KR20240056100A - Smart fountain - Google Patents

Abstract

The present invention relates to a smart fountain (1). Such a smart fountain (1) includes a water tank (7) disposed inside the base (3) to store water; Cold and hot water units (11, 13) connected to the water tank (7) and supplying cold and hot water; A sterilization lamp (L) placed in the water tank (7) to perform sterilization and including an ultraviolet lamp (UV) or an AOP lamp (Advanced Oxidation Process Lamp); A filter (9) disposed on one side of the water tank (7); A front plate (5) arranged upright on the upper part of the base (3); a spray unit (6) disposed on the upper part of the front plate (5) to spray water; a pumping unit 15 that pumps water from the water tank 7 to the spraying unit 6 through a pipe; A sensor unit 16 disposed in the water tank 7 and the cold and hot water units 11 and 13; And it includes a control unit 18 that monitors and controls the smart fountain 1 in real time by signals transmitted from the sensor unit 16.

Description

Smart fountain

The present invention relates to a smart fountain, and more specifically, to a smart fountain that is easy to manage by removing foreign substances, bacteria, and viruses from water, managing the water temperature by using cold and hot water, and monitoring the real-time status of the fountain.

In general, many fountains are installed in public places for aesthetic purposes, and these fountains come in various types.

Typically, a fountain has a storage tank that stores water at the bottom, a front plate is installed on top of the storage tank, a spray nozzle is placed on the top of the front plate, and this spray nozzle is connected to the storage tank.

Therefore, the water stored in the storage tank is pumped upward by the pump, and the pumped water is sprayed downward through the spray nozzle and falls on the front plate.

However, since conventional fountains use water from a storage tank for a long period of time, foreign substances, bacteria, viruses, etc. grow in the water after a certain period of time, which poses a hygiene problem.

In addition, there is a problem that management is difficult because it is difficult to determine the situation of the fountain in real time from a remote location.

Patent Application No. 10-2007-88815 (Name: Indoor Decorative Fountain)

Therefore, the present invention was proposed to solve the above problems, and the purpose of the present invention is to remove foreign substances, bacteria, and viruses from water, manage the water temperature by using cold and hot water, and monitor the real-time situation of the fountain to facilitate management. The goal is to provide a smart fountain.

In order to achieve the above object, an embodiment of the present invention provides a smart fountain, and this smart fountain (1) includes,

A water tank (7) disposed inside the base (3) to store water;

Cold and hot water units (11, 13) connected to the water tank (7) and supplying cold and hot water;

A sterilization lamp (L) placed in the water tank (7) to perform sterilization and including an ultraviolet lamp (UV) or an AOP lamp (Advanced Oxidation Process Lamp);

A filter (9) disposed on one side of the water tank (7);

A front plate (5) arranged upright on the upper part of the base (3);

a spray unit (6) disposed on the upper part of the front plate (5) to spray water;

a pumping unit 15 that pumps water from the water tank 7 to the spraying unit 6 through a pipe;

A sensor unit 16 disposed in the water tank 7 and the cold and hot water units 11 and 13; and

It includes a control unit 18 that monitors and controls the smart fountain 1 in real time by signals transmitted from the sensor unit 16.

The smart fountain according to the above-described embodiment of the present invention removes foreign substances, bacteria, and viruses from the water, manages the water temperature by using cold and hot water, and monitors the real-time status of the fountain, making it easy to manage.

Figure 1 is a perspective view showing the appearance of a smart fountain according to an embodiment of the present invention.
Figure 2 is a front view of Figure 1.
FIG. 3 is a block diagram schematically showing the structure of the control unit shown in FIG. 1.

Hereinafter, a smart fountain according to an embodiment of the present invention will be described in detail with reference to the attached drawings.

As shown in FIGS. 1 to 3, the smart fountain 1 proposed by the present invention includes a base 3; A water tank (7) disposed inside the base (3) to store water; Cold and hot water units (11, 13) connected to the water tank (7) and supplying cold and hot water; A sterilizing lamp (L) placed in the water tank (7); A filter (9) disposed on one side of the water tank (7); A front plate (5) arranged upright on the upper part of the base (3); a spray unit (6) disposed on the upper part of the front plate (5) to spray water; a pumping portion (15) that pumps water from the water tank (7) into the pipe; A sensor portion (16) disposed in the water tank (7) and the hot and cold water portions (11, 13); It includes a control unit 18 that monitors and controls the smart fountain 1 in real time by signals transmitted from the sensor unit 16.

In the smart fountain (1) having this structure,

A water tank 7 is placed inside the base 3 to store a certain volume of water.

In addition, cold and hot water can be supplied and stored in the water tank 7 by connecting the cold and hot water units 11 and 13.

The cold and hot water parts (11, 13) can be connected to the water tank (7) in various forms, for example, they have a cold water pipe (t1) and a hot water pipe (t2) connected to the outside, and the cold water pipe (t1) and a structure that connects the hot water pipe (t2) to the water tank (7). In this case, cold water and hot water are supplied to the water tank 7 as needed by mounting on-off valves on the cold water pipe (t1) and the hot water pipe (t2), respectively.

Alternatively, a cooling and heating system is mounted on one side of the water tank 7. At this time, the heating system can be a heating coil, a thermoelectric semiconductor, etc., and the cooling system can be a cooler. Therefore, this is a method of supplying cold water and hot water to the water tank 7 by appropriately controlling the cooling and heating systems.

In this way, the cold and hot water supplied from the cold and hot water units 11 and 13 is stored in the water tank 7, and sterilization can be performed by the sterilization lamp L.

At this time, the sterilizing lamp (L) may include various types of lamps, for example, an ultraviolet lamp (UV) or an Advanced Oxidation Process Lamp (AOP lamp) may be applied.

These sterilizing lamps (L) are placed in an appropriate number on the floor or side walls inside the water tank (7). Therefore, sterilization can be carried out by irradiating ultraviolet rays from the sterilization lamp (L) to the water stored in the water tank (7).

Then, the sterilized water passes through the filter 9 and is discharged into the pipe.

At this time, the filter 9 removes foreign substances contained in the water and is provided in multiple layers.

For example, the filter 9 is composed of primary and secondary filters 23 and 25, and the primary filter 23 is a natural filter made of gravel and filter paper. And, the secondary filter 25 is a ceramic filter.

Accordingly, the water discharged from the water tank 7 can be supplied to the pipe with foreign substances removed by passing through the filter 9.

Of course, the filter 9 is not limited to the above structure, and may be changed in various ways depending on the environment.

Then, the water discharged from the water tank 7 flows into the pumping unit 15 and is pumped, thereby being supplied to the spraying unit 6 through the pipe.

The pumping unit 15 includes a device capable of pumping water, for example, a pump, a motor, etc.

Accordingly, the water pumped to the upper layer by the pumping unit 15 is supplied to the spray unit 6 through the pipe.

This injection unit (6) includes a main pipe (17) connected to the pipe; A plurality of injection pipes (19) that protrude on both sides of the main unit and spray water downward; It includes a spray nozzle 21 that is disposed at the bottom of the spray pipe 19 and sprays water.

At this time, the injection direction of the plurality of injection pipes 19 is inclined inward, that is, toward the front plate 5.

Accordingly, the water sprayed through the plurality of spray pipes 19 is sprayed onto the surface of the front plate 5 through the spray nozzle 21 and falls downward.

In addition, the front plate 5 functions to guide falling water to the lower water tank 7, and can be formed of various materials. For example, transparent or translucent plastic, artificial marble, etc.

In this way, a humidifying effect can be obtained in the surrounding area as water falling from the upper side flows down through the front panel 5.

Additionally, light can be emitted from the front panel 5 by installing an illumination lamp on the front panel 5 as needed. Therefore, when bugs gather around this light, these bugs fall into the lower tank (7) due to the flow of water and are filtered by the filter (9), where they can be effectively removed.

Meanwhile, the sensor unit 16 is disposed in the smart fountain 1, so that the situation of the fountain 1 can be detected in real time and transmitted to the control unit 18.

In more detail, the sensor unit 16 includes a temperature sensor (S1) disposed in the water tank (7) to detect the temperature of the water; a negative ion sensor (S3) disposed in the water tank (7) to measure negative ions in water; A fine dust sensor (S2); A humidity sensor (S4) that measures the humidity of the smart fountain (1); CO2 sensor (S5); Includes water level sensor (S6).

In the sensor unit 16 having this structure,

The temperature sensor (S1) includes a contact temperature sensor and a non-contact temperature sensor. The contact temperature sensor includes a thermocouple, thermistor, and resistance temperature detectors (RTD), and the non-contact temperature sensor includes a thermocouple, a thermistor, and a resistance temperature detector (RTD). Including infrared thermometers, etc.

The negative ion sensor (S3) includes various types of sensors, for example, boron-based chemical sensors and semiconductor-type sensors are applicable.

The fine dust sensor (S2) can be used in light scattering, beta ray absorption, or weight measurement methods.

The humidity sensor (S4) includes an electric humidity sensor, a wet and dry bulb sensor, a resistance change type humidity sensor (S4), and a capacitance change type humidity sensor.

In addition, the CO2 sensor (S5) can be applied to various sensors such as non-dispersive infrared type, solid electrolyte type, and thick film type sensor.

Meanwhile, the control unit 18 includes an input module (M1) that receives a signal transmitted from the sensor unit 16; a calculation module (M2) that operates the smart fountain (1) by calculating the input signal; a communication module (M3) that transmits the result calculated by the calculation module (M2) to a remote location; It includes a display window (M4) where the calculated result value is displayed.

The input module (M1) receives measured values transmitted from the temperature sensor (S1), the negative ion sensor (S3), the fine dust sensor (S2), the humidity sensor (S4), and the CO2 sensor (S5).

And, the calculation module (M2) can operate the smart fountain (1) within the normal range by operating the pump, valve, sterilization lamp, etc. based on these measured values.

That is, the operation module M2 transmits a signal to the pump 15 to drive the pump and supply the water in the water tank 7 to the upper injection unit 6 through the pipe to inject it.

At this time, the amount of water supplied to the spray unit 6 can be appropriately adjusted by controlling the output of the pump 15.

In this way, while water is circulated from the water tank 7 to the spray unit 6 by the pump 15, the temperature of the water tank 7 is measured and cold and hot water is appropriately supplied to the water tank 7.

That is, the temperature sensor (S1) measures the temperature of the water tank (7) and transmits it to the control unit (18), and the calculation module (M2) calculates it to determine if the temperature of the water tank (7) is outside the standard value range, for example. If it is below the standard value, a signal is sent to the hot water valve to open the hot water pipe (t2) to supply hot water to the water tank (7) to raise it to the standard value range.

Conversely, if the value is above the standard value, a signal is sent to the cold water valve to open the cold water pipe (t1) to supply cold water to the water tank (7), thereby lowering the temperature to the standard value range.

In this way, the temperature of the water tank 7 is measured by the temperature sensor S1, and the calculation module M2 reflects this to control the temperature of the water tank 7 within the standard value range, thereby preventing freezing and bursting.

In this way, the control unit 18 receives related signals from the negative ion sensor (S3), fine dust sensor (S2), humidity sensor (S4), and CO ₂ sensor (S5), and the calculation module (M2) receives them. Calculate and determine whether it is within the standard value range.

In other words, it is determined whether the negative ion value of the smart fountain (1) is within the standard value, or whether the fine dust value, humidity value, and CO ₂ value are within the standard value.

In addition, the identified results are transmitted to a remote management office, and the manager can determine the status of the smart fountain (1) in real time based on these results.

Of course, the control unit 18 may stop the operation of the smart fountain 1 when the sensor value determined from the sensor is outside the standard value range.

Additionally, the control unit 18 may sterilize the water tank 7 by transmitting a signal to the sterilization lamp (L). This sterilization operation may be performed in various ways. For example, the water tank 7 may be sterilized by operating the sterilization lamp L at regular intervals.

Or, if the control unit 18 deviates from a certain range based on the measured values transmitted from the negative ion sensor (S3), fine dust sensor (S2), humidity sensor (S4), and CO ₂ sensor (S5), the sterilization lamp ( Sterilization of the water tank 7 can also be performed by operating L).

In addition, each measurement value transmitted by the sensor unit 16 is displayed as a number on the display window M4, so that the current status of the smart fountain 1 can be checked in real time from the outside.

Claims (5)

A water tank (7) disposed inside the base (3) to store water;
Cold and hot water units (11, 13) connected to the water tank (7) and supplying cold and hot water;
A sterilization lamp (L) placed in the water tank (7) to perform sterilization and including an ultraviolet lamp (UV) or an AOP lamp (Advanced Oxidation Process Lamp);
A filter (9) disposed on one side of the water tank (7);
A front plate (5) arranged upright on the upper part of the base (3);
a spray unit (6) disposed on the upper part of the front plate (5) to spray water;
a pumping unit 15 that pumps water from the water tank 7 to the spraying unit 6 through a pipe;
A sensor unit 16 disposed in the water tank 7 and the cold and hot water units 11 and 13; and
A smart fountain (1) including a control unit (18) that monitors and controls the smart fountain (1) in real time by a signal transmitted from the sensor unit (16). According to clause 1,
The cold and hot water units (11, 13) include a cold water pipe (t1) and a hot water pipe (t2) connected to the water tank (7); A smart fountain (1) including an on-off valve that is mounted on the cold water pipe (t1) and the hot water pipe (t2) and opens and closes. According to clause 1,
The injection unit (6) includes a main pipe (17) connected to the pipe; A plurality of injection pipes (19) that protrude on both sides of the main unit and spray water downward; A smart fountain (1) including a spray nozzle (21) disposed at the bottom of the spray pipe (19) and spraying water. According to clause 1,
The sensor unit 16 includes a temperature sensor (S1) disposed in the water tank 7 and detecting the temperature of the water; a negative ion sensor (S3) disposed in the water tank (7) to measure negative ions in water; A fine dust sensor (S2); A humidity sensor (S4) that measures the humidity of the smart fountain (1); CO2 sensor (S5); Smart fountain (1) with water level sensor (S6). According to clause 1,
The control unit 18 includes an input module (M1) that receives a signal transmitted from the sensor unit 16; a calculation module (M2) that operates the smart fountain (1) by calculating the input signal; a communication module (M3) that transmits the result calculated by the calculation module (M2) to a remote location; A smart fountain (1) including a display window (M4) where the calculated results are displayed.