CN215938353U - Automatic generator and atomizer for sterilized water - Google Patents

Abstract

The utility model discloses an automatic generator of disinfectant fluid, which comprises a material storage tank, a quantitative feeding box and a liquid storage tank which are sequentially arranged from top to bottom, wherein an electrode group is arranged in the liquid storage tank, a delay switch is arranged in the quantitative feeding box, and the delay switch is electrically connected with the electrode group and can be connected with an external power supply through an electric wire so as to electrolyze liquid in the liquid storage tank. Also discloses an automatic generating and atomizing device for the sterilized water, which further comprises an ultrasonic atomizing unit, wherein the ultrasonic atomizing unit comprises an ultrasonic generator and an ultrasonic atomizing sheet which are connected through electric wires. Can be used for ultrasonic atomization humidification, disinfectant preparation, electrolytic disinfectant preparation and atomization as required, can be used for indoor humidification, sterilization, formaldehyde removal, vegetable and fruit disinfection and the like, and has the advantages of easily available raw materials and convenient operation.

Description

Automatic generator and atomizer for sterilized water

Technical Field

The utility model relates to the technical field of disinfection and sterilization, in particular to an automatic disinfectant generator and an atomizer.

Background

In daily life, disinfection liquid is often needed, for example, tableware, fruits and vegetables, clothes, daily necessities and the like are needed to be disinfected; there are occasions where air sterilization is also required in certain situations, such as hospitals, stations, or in cases of infectious epidemics, where there are many people in order to reduce the spread of germs and viruses. The commercially available disinfection solution is expensive, and especially, a large amount of disinfection solution is needed during the period of epidemic diseases, so the cost problem of the disinfection solution is very important.

The sodium hypochlorite is an efficient and safe disinfectant, can be automatically degraded into nontoxic sodium chloride in the environment, and avoids adverse effects on human bodies and the environment. At present, different small generators for generating sodium hypochlorite by using salt exist in the market, but the salt is required to be manually measured and added, and the salt is manually sprayed, so that the sprayed fog water has large and uneven particles, is suitable for manually spraying and disinfecting specific objects, and is not suitable for automatically disinfecting air.

Compared with a spray atomizer, the ultrasonic atomizer can obtain superfine easily-dispersed atomized liquid and is widely applied to the fields of medical treatment, indoor humidification, disinfection, air purification and the like. In the field of medical care, the medicament is put into dispersion liquid, and the dispersion liquid is atomized in the air by ultrasound so as to be absorbed by the skin or respiratory tract of a human body to exert the medicinal effect. In the field of air purification, a disinfectant is added into ultrasonic liquid to prevent bacteria in atomized liquid from growing and to purify air.

The Chinese patent publication No. CN205073349U proposes that an electrolytic bath is used for electrolyzing a sodium chloride solution to generate a disinfectant, and an ultrasonic generator is used for atomizing the disinfectant for the field of seedling culture and food processing. Chinese patent application CN201310637900.2 discloses a method for producing a disinfectant by electrolyzing a potassium chloride solution in an electrolytic cell and atomizing the disinfectant by an ultrasonic generator for plant disinfection and fertilization. The device is a mechanical combination of generating disinfectant through electrolysis and ultrasonic atomization, is only applied to large occasions, and is not high in automation degree in daily life and inconvenient to use.

In summary, although some of the currently marketed ultrasonic atomizer products have the additional function of adding solids into the dispersion, the ultrasonic atomizer is limited to large-scale equipment and is not suitable for an ultrasonic atomizer with a compact structure; or the prior small-sized sterilized water generator needs to manually add the solid by a spoon, has complex operation, can not spray ultrasonically, and has limited application range.

SUMMERY OF THE UTILITY MODEL

The present invention has been made in view of the above problems, and an object of the present invention is to provide an automatic generator of sterilized water.

In order to achieve the purpose, the utility model adopts the technical scheme that:

an automatic disinfectant liquid generator comprises a material storage tank, a quantitative feeding box and a liquid storage tank which are sequentially arranged from top to bottom, wherein a first discharge hole is formed in the bottom of the material storage tank, a first feed hole is formed in the top of the quantitative feeding box, a second discharge hole is formed in the bottom of the quantitative feeding box, a second feed hole is formed in the top of the liquid storage tank, the first discharge hole and the first feed hole can be fixedly connected so as to connect the material storage tank and the quantitative feeding box, and the second discharge hole and the second feed hole can be fixedly connected so as to connect the quantitative feeding box and the liquid storage tank;

an electrode group is arranged in the liquid storage tank, a delay switch is arranged in the quantitative feeding box, and the delay switch is electrically connected with the electrode group and can be connected with an external power supply through an electric wire so as to electrolyze liquid in the liquid storage tank.

In the technical scheme, the quantitative feeding box is a quantitative feeding box A which comprises a shell A and a columnar first material transfer box in the shell A, a first feeding port A and a second discharging port A which are arranged on the shell A are arranged in a vertically staggered manner, the first feeding port A is close to the right end of the shell A, the second discharging port A is close to the left end of the shell A, the time delay switch is arranged on the left side wall of the shell A, the top of the first material transfer box is open, the bottom of the first material transfer box is provided with a movable bottom plate, the right end of the movable bottom plate is hinged on the first material transfer box, the left end of the movable bottom plate is not fixed, a spring is arranged between the first material transfer box and the delay switch, two ends of the spring are respectively and fixedly connected with the first material transfer box and the delay switch, a button A is fixedly arranged on the right outer side of the first material transfer box, and the right end of the button A penetrates through the shell A and is exposed outside the shell A; a flanging edge extending outwards is arranged at the right top of the first material transfer box; when the button A is not pressed, the first feeding port A of the quantitative charging box is opposite to and communicated with the top of the first material transfer box.

Or the quantitative feeding box is a quantitative feeding box B which comprises a shell B and a second material transfer box in the shell B, and a first feeding hole B and a second discharging hole B which are arranged on the shell B are arranged in an up-down opposite mode;

the main body of the second material transfer box is a cylinder body with two open ends, the cylinder body is fixedly arranged in a shell B, the top and the bottom of the cylinder body are correspondingly provided with a top plate and a bottom plate, through holes are formed in the top plate and the bottom plate, the upper part of the left side wall of the shell B is provided with a delay switch which is at the same height as the top plate, an upper spring is arranged between the delay switch and the top plate, two ends of the upper spring are respectively and fixedly connected with the delay switch and the top plate, a lower spring is arranged between the bottom plate and the left side wall of the shell B, one end of the lower spring is fixed on the shell B, and the other end of the lower spring is fixed on the bottom plate;

a torsion bar is arranged between the top plate and the bottom plate, two ends of the torsion bar are respectively and fixedly connected with the right end of the top plate and the right end of the bottom plate, a button B is fixedly arranged at the joint of the torsion bar and the top plate, and the right end of the button B penetrates through the shell B and is exposed outside the shell B; when the button B is not pressed down, the through hole on the top plate is opposite to the first feed port B, and the through hole on the bottom plate is positioned on the left outer side of the cylinder body, so that the cylinder body cannot be communicated with the second discharge port B;

when the button B is pressed, the top plate moves leftwards, the through hole in the top plate moves leftwards, meanwhile, the torsion bar drives the bottom plate to move rightwards, and the through hole in the bottom plate is opposite to the second discharge hole B, so that the interior of the cylinder is communicated with the second discharge hole B.

Or the quantitative feeding box is a quantitative feeding box C which comprises a shell C and a third material transfer box in the shell C, a first feeding hole C and a second discharging hole C which are arranged on the shell C are oppositely arranged up and down, a sealing flat plate A is arranged at the bottom of the first feeding hole C, the left end of the sealing flat plate A is hinged to the first feeding hole C, the right end of the sealing flat plate A is not fixed, and a delay switch is arranged on the left side wall of the shell C;

the third material transfer box comprises a cylindrical outer box A and a first inner box, the outer box A is fixed in the shell C, the first inner box is nested in the outer box A, the top and the bottom of the outer box A are respectively provided with a first opening and are respectively fixedly connected with the first feed inlet C and the second discharge outlet C and communicated with the first feed inlet C and the second discharge outlet C, a first rotating shaft is arranged in the shell C, one end of the first rotating shaft is connected with the shell C, the other end of the first rotating shaft penetrates through the third material transfer box and penetrates out of the shell C to be fixedly connected with the knob A, a torsional spring is sleeved on the first rotating shaft, two torsion arms of the torsional spring are respectively fixedly connected with the top and the bottom of the shell C, a trigger rod A is vertically arranged on the first rotating shaft, the position of the trigger rod A on the first rotating shaft corresponds to the position of the delay switch, and the first rotating shaft drives the first inner box and the trigger rod A to rotate when the knob A is rotated, when the knob A is rotated for 180 degrees, the trigger rod A triggers the delay switch;

a first material inlet and outlet is formed in the first inner box, the first material inlet and outlet is over against the first feeding hole C before the knob A is rotated, and the first material inlet and outlet is over against the second discharging hole C after the knob A is rotated 180 degrees.

Or the quantitative feeding box is a quantitative feeding box D, the quantitative feeding box D comprises a shell T and a fourth material transfer box in the shell T, a first feeding hole T and a second discharging hole T which are arranged on the shell T are oppositely arranged up and down, a sealing flat plate B is arranged at the bottom of the first feeding hole T, the left end of the sealing flat plate B is hinged to the first feeding hole T, the right end of the sealing flat plate B is not fixed, and a delay switch is arranged on the left side wall of the shell T;

the fourth material transfer box comprises a cylindrical outer box B and a second inner box, the outer box B is fixed in the outer shell B, the second inner box is nested in the outer box B, the top and the bottom of the outer box B are respectively provided with a second opening and are respectively fixedly connected and communicated with the first feed port D and the second discharge port D, a second rotating shaft is arranged in the outer shell D, one end of the second rotating shaft is connected with the outer shell D, and the other end of the second rotating shaft penetrates through the fourth material transfer box and penetrates out of the outer shell D to be fixedly connected with the knob B;

the inner part of the second inner box is divided into an upper cavity and a lower cavity by a partition plate, a second material inlet and a second material outlet are formed in the upper cavity and the lower cavity, a first gear rotary switch is arranged on a second rotating shaft, two trigger rods B are vertically arranged on the second rotating shaft, the two trigger rods B respectively correspond to the upper cavity and the lower cavity, the position of the trigger rod B on the second rotating shaft corresponds to the position of the time delay switch, the second rotating shaft drives the second inner box and the trigger rod B to rotate when the knob B is rotated, and the trigger rod B triggers the time delay switch; in a natural state, the second material inlet and outlet on the upper cavity body is over against the first feeding hole T, and the second material inlet and outlet on the lower cavity body is over against the second discharging hole T.

Or the quantitative feeding box is a quantitative feeding box E, the quantitative feeding box E comprises a shell E and a fifth material transfer box fixed in the shell E, a first feeding hole E and a second discharging hole E which are arranged on the shell E are oppositely arranged up and down, a sealing flat plate C is arranged at the bottom of the first feeding hole E, the left end of the sealing flat plate C is hinged to the first feeding hole E, the right end of the sealing flat plate C is not fixed, and a delay switch is arranged on the left side wall of the shell E;

the fifth material transfer box is cylindrical and horizontally arranged in the shell pentagon, third openings are formed in the top and the bottom of the fifth material transfer box and are respectively fixedly connected and communicated with the first feeding hole pentagon and the second discharging hole pentagon, a third rotating shaft is arranged in the shell pentagon, one end of the third rotating shaft is connected with the shell pentagon, the other end of the third rotating shaft penetrates through the fifth material transfer box and penetrates out of the shell pentagon to be fixedly connected with the knob pentagon, and a second gear rotary switch is arranged on the third rotating shaft;

a plurality of sector separation boards of fixedly connected with on the third rotation axis, leave the clearance between sector separation board's end and the inner wall that the fifth material shifted the box for sector separation board rotates along with the rotation of third rotation axis, and sector separation board equally divide the inside of fifth material shift box into a plurality of fan-shaped cavities, and a plurality of trigger bars of fixedly connected with on the third rotation axis third correspond a fan-shaped cavity, and the position of trigger bar third on the third rotation axis with delay switch's position is corresponding, and the third rotation axis drives the trigger bar third and rotates when rotating knob third, and the trigger bar third triggers delay switch.

Preferably, the liquid storage tank is provided with a water filling port, and the bottom of the liquid storage tank is provided with a liquid outlet; the liquid storage pot includes storage water tank and work basin, storage water tank detachably installs the top of work basin is provided with the inner tube in the storage water tank, the top of inner tube is opened and just is being used for the water storage to the second feed inlet at storage water tank top, and the chamber that the section of thick bamboo wall of inner tube and the outer wall of storage water tank enclose is used for the water storage, and the bottom of inner tube also opens to make the material that gets into from the second feed inlet directly fall into the work basin, is provided with the float valve on the bottom plate of storage water tank and is used for intaking to the work basin. The water storage tank and the working water tank are separately arranged, water is stored in the water storage tank, electrolysis and atomization are carried out in the working water tank, and the working water tank is controlled to be at a lower liquid level, so that ultrasonic atomization is facilitated.

The utility model also provides an automatic disinfectant fluid atomizer which comprises any one of the automatic disinfectant fluid generators and an ultrasonic atomizing unit, wherein the ultrasonic atomizing unit comprises an ultrasonic generator and an ultrasonic atomizing sheet which are connected through an electric wire, the ultrasonic atomizing sheet is arranged in the fluid reservoir to atomize the fluid in the fluid reservoir, and the ultrasonic generator is arranged outside the fluid reservoir; the upper part of the liquid storage tank is provided with a mist outlet.

When the automatic disinfectant generator adopts the quantitative feeding box A or the quantitative feeding box B, a time relay adjacent to the delay switch is further arranged on the inner surface of the left side wall of the quantitative feeding box, the time relay and the delay switch are both fixedly connected with the spring, and the action of the time relay and the delay switch is realized through the compression of the spring; the time relay is respectively connected with the ultrasonic generator and the ultrasonic atomization sheet through electric wires;

when the automatic disinfectant generator adopts the quantitative feeding box C, the quantitative feeding box D or the quantitative feeding box E, a time relay adjacent to the time delay switch is further arranged on the inner surface of the left side wall of the quantitative feeding box, the rotating knob drives the trigger rod to rotate through the gear rotating switch, the trigger rod touches the time relay and the time delay switch, and the time relay is electrically connected with the ultrasonic atomization unit.

Preferably, the ultrasonic atomization unit further comprises an external power supply, a liquid level control switch, a time control switch, a power control switch and a fan, wherein the liquid level control switch is electrically connected with a liquid level sensor arranged in the liquid storage tank, the time control switch, the power control switch and the fan are electrically connected with the ultrasonic generator, and the fan is installed inside the working water tank to promote the discharge of atomized liquid; the first lead of the connection time relay and the ultrasonic generator and the second lead of the connection time relay and the ultrasonic atomization sheet are connected through a third lead, and an atomization switch is arranged on the third lead;

diodes are arranged on the time relay and the atomization switch to ensure that current can only flow in a single direction, and short circuit caused by simultaneous connection of the time relay and the atomization switch is avoided.

The utility model has the beneficial effects that: the quantitative feeding box is simple in structure, novel and reasonable in design, easy to produce and manufacture, materials can be quantitatively fed by pressing the button or rotating the knob, manual quantity adding is not needed, automatic quantitative feeding is achieved, and operation is very convenient. The electrolytic generation and atomization of the disinfectant are automatically completed, and the safety protection is provided, so that the power is automatically cut off after the disinfectant is atomized, and the use is safe.

Drawings

Fig. 1 is a schematic view showing the construction of an automatic generator of sterilized water and an atomizer according to the present invention.

FIG. 2 is a schematic view of the structure of the quantitative charging cassette of example 1.

FIG. 3 is a schematic view of the structure of the quantitative charging cassette of example 2.

FIG. 4 is a schematic front view of the structure of the measuring cassette of example 3.

FIG. 5 is a schematic left side view of the structure of the quantitative charging cassette of example 3.

FIG. 6 is a schematic front view of the structure of the measuring cassette of example 4.

FIG. 7 is a schematic left side view of the structure of the quantitative charging cassette of example 4.

FIG. 8 is a schematic front view of the structure of the measuring cassette of example 5.

FIG. 9 is a schematic left side view of the structure of the quantitative charging cassette of example 5.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, but the present invention is not limited thereby. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Embodiment 1, automatic generator of sterilized water and atomizer

Automatic generator for disinfectant fluid

An automatic generator of sterilized water as shown in fig. 1 is mainly composed of a material storage tank 1, a quantitative feeding box and a liquid storage tank 2 which are arranged from top to bottom in sequence. The bottom of the material storage tank 1 is provided with a first discharge hole 1-1, the top of the quantitative feeding box is provided with a first feed hole, the bottom of the quantitative feeding box is provided with a second discharge hole, the top of the liquid storage tank 2 is provided with a second feed hole 2-1, the first discharge hole 1-1 and the first feed hole can be fixedly connected so as to connect the material storage tank 1 and the quantitative feeding box, and the second discharge hole and the second feed hole 2-1 can be fixedly connected so as to connect the quantitative feeding box and the liquid storage tank 2;

an electrode group 3 is arranged in the liquid storage tank 2, a delay switch 4 is arranged in the quantitative feeding box, the delay switch 4 is electrically connected with the electrode group 3 and can be connected with an external power supply through an electric wire so as to electrolyze liquid in the liquid storage tank 2.

In some embodiments, the quantitative feeding box adopts a quantitative feeding box A, as shown in FIG. 2, the quantitative feeding box A comprises an outer shell A-1 and a columnar first material transfer box A-2 in the outer shell A-1, a first material inlet A-3 and a second material outlet A-4 arranged on the outer shell A-1 are arranged in a staggered manner up and down, the first material inlet A-3 is close to the right end of the outer shell A-1, the second material outlet A-4 is close to the left end of the outer shell A-1, a delay switch 4 is arranged on the left side wall of the outer shell A-1, the top of the first material transfer box A-2 is open, a movable bottom plate A-5 is arranged at the bottom, the right end of the movable bottom plate A-5 is hinged on the first material transfer box A-2, the left end is not fixed, a spring A-6 is arranged between the first material transfer box A-2 and the delay switch 4, two ends of the spring A-6 are respectively fixedly connected with the first material transfer box A-2 and the delay switch 4, a button A-7 is fixedly arranged on the right outer side of the first material transfer box A-2, and the right end of the button A-7 penetrates through the shell A-1 and is exposed outside the shell A-1; a sealing flat plate A-8 is arranged at the bottom of the first material inlet A-3, the right end of the sealing flat plate A-8 is hinged to the first material inlet A-3, the left end of the sealing flat plate A-8 is not fixed, and a turned edge A-9 extending outwards is arranged at the right top of the first material transfer box A-2; when the button A-7 is not pressed, the first inlet A-3 of the quantitative charging box is opposite to and communicates with the top of the first material transfer box A-2.

In some embodiments, the liquid storage tank 2 is provided with a water filling port 2-2 and a liquid discharging port 2-3 at the bottom; the liquid storage tank 2 comprises a water storage tank 2-4 and a working water tank 2-5, the water storage tank 2-4 is detachably mounted at the top of the working water tank 2-5, an inner cylinder 2-6 is arranged in the water storage tank 2-4, the top of the inner cylinder 2-6 is open and faces a second feed inlet 2-1 at the top of the liquid storage tank 2, a cavity defined by the cylinder wall of the inner cylinder 2-6 and the outer wall of the water storage tank 2-4 is used for storing water, the bottom of the inner cylinder 2-6 is also open so that materials entering from the second feed inlet 2-1 directly fall into the working water tank 2-5, and a floating valve 2-7 is arranged on a bottom plate of the water storage tank 2-4 and used for feeding water into the working water tank 2-5.

Second, an automatic atomizer of disinfectant fluid

An automatic atomizer for sterilized water is mainly composed of the automatic generator for sterilized water and an ultrasonic atomization unit 5. The ultrasonic atomization unit 5 comprises an ultrasonic generator 5-1 and an ultrasonic atomization sheet 5-2 which are connected through an electric wire, the ultrasonic atomization sheet 5-2 is arranged in the liquid storage tank 2 to atomize the liquid in the liquid storage tank 2, and the ultrasonic generator 5-1 is arranged outside the liquid storage tank 2; the upper part of the liquid storage tank 2 is provided with mist outlets 2-8. The electrode group 3 and the ultrasonic atomization sheet 5-2 are both arranged in the working water tank 2-5.

In some embodiments, the inner surface of the left side wall of the quantitative charging box is further provided with a time relay 6 adjacent to the time delay switch 4, the time relay 6 and the time delay switch 4 are both fixedly connected with a spring, and the action of the time relay 6 and the time delay switch 4 is realized through the compression of the spring; the time relay 6 is respectively connected with the ultrasonic generator 5-1 and the ultrasonic atomization sheet 5-2 through electric wires;

in some embodiments, the ultrasonic atomization unit 5 further comprises an external power supply 5-3, a liquid level control switch 5-4, a time control switch 5-5, a power control switch 5-6 and a fan 5-8, wherein the liquid level control switch 5-4 is electrically connected with a liquid level sensor arranged in the liquid storage tank 2, the time control switch 5-5, the power control switch 5-6 and the fan 5-8 are electrically connected with the ultrasonic generator 5-1, and the fan 5-8 is arranged inside the working water tank 2-5; a first lead connecting the time relay 6 with the ultrasonic generator 5-1 and a second lead connecting the time relay 6 with the ultrasonic atomization sheet 5-2 are connected through a third lead, and the third lead is provided with an atomization switch 5-7; diodes are arranged on the time relay 6 and the atomization switches 5-7 to ensure that current can only flow in a single direction, so that short circuit caused by simultaneous connection of the time relay 6 and the atomization switches 5-7 is avoided.

The working process of the automatic disinfectant fluid atomizer of the utility model is as follows:

under the natural state, because the action of gravity, material (salt) in material storage tank 1 falls into the material of ration charging box and shifts the box, has always the material to exist in the material shifts the box. Water is added from a water filling port 2-2 on the liquid storage tank 2, and the button is pressed or rotated, so that the materials in the material transfer box fall into the liquid storage tank 2 through a second discharge port. The button is released, and the material transfer box returns to the initial state under the action of the elastic force to store materials. Or under the action of the gear switch, the next material transfer box cavity rotates to store the prepared materials below the first feeding hole. When the button is pressed or rotated, the delay switch 4 and the time relay 6 are also triggered, the delay switch 4 starts the electrode group to work, and the salt is electrolyzed in the liquid storage tank 2 to generate the sterilized water. The time relay 6 also starts to work, the ultrasonic atomization is automatically started after the set time (the time required for completing the electrolysis), the time control switch 5-5 and the power control switch 5-6 are adjusted, and the atomizer is automatically closed after the atomization time is reached.

The atomized disinfectant fluid can be used for sterilizing and removing formaldehyde in public places and indoors.

In addition, clear water is added into the water filling port 2-2, the switch 5-7 is closed, the time control switch 5-5 and the power control switch 5-6 are adjusted, the atomizer is automatically closed after the atomization time is reached, and the aim of humidifying air by conventional atomized water can be achieved.

In addition, the knob is pressed or rotated to start the delay switch 4, the delay switch 4 starts the electrode group to work, and the salt is electrolyzed in the liquid storage tank 2 to generate the sterilized water. The bottom is provided with a liquid outlet 2-3 for discharging the disinfectant liquid, and the disinfectant liquid can be used for daily disinfection, washing of vegetables and fruits and the like.

Example 2

The quantitative feeding box B shown in FIG. 3 comprises a shell B-1 and a second material transfer box B-2 in the shell B-1, wherein a first feeding hole B-3 and a second discharging hole B-4 which are arranged on the shell B-1 are arranged oppositely up and down;

the main body of the second material transfer box B-2 is a cylinder body with two open ends, the cylinder body is fixedly arranged in a shell B-1, the top and the bottom of the cylinder body are correspondingly provided with a top plate B-6 and a bottom plate B-7, through holes B-8 are respectively arranged on the top plate B-6 and the bottom plate B-7, the upper part of the left side wall of the shell B-1 is provided with a delay switch 4 with the same height as the top plate B-6, an upper spring B-9 is arranged between the delay switch 4 and the top plate B-6, two ends of the upper spring B-9 are respectively and fixedly connected with the delay switch 4 and the top plate B-6, a lower spring B-10 is arranged between the bottom plate B-7 and the left side wall of the shell B-1, one end of the lower spring B-10 is fixed on the shell B-1, the other end is fixed on the bottom plate B-7;

a torsion bar B-11 is arranged between the top plate B-6 and the bottom plate B-7, two ends of the torsion bar B-11 are respectively and fixedly connected with the right end of the top plate B-6 and the right end of the bottom plate B-7, a button B-12 is fixedly arranged at the joint of the torsion bar B-11 and the top plate B-6, and the right end of the button B-12 penetrates through the shell B-1 and is exposed out of the shell B-1; when the button B-12 is not pressed, the through hole B-8 on the top plate B-6 is opposite to the first feed port B-3, and the through hole B-8 on the bottom plate B-7 is positioned at the left outer side of the cylinder body so that the cylinder body cannot be communicated with the second discharge port B-4;

when the button B-12 is pressed, the top plate B-6 moves leftwards, the through hole B-8 on the top plate B-6 moves leftwards, and meanwhile, the torsion bar B-11 drives the bottom plate B-7 to move rightwards, the through hole B-8 on the bottom plate B-7 is opposite to the second discharge hole B-4, so that the interior of the cylinder is communicated with the second discharge hole B-4.

Example 3

The quantitative feeding box C shown in the figures 4 and 5 comprises a shell C-1 and a third material transfer box C-2 in the shell C-1, wherein a first feeding hole C-3 and a second discharging hole C-4 which are arranged on the shell C-1 are oppositely arranged up and down, a sealing flat plate C-5 is arranged at the bottom of the first feeding hole C-3, the left end of the sealing flat plate C-5 is hinged on the first feeding hole C-3, the right end of the sealing flat plate C-5 is not fixed, and a delay switch 4 is arranged on the left side wall of the shell C-1;

the third material transfer box C-2 comprises a cylindrical outer box A C-6 and a first inner box C-7, the outer box A C-6 is fixed in the shell C-1, the first inner box C-7 is nested in the outer box A C-6, the top and the bottom of the outer box A C-6 are respectively provided with a first opening C-8 and are respectively fixedly connected and communicated with a first feed inlet C-3 and a second discharge outlet C-4, a first rotating shaft C-9 is arranged in the shell C-1, one end of the first rotating shaft C-9 is connected with the shell C-1, the other end of the first rotating shaft C-9 penetrates through the third material transfer box C-2 and penetrates out of the shell C-1 to be fixedly connected with a knob A C-10, a torsion spring C-11 is sleeved on the first rotating shaft C-9, the two torque arms of the torsion spring C-11 are fixedly connected with the top and the bottom of the shell C-1 respectively, a first rotating shaft C-9 is vertically provided with a trigger rod A C-12, the position of the trigger rod A C-12 on the first rotating shaft C-9 corresponds to the position of the delay switch 4, the first rotating shaft C-9 drives the first inner box C-7 and the trigger rod A C-12 to rotate when the knob A C-10 is rotated, and the trigger rod A C-12 triggers the delay switch 4 after the knob A is rotated by C-10180 degrees;

the first inner box C-7 is provided with a first material inlet and outlet C-13, the first material inlet and outlet C-13 is opposite to the first feed inlet C-3 before the knob A C-10 is rotated, and the first material inlet and outlet C-13 is opposite to the second feed outlet C-4 after the knob A C-10180 degrees is rotated.

Example 4

The quantitative feeding box D shown in the figures 6 and 7 comprises a shell D-1 and a fourth material transfer box D-2 in the shell D-1, wherein a first feeding hole D-3 and a second discharging hole D-4 which are arranged on the shell D-1 are oppositely arranged up and down, a sealing flat plate B-5 is arranged at the bottom of the first feeding hole D-3, the left end of the sealing flat plate B-5 is hinged on the first feeding hole D-3, the right end of the sealing flat plate B-5 is not fixed, and a delay switch 4 is arranged on the left side wall of the shell D-1;

the fourth material transfer box D-2 comprises a cylindrical outer box B D-6 and a second inner box D-7, the outer box B D-6 is fixed in the outer shell D-1, the second inner box D-7 is nested in the outer box B D-6, the top and the bottom of the outer box B D-6 are respectively provided with a second opening D-8 and are respectively fixedly connected and communicated with the first material inlet D-3 and the second material outlet D-4, a second rotating shaft D-9 is arranged in the outer shell D-1, one end of the second rotating shaft D-9 is connected with the outer shell D-1, and the other end of the second rotating shaft D-9 penetrates through the fourth material transfer box D-2 and penetrates out of the outer shell D-1 to be fixedly connected with the knob B D-10;

the interior of the second inner box D-7 is divided into an upper cavity and a lower cavity by a partition board, the upper cavity and the lower cavity are both provided with a second material inlet and outlet D-11, a first gear rotary switch D-12 is arranged on a second rotary shaft D-9, two trigger rods B-13 are vertically arranged on the second rotary shaft D-9, the two trigger rods B-13 respectively correspond to the upper cavity and the lower cavity, the position of the trigger rod B-13 on the second rotary shaft D-9 corresponds to the position of the delay switch 4, when the knob B-10 is rotated, the second rotary shaft D-9 drives the second inner box D-7 and the trigger rod B-13 to rotate, and the trigger rod B-13 triggers the delay switch 4; in a natural state, a second material inlet and outlet D-11 on the upper cavity body is over against the first material inlet D-3, and a second material inlet and outlet D-11 on the lower cavity body is over against the second material outlet D-4.

Example 5

The quantitative feeding box E shown in the figures 8 and 9 comprises a shell E-1 and a fifth material transfer box E-2 fixed in the shell E-1, wherein a first feeding hole E-3 and a second discharging hole E-4 which are arranged on the shell E-1 are oppositely arranged up and down, a sealing flat plate C-5 is arranged at the bottom of the first feeding hole E-3, the left end of the sealing flat plate C-5 is hinged to the first feeding hole E-3, the right end of the sealing flat plate C-5 is not fixed, and a delay switch 4 is arranged on the left side wall of the shell E-1;

the fifth material transfer box E-2 is cylindrical and is horizontally arranged in the shell E-1, the top and the bottom of the fifth material transfer box E-2 are respectively provided with a third opening E-6 which is fixedly connected and communicated with the first feed port E-3 and the second discharge port E-4, a third rotating shaft E-7 is arranged in the shell E-1, one end of the third rotating shaft E-7 is connected with the shell E-1, the other end of the third rotating shaft E-7 penetrates through the fifth material transfer box E-2 and penetrates out of the shell E-1 to be fixedly connected with the knob E-8, and a second gear rotary switch E-9 is arranged on the third rotating shaft E-7;

a plurality of fan-shaped partition plates E-10 are fixedly connected to the third rotating shaft E-7, a gap is reserved between the tail ends of the fan-shaped partition plates E-10 and the inner wall of the fifth material transfer box E-2, so that the fan-shaped partition plates E-10 rotate along with the rotation of the third rotating shaft E-7, the interior of the fifth material transfer box E-2 is uniformly divided into a plurality of fan-shaped cavities by the fan-shaped partition plates E-10, a plurality of trigger rods E-11 are fixedly connected to the third rotating shaft E-7, one trigger rod E-11 corresponds to one fan-shaped cavity, the position of the trigger rod E-11 on the third rotating shaft E-7 corresponds to the position of the delay switch 4, and the third rotating shaft E-7 drives the trigger rod E-11 to rotate when the knob C-8 is rotated, the trigger lever C E-11 triggers the time delay switch 4.

Claims (10)

1. An automatic generator of sterilized water, characterized in that: the quantitative feeding device comprises a material storage tank (1), a quantitative feeding box and a liquid storage tank (2) which are sequentially arranged from top to bottom, wherein a first discharge hole (1-1) is formed in the bottom of the material storage tank (1), a first feed hole is formed in the top of the quantitative feeding box, a second discharge hole is formed in the bottom of the quantitative feeding box, a second feed hole (2-1) is formed in the top of the liquid storage tank (2), the first discharge hole (1-1) and the first feed hole can be fixedly connected to connect the material storage tank (1) and the quantitative feeding box, and the second discharge hole and the second feed hole (2-1) can be fixedly connected to connect the quantitative feeding box and the liquid storage tank (2);

an electrode group (3) is arranged in the liquid storage tank (2), a delay switch (4) is arranged in the quantitative feeding box, the delay switch (4) is electrically connected with the electrode group (3) and can be connected with an external power supply through an electric wire so as to electrolyze liquid in the liquid storage tank (2).

2. An automatic generator of sterilized water as set forth in claim 1, wherein: the quantitative feeding box is a quantitative feeding box A, the quantitative feeding box A comprises a shell A (A-1) and a columnar first material transfer box (A-2) in the shell A (A-1), a first feeding port A (A-3) and a second discharging port A (A-4) which are arranged on the shell A (A-1) are arranged in a vertically staggered manner, the first feeding port A (A-3) is close to the right end of the shell A (A-1), the second discharging port A (A-4) is close to the left end of the shell A (A-1), a delay switch (4) is arranged on the left side wall of the shell A (A-1), the top of the first material transfer box (A-2) is opened, the bottom of the first material transfer box (A-2) is provided with a movable bottom plate (A-5), the right end of the movable bottom plate (A-5) is hinged to the first material transfer box (A-2), The left end of the first material transferring box (A-2) is not fixed, a spring (A-6) is arranged between the first material transferring box (A-2) and the delay switch (4), two ends of the spring (A-6) are fixedly connected with the first material transferring box (A-2) and the delay switch (4) respectively, a button A (A-7) is fixedly arranged on the right outer side of the first material transferring box (A-2), and the right end of the button A (A-7) penetrates through the shell A (A-1) and is exposed out of the shell A (A-1); the right top of the first material transfer box (A-2) is provided with a flanging (A-9) extending outwards; when the button A (A-7) is not pressed, the first inlet A (A-3) of the quantitative charging box is opposite to and communicated with the top of the first material transfer box (A-2).

3. An automatic generator of sterilized water as set forth in claim 1, wherein: the quantitative feeding box is a quantitative feeding box B, the quantitative feeding box B comprises a shell B (B-1) and a second material transfer box (B-2) in the shell B (B-1), and a first feeding hole B (B-3) and a second discharging hole B (B-4) which are arranged on the shell B (B-1) are arranged in a manner of being opposite to each other up and down;

the main body of the second material transfer box (B-2) is a cylinder body with two open ends, the cylinder body is fixedly arranged in a shell B (B-1), the top and the bottom of the cylinder body are correspondingly provided with a top plate (B-6) and a bottom plate (B-7), through holes (B-8) are respectively arranged on the top plate (B-6) and the bottom plate (B-7), the upper part of the left side wall of the shell B (B-1) is provided with a delay switch (4) which is at the same height with the top plate (B-6), an upper spring (B-9) is arranged between the delay switch (4) and the top plate (B-6), two ends of the upper spring (B-9) are respectively and fixedly connected with the delay switch (4) and the top plate (B-6), a lower spring (B-10) is arranged between the bottom plate (B-7) and the left side wall of the shell B-1), one end of the lower spring (B-10) is fixed on the shell B (B-1), and the other end is fixed on the bottom plate (B-7);

a torsion bar (B-11) is arranged between the top plate (B-6) and the bottom plate (B-7), two ends of the torsion bar (B-11) are respectively and fixedly connected with the right end of the top plate (B-6) and the right end of the bottom plate (B-7), a button B (B-12) is fixedly arranged at the joint of the torsion bar (B-11) and the top plate (B-6), and the right end of the button B (B-12) penetrates out of the shell B (B-1) and is exposed out of the shell B (B-1); when the button B (B-12) is not pressed, the through hole (B-8) on the top plate (B-6) is opposite to the first feed port B (B-3), and the through hole (B-8) on the bottom plate (B-7) is positioned at the left outer side of the cylinder body so that the cylinder body cannot be communicated with the second discharge port B (B-4);

when the button B (B-12) is pressed, the top plate (B-6) moves leftwards, the through hole (B-8) on the top plate (B-6) moves leftwards, meanwhile, the torsion bar (B-11) drives the bottom plate (B-7) to move rightwards, the through hole (B-8) on the bottom plate (B-7) is opposite to the second discharge hole B (B-4), and therefore the interior of the cylinder is communicated with the second discharge hole B (B-4).

4. An automatic generator of sterilized water as set forth in claim 1, wherein: the quantitative feeding box is a quantitative feeding box C, the quantitative feeding box C comprises a shell C (C-1) and a third material transfer box (C-2) in the shell C (C-1), a first feeding hole C (C-3) and a second discharging hole C (C-4) which are arranged on the shell C (C-1) are oppositely arranged up and down, a sealing flat plate A (C-5) is arranged at the bottom of the first feeding hole C (C-3), the left end of the sealing flat plate A (C-5) is hinged to the first feeding hole C (C-3), the right end of the sealing flat plate A is not fixed, and a delay switch (4) is arranged on the left side wall of the shell C (C-1);

the third material transfer box (C-2) comprises a cylindrical outer box A (C-6) and a first inner box (C-7), the outer box A (C-6) is fixed in the shell C-1, the first inner box (C-7) is nested in the outer box A (C-6), the top and the bottom of the outer box A (C-6) are respectively provided with a first opening (C-8) and are respectively fixedly connected and communicated with a first feed inlet C (C-3) and a second discharge outlet C (C-4), the shell C-1 is internally provided with a first rotating shaft (C-9), one end of the first rotating shaft (C-9) is connected with the shell C-1, the other end of the first rotating shaft penetrates through the third material transfer box (C-2) and penetrates out of the shell C-1) to be fixedly connected with a knob A (C-10), a torsion spring (C-11) is sleeved on the first rotating shaft (C-9), two torsion arms of the torsion spring (C-11) are fixedly connected with the top and the bottom of the shell C-1 respectively, a trigger lever A (C-12) is vertically arranged on the first rotating shaft (C-9), the position of the trigger lever A (C-12) on the first rotating shaft (C-9) corresponds to the position of the delay switch (4), the first rotating shaft (C-9) drives the first inner box (C-7) and the trigger lever A (C-12) to rotate when the knob A (C-10) is rotated, and the trigger lever A (C-12) triggers the delay switch (4) after the knob A (C-10) is rotated by 180 degrees;

a first material inlet and outlet (C-13) is formed in the first inner box (C-7), the first material inlet and outlet (C-13) is opposite to the first feeding hole C (C-3) before the knob A (C-10) is rotated, and after the knob A (C-10) is rotated by 180 degrees, the first material inlet and outlet (C-13) is opposite to the second discharging hole C (C-4).

5. An automatic generator of sterilized water as set forth in claim 1, wherein: the quantitative feeding box is a quantitative feeding box D, the quantitative feeding box D comprises a shell D (D-1) and a fourth material transfer box (D-2) in the shell D (D-1), a first feeding hole D (D-3) and a second discharging hole D (D-4) which are arranged on the shell D (D-1) are oppositely arranged up and down, a sealing flat plate B (D-5) is arranged at the bottom of the first feeding hole D (D-3), the left end of the sealing flat plate B (D-5) is hinged to the first feeding hole D (D-3), the right end of the sealing flat plate B (D-5) is not fixed, and a delay switch (4) is arranged on the left side wall of the shell D (D-1);

the fourth material transfer box (D-2) comprises a cylindrical outer box B (D-6) and a second inner box (D-7), the outer box B (D-6) is fixed in the outer shell D (D-1), the second inner box (D-7) is nested in the outer box B (D-6), the top and the bottom of the outer box B (D-6) are both provided with second openings (D-8) which are respectively fixedly connected and communicated with the first feed inlet D-3 and the second discharge outlet D-4, a second rotating shaft (D-9) is arranged in the outer shell D-1, one end of the second rotating shaft (D-9) is connected with the shell (D-1), and the other end of the second rotating shaft passes through the fourth material transfer box (D-2) and penetrates out of the shell (D-1) to be fixedly connected with the knob B (D-10);

the interior of the second inner box (D-7) is divided into an upper cavity and a lower cavity by a partition plate, the upper cavity and the lower cavity are both provided with a second material inlet and outlet (D-11), a first gear rotary switch (D-12) is arranged on a second rotary shaft (D-9), two trigger rods B (D-13) are vertically arranged on the second rotary shaft (D-9), the two trigger rods B (D-13) correspond to the upper cavity and the lower cavity respectively, the position of the trigger rod B (D-13) on a second rotating shaft (D-9) corresponds to the position of the delay switch (4), the second rotating shaft (D-9) drives a second inner box (D-7) and the trigger rod B (D-13) to rotate when the knob B (D-10) is rotated, and the trigger rod B (D-13) triggers the delay switch (4); in a natural state, a second material inlet and outlet (D-11) on the upper cavity body is over against the first material inlet D (D-3), and a second material inlet and outlet (D-11) on the lower cavity body is over against the second material outlet D (D-4).

6. An automatic generator of sterilized water as set forth in claim 1, wherein: the quantitative feeding box is a quantitative feeding box E, the quantitative feeding box E comprises an outer shell penta (E-1) and a fifth material transfer box (E-2) fixed in the outer shell penta (E-1), a first feeding hole penta (E-3) and a second discharging hole penta (E-4) which are arranged on the outer shell penta (E-1) are arranged in an up-and-down opposite mode, a sealing flat plate C (E-5) is arranged at the bottom of the first feeding hole penta (E-3), the left end of the sealing flat plate C (E-5) is hinged to the first feeding hole penta (E-3), the right end of the sealing flat plate C is not fixed, and a delay switch (4) is arranged on the left side wall of the outer shell penta (E-1);

the fifth material transfer box (E-2) is cylindrical and is horizontally arranged in the shell penta (E-1), the top and the bottom of the fifth material transfer box (E-2) are respectively provided with a third opening (E-6) and are respectively fixedly connected and communicated with the first feed inlet penta (E-3) and the second discharge outlet penta (E-4), a third rotating shaft (E-7) is arranged in the shell penta (E-1), one end of the third rotating shaft (E-7) is connected with the shell penta (E-1), the other end of the third rotating shaft (E-7) penetrates through the fifth material transfer box (E-2) and penetrates through the shell penta (E-1) to be fixedly connected with the knob penta (E-8), and a second gear position rotary switch (E-9) is arranged on the third rotating shaft (E-7);

a plurality of fan-shaped partition plates (E-10) are fixedly connected to a third rotating shaft (E-7), a gap is reserved between the tail end of each fan-shaped partition plate (E-10) and the inner wall of a fifth material transfer box (E-2), the fan-shaped partition plates (E-10) rotate along with the rotation of the third rotating shaft (E-7), the fan-shaped partition plates (E-10) divide the interior of the fifth material transfer box (E-2) into a plurality of fan-shaped cavities, a plurality of trigger lever jacks (E-11) are fixedly connected to the third rotating shaft (E-7), one trigger lever jack (E-11) corresponds to one fan-shaped cavity, the position of each trigger lever jack (E-11) on the third rotating shaft (E-7) corresponds to the position of the delay switch (4), and the third rotating shaft (E-7) drives the trigger lever jack (E-11) to rotate when the knob jack (E-8) is rotated And the trigger lever C (E-11) triggers the delay switch (4).

7. An automatic generator of sterilized water as claimed in any one of claims 1 to 6, wherein: a water filling port (2-2) is arranged on the liquid storage tank (2), and a liquid outlet (2-3) is arranged at the bottom of the liquid storage tank; the liquid storage tank (2) comprises a water storage tank (2-4) and a working water tank (2-5), the water storage tank (2-4) is detachably arranged at the top of the working water tank (2-5), an inner cylinder (2-6) is arranged in the water storage tank (2-4), the top of the inner cylinder (2-6) is open and is just opposite to the second feed inlet (2-1) at the top of the liquid storage tank (2), a cavity formed by the cylinder wall of the inner cylinder (2-6) and the outer wall of the water storage tank (2-4) is used for storing water, the bottom of the inner cylinder (2-6) is also open, so that materials entering from the second feed inlet (2-1) directly fall into the working water tank (2-5), a bottom plate of the water storage tank (2-4) is provided with a float valve (2-7) for feeding water into the working water tank (2-5).

8. An automatic atomizer of disinfectant fluid, its characterized in that: the automatic generator of sterilized water comprising any one of claims 1 to 7, further comprising an ultrasonic atomization unit (5), wherein the ultrasonic atomization unit (5) comprises an ultrasonic generator (5-1) and an ultrasonic atomization sheet (5-2) which are connected through an electric wire, the ultrasonic atomization sheet (5-2) is arranged in the liquid storage tank (2) to atomize the liquid in the liquid storage tank (2), and the ultrasonic generator (5-1) is arranged outside the liquid storage tank (2); the upper part of the liquid storage tank (2) is provided with a mist outlet (2-8).

9. The automatic atomizer for sterilized water of claim 8, wherein: when the automatic generator of the sterilized water is the automatic generator of the sterilized water according to claim 2 or 3, a time relay (6) adjacent to the delay switch (4) is further arranged on the inner surface of the left side wall of the quantitative charging box, the time relay (6) and the delay switch (4) are both fixedly connected with a spring, and the actions of the time relay (6) and the delay switch (4) are realized through the compression of the spring; the time relay (6) is respectively connected with the ultrasonic generator (5-1) and the ultrasonic atomization sheet (5-2) through electric wires;

when the automatic generator for sterilized water is the automatic generator for sterilized water according to claim 4, 5 or 6, the rotating knob drives the trigger rod to rotate through the gear rotating switch, the trigger rod touches the time relay (6) and the delay switch (4), and the time relay (6) is electrically connected with the ultrasonic atomization unit (5).

10. The automatic atomizer for sterilized water of claim 9, wherein: the ultrasonic atomization unit (5) further comprises an external power supply (5-3), a liquid level control switch (5-4), a time control switch (5-5), a power control switch (5-6) and a fan (5-8), the liquid level control switch (5-4) is electrically connected with a liquid level sensor arranged in the liquid storage tank (2), the time control switch (5-5), the power control switch (5-6) and the fan (5-8) are electrically connected with the ultrasonic generator (5-1), and the fan (5-8) is installed inside the working water tank (2-5); a first lead for connecting the time relay (6) with the ultrasonic generator (5-1) and a second lead for connecting the time relay (6) with the ultrasonic atomization sheet (5-2) are connected through a third lead, and the third lead is provided with an atomization switch (5-7);

diodes are arranged on the time relay (6) and the atomization switches (5-7) to ensure that current can only flow in a single direction, so that short circuit caused by simultaneous connection of the time relay (6) and the atomization switches (5-7) is avoided.

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