit 5 comprises a resistor R5, a triode two VT2, a second relay K1 and a diode two VD2, one end of the resistor R5 is connected with the 3 pins of the second 555 time base chip, the other end of the resistor R5 is connected with the base electrode of the triode two VT2, the emitter electrode of the triode two VT2 is grounded, the collector electrode of the triode two VT2 is connected with a power supply through the second relay K1, and the diode two VD2 is connected with the second relay K1 in parallel.

Referring to fig. 4, the water filling circuit 7 includes a water pump, a second normally open contact K1-1, the water pump is connected with the power supply through the second normally open contact K1-1, and the second normally open contact K1-1 is controlled by a second relay K1.

When the water level in the water tank begins to fall, the magnetic floating ball falls along with the water level in the pipe body, when the magnetic floating ball falls to the level height of the first Hall sensor H1, the first Hall sensor H1 generates a high-level signal and transmits the high-level signal to the first phase inverter CMOS1, so that the high-level signal is converted into a low-level signal, the low-level signal is input into 2 pins of the first 555 time base chip, 3 pins of the first 555 time base chip output the high-level signal, in the process, the first 555 time base chip serves as a timer, the high-level signal is output within the timing time and transmitted to the base of the triode VT1, the base of the triode VT1 obtains the high-level signal, so that the collector and the emitter of the triode VT1 are conducted, a circuit where the first relay K2 is located keeps a circuit, so that the first relay K2 is powered and controls the first normally open contact K2-1 to be closed, the circuit of the water softener is also conducted and starts to operate, so that the water softener starts to operate, and stops operating after the high-level signal is finished.

Then the water level will continue to drop, the magnetic floating ball will drop to the level height of the second hall sensor H2, the second hall sensor H2 will generate high level signal and transmit it to the second inverter CMOS2, so as to convert the high level signal into low level signal, the low level signal is input into the 2 pin of the second 555 time base chip, the 3 pin of the second 555 time base chip outputs high level signal, in this process, the second 555 time base chip also serves as timer, outputs high level signal with certain pulse width, and transmits it to the base of the triode second VT2, the base of the triode second VT2 is conducted, so as to conduct the collector and emitter of the triode second VT2, the circuit of the second relay K1 is kept through, so that the second relay K1 is powered and controls the second normally open contact K1-1 to be closed, the circuit of the water pump is conducted and starts to operate, so that the water pump starts to work, the water which is treated in the water softener is injected into the water tank, and the water pump stops working after the high-level signal is finished.

In the process of carrying out the water injection in the water pump to the water tank, the water yield in the water tank can increase, the liquid level rises from this, the magnetic force floater also rises along with the liquid level, and pass through the level at first hall sensor H1 place again, when the magnetic force floater arrives the level at first hall sensor H1 place, through the same mode as above-mentioned, the water softener can work for a period of time again, make can preserve some moisture that has handled in the water softener and carry out reserve, and when water is not enough again, the water softener starts work again, thereby make it to handle good water, pump through the water pump, make the water pump increase the water yield in the water tank to the level after-position at first hall sensor H1 place, at this moment, still keep some moisture that handles in the water softener reserve.

It is above only the utility model discloses a preferred embodiment, the utility model discloses a scope of protection does not only confine above-mentioned embodiment, the all belongs to the utility model discloses a technical scheme under the thinking all belongs to the utility model discloses a scope of protection. It should be noted that, for those skilled in the art, various modifications and decorations can be made without departing from the principle of the present invention, and these modifications and decorations should also be regarded as the protection scope of the present invention.

Claims (7)

1. The utility model provides an integrated kitchen steam ager water consumption control system which characterized in that: comprises that

The water level detection circuit (1) is used for respectively outputting a first water level signal and a second water level signal when the water level in the water tank is at a first benchmark water level and a second benchmark water level, and the horizontal height of the first benchmark water level is higher than the second benchmark water level;

the first timing circuit (2) is coupled with the output end of the water level detection circuit (1), triggers and starts timing after receiving the first water level signal, and outputs the first timing signal within the timing time;

the first switch circuit (4) is coupled with the output end of the first timing circuit (2) and is coupled with the water treatment circuit (6), and the first switch circuit (4) is coupled with the first timing circuit (2) after responding to the conduction of the first timing signal and is conducted in response to the first timing signal so as to supply power to the water softener;

the second timing circuit (3) is coupled with the output end of the water level detection circuit (1), triggers and starts timing after receiving the second water level signal, and outputs the second timing signal;

and the second switch circuit (5) is coupled with the output end of the second timing circuit (3) and is coupled with the water injection circuit (7), and after the second switch circuit (5) is switched on in response to the second timing signal, the water injection circuit (7) injects water into the water tank within the timing time.

2. The water consumption control system of the integrated kitchen steam box according to claim 1, characterized in that: the water level detection circuit (1) comprises a first Hall sensor and a second Hall sensor which are fixedly connected to the outer peripheral wall of the water tank and a magnetic floating ball located in the water tank, the horizontal height of the first Hall sensor is higher than that of the second Hall sensor, the first Hall sensor and the second Hall sensor are respectively coupled with a first trigger circuit and a second trigger circuit, and the lifting track of the magnetic floating ball in the water tank is in a vertical linear shape.

3. The water consumption control system of the integrated kitchen steam box according to claim 2, characterized in that: the water tank is internally provided with a limiting assembly communicated with the inside of the water tank, and the magnetic floating ball is vertically and slidably connected with the inside of the limiting assembly.

4. The water consumption control system of the integrated kitchen steam box according to claim 2, characterized in that: the first Hall sensor and the second Hall sensor are both switch type Hall sensors.

5. The water consumption control system of the integrated kitchen steam box according to claim 4, characterized in that: a first inverter and a second inverter are respectively coupled between the first hall sensor and the first trigger circuit and between the second hall sensor and the second trigger circuit, and the first trigger circuit and the second trigger circuit are both monostable trigger circuits.

6. The water consumption control system of the integrated kitchen steam box according to claim 1, characterized in that: the first switch circuit (4) comprises a first triode switch circuit which is conducted in response to the first timing signal and a first relay switch circuit which is coupled with the first triode switch circuit and supplies power to the water softener when the first triode switch circuit is conducted.

7. The water consumption control system of the integrated kitchen steam box according to claim 1, characterized in that: the second switch circuit (5) comprises a second triode switch circuit which is conducted in response to the second timing signal and a second relay switch circuit which is coupled with the second triode switch circuit and supplies power to the water pump when the second triode switch circuit is conducted.

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