KR20210088184A - System for supplying hot water with remote control function - Google Patents

Abstract

The present invention relates to a hot water supply system which provides a hot water supply apparatus capable of increasing thermal efficiency in comparison to an electricity supply amount, increasing discharge pressure, and lowering the contamination of supplied hot water, and has a monitoring and remote control function for the hot water supply apparatus. Hot water production costs are reduced by increasing thermal efficiency in comparison to an electricity supply amount, and high-temperature operation water can be sent to a long distance by increasing discharge pressure. Therefore, the operation water can be used in large quantities for farming and industries. Also, the hot water supply apparatus lowers the contamination of supplied hot water to drastically reduce the contamination of a water tank and can be effectively used for washing dishes or food. Specifically, a controller (control unit) of the hot water supply apparatus automatically controls the function of a corresponding apparatus (boiler) due to the development of communication technology such as IoT, and is linked to a control system through a communication network such as a wireless network to allow a user to remotely control the apparatus to prepare for unexpected errors through an internet-based control system and provide a real-time monitoring service to improve the stability of the hot water supply apparatus including a boiler.

Description

System for supplying hot water with remote control function

The present invention relates to a hot water supply system, and more particularly, a hot water supply device capable of increasing thermal efficiency compared to electricity input amount, increasing an outlet pressure, and lowering the contamination level of supplied hot water, and hot water having a remote control function for the hot water supply device It is about the supply system.

In general, a hot water supply device including a boiler is a device for boiling water to a certain temperature, including household and industrial uses, and uses the combustion heat generated by burning liquefied fuel such as kerosene or gaseous fuel such as gas as a heat source to produce water. It is made by boiling.

Conventional boilers using oil or gas have very low thermal efficiency due to heat loss through the flue or incomplete combustion, etc., and generate a large amount of gas in the combustion process, thereby causing environmental pollution or generation of fine dust.

On the other hand, an electric boiler using electricity heats hot water by heating cold water flowing in through a water supply pipe through an electric heater, and it is divided into a hot water storage type boiler and a hot water supply type boiler according to a method of heating the hot water.

The hot water storage type electric boiler heats low-temperature water stored in a large heating heating tank through a water supply pipe to a high temperature through an electric heater installed in the water storage tank, and discharges it to a drain pipe. At this time, the water stored in the heating and heating tank is gradually heated by the electric heater, and is heated as a whole while circulating in the heating and heating tank by the temperature difference. That is, the water stored in the heating heating tank is heated as a whole as time elapses.

However, since the electric heater cannot heat the entire heating and heating tank in a short time, it takes a lot of time to heat the water stored in the heating and heating tank, and the size of the heating and heating tank places restrictions on the installation site. There is a problem with receiving.

In addition, the heater is easily corroded by heat, so the efficiency is significantly reduced, frequent repair is required due to corrosion of the heater, and the thermal efficiency is significantly lowered compared to the amount of electricity introduced.

The hot water boiler is instantaneously heated by a large-capacity electric heater to convert cold water into hot water quickly and because a separate hot water tank is not used, it is compact and can be used in a wall-mounted form, so it can be used for heating small rooms or for instant water heater It is used a lot.

However, in the conventional hot water supply type electric boiler, if the electric heater is momentarily overloaded and the generated heat is not sufficiently transferred to the working water, frequent failure of the boiler may occur. There is a problem in that the economic burden increases.

In addition, when the heated working water flows out of the high-temperature generator, the outflow pressure is low, so it is not easy to send the high-temperature working water to a long distance, so it is difficult to use it in large-capacity for agricultural and industrial purposes.

In addition, since hot water in electric boilers or boilers using oil or gas is used in the existing water tank, there is a problem in washing dishes and food due to the contamination state of the water tank or the state of water contamination. There is a problem that needs to be managed.

Laid-Open Patent Publication No. 10-2010-0021255 (2010.02.24.)

The present invention is to solve the above-mentioned conventional problems, the object of which is to provide a hot water supply device that can increase the thermal efficiency compared to the amount of electricity input, increase the outlet pressure, and also lower the pollution degree of the supplied hot water, To provide a hot water supply system having a monitoring and remote control function.

In order to achieve the above object, a hot water supply system having a remote control function according to an aspect of the present invention includes an inlet pipe in a first direction; a vortex generator installed in the inlet pipe to apply vibration to room temperature water introduced through the inlet of the inlet pipe and generate a vortex; a plurality of flow pipes connected to the outlet of the inlet pipe and installed parallel to each other in a second direction perpendicular to the first direction; a connecting pipe sequentially connecting the plurality of neighboring flow pipes, but alternately connecting the upper part and the lower part; a heating element helically installed in each flow pipe in the second direction to spirally guide a flow path of water flowing in through the inlet of the flow pipe and flowing out through the outlet; an outlet pipe in a first direction connected to the rear ends of the plurality of flow pipes; a hot water supply tank installed at the outlet of the outlet pipe; a water purifying device for generating ions and dissolving the generated ions under pressure to inject them into room temperature water introduced through the inlet of the inlet pipe; A temperature sensor for detecting the temperature of the hot water in the hot water supply tank and the temperature of the heating element, a pollution sensor for detecting the degree of contamination of the hot water, and a water pressure sensor for detecting the water pressure of the hot water discharged from the hot water supply tank a sensor unit; and the degree of heat generation of the heating element based on the sensed temperature information, contamination degree information, and water pressure information, the type of ions generated in the water purification device, the amount and input amount of ions, and the degree of vibration and vortex generation of the vortex generator Hot water supply device including a control unit for controlling; a display device for visually or audibly displaying status information including at least one of a temperature abnormality state for hot water, a water pollution state presence or absence state, and a water pressure abnormality state according to the control of the controller; and transmitting at least one or more of information detected through the sensor unit and information displayed through the display device to a remote management server or manager terminal under the control of the controller, and remote control from the management server or the manager terminal It may include; a remote communication module for receiving command information, the control unit may control the hot water supply device according to the remote control command.

The heating element is a spiral heating member formed of a rod-shaped heating member located in the center of the flow tube along the longitudinal direction of the flow tube, and spiral blades having a spiral surface maintaining a predetermined angle with the longitudinal direction of the flow tube around the supporter. And, it may be formed to include a plurality of projections formed protruding on the surface of the spiral blade.

The heating element may be formed to include a spiral heating member having a spiral surface of a predetermined width maintaining a predetermined angle with the longitudinal direction of the flow tube.

It may further include a circulation pipe for circulating the hot water discharged from the hot water supply tank in a predetermined path and then returning it to the inlet pipe.

The water purifier may inject ions dissolved under pressure into the hot water flowing into the inlet pipe through the circulation pipe.

As described above, according to various aspects of the present invention, it is possible to reduce the cost of hot water production by increasing the thermal efficiency compared to the amount of electricity input, and to send high-temperature working water to a long distance by increasing the outlet pressure, so that it can be used in a large capacity for agriculture, industry, etc. , also provides a hot water supply device that can be usefully used for washing dishes, food, etc. while dramatically reducing the contamination level of the water tank by reducing the contamination level of the supplied hot water. In particular, with the development of communication technology such as IoT, the controller of the hot water supply device (control unit) automatically controls the function of the device (boiler) on its own and is linked to the control system through a communication network such as a wireless network so that the user can control it remotely. There is an effect of improving the stability of a hot water supply device including a boiler by making preparations for unsuccessful errors and providing a real-time monitoring service.

1 is a block diagram of a hot water supply system having a remote control function according to an exemplary embodiment of the present invention;
2 is a block diagram of the hot water supply device of FIG. 1;
3 is a configuration diagram of a heating element according to an example of the present invention;
4 is a configuration diagram of a heating element according to another example of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. In adding reference numerals to the components of each drawing, the same components are to have the same reference numerals as much as possible even though they are indicated in different drawings. In addition, when it is determined that a detailed description of a known configuration or function related to the embodiment of the present invention may obscure the gist of the present invention, the detailed description thereof will be omitted. Hereinafter, each embodiment according to the present invention is merely an example for helping the understanding of the present invention, and the present invention is not limited to these embodiments. In particular, the present invention may be composed of a combination of at least any one of individual components or individual functions included in each embodiment.

1 is a block diagram of a hot water supply system 1 having a remote control function according to an exemplary embodiment of the present invention. As shown in the figure, a hot water supply device 100, a water purification device 110, and a sensor unit 120 , a control unit 130 , a power supply device 140 , a display device 150 , a remote communication module 160 , a communication network 170 , a management server 180 , and a manager terminal 190 may be included. .

The hot water supply device 100 represents a high-temperature generating device including a boiler for supplying hot water to the required place through the outlet pipe 60 after generating hot water by applying heat to the water introduced through the inlet pipe 10, In particular, it is possible to increase the driving force by forming a vortex in the working water and increase the contact area with the heating element to increase the thermal efficiency compared to the amount of electricity input, increase the outlet pressure, and also reduce the pollution level of the supplied hot water. See FIG. 2 to be described in detail.

The water purifying device 110 is to purify the quality of the water flowing in through the inlet pipe 10 or the water flowing out or circulated through the outlet pipe 60 to high quality water.

The sensor unit 120 includes the temperature of water flowing in through the inlet pipe 10 , the temperature of the heating element of the hot water supply device (high temperature generator) 100 , the temperature of water (hot water) flowing out through the outlet pipe 60 , and It may include various sensors for detecting water pressure, pollution degree of water, and the like.

The control unit 130 includes a hot water supply device (high temperature generator) 100, a water purification device 110, a display device 150, and a remote communication module 160 based on various data sensed through the sensor unit 120. It represents a controller for general control of the whole hot water supply system including the like.

The power supply device 140 represents a device for supplying power to the entire hot water supply system.

The display device 150 includes a user interface device for displaying various status information of the hot water supply device 100 and inputting various commands or setting values required by the user, for example, the control unit 130 According to the control, state information including the presence or absence of temperature abnormality, water pollution state, and water pressure abnormality state may be displayed visually or audibly according to the control.

The remote communication module 160 communicates with the remote management server 180 and the manager terminal 190 through the communication network 170 to implement Internet of Things (IoT) communication, and according to the control of the controller 130 , Various information including information detected through the sensor device 120 and information displayed through the display device 150 is transmitted to the remote management server 180 and/or the manager terminal 190, and the management server 180 ) and/or may receive various information including remote control command information transmitted from the manager terminal 190 .

The communication network 170 connects the hot water supply system 1 including the hot water supply device (high temperature generator) 100, the management server 180, and the manager terminal 190 through wired, wireless and/or the Internet. It represents a single or complex communication network to enable communication between objects.

The management server 180 provides real-time various status information including a temperature abnormality state for the hot water supply device (high temperature generator) 100 of the hot water supply system 1, a water pollution state, and a water pressure abnormality state. It is possible to collect, monitor, and transmit a remote control command from a manager to the controller 130 of the hot water supply device (high temperature generator) 100 to remotely control the device.

The manager terminal 190 includes a user terminal such as a smartphone, and when an abnormality occurs in the hot water supply device (high temperature generator) 100 of the hot water supply system 1, the controller 130 or the management server 180 Receives the provided abnormal information and notifies the manager (user) in real time, and also transmits a remote control command from the manager (user) to the controller 130 of the hot water supply device (high temperature generator) 100 to control the device Can be remotely controlled.

2 is a block diagram of a hot water supply device 1,100 according to an exemplary embodiment of the present invention.

Referring to FIG. 2 , the hot water supply device 1100 includes an inlet pipe 10 , a vortex generator 20 , a flow pipe 30 , a connection pipe 40 , a heating element 50 , an outlet pipe 60 , hot water supply It may include a tank 70 , a circulation pipe 75 , a water purification device 110 , a sensor unit 120 , a control unit 130 , and a power supply unit 140 .

The inlet pipe 10 is installed in the first direction to form a flow path through which raw water for generating hot water, for example, room temperature water, is introduced into the high temperature generator 100 .

The vortex generator 20 is installed in the inlet pipe 10 to apply vibration to the room temperature water introduced through the inlet of the inlet pipe 10 and generate a vortex, and applies vibration to the introduced water molecules for primary heating. By generating a vortex, it can be output by adding propulsion.

The flow pipe 30 and the connecting pipe 40 are for allowing the water that has passed through the inlet pipe 10 to flow along the zigzag flow path and then to flow out through the outlet pipe 60, for example, the flow pipe 30 is Connected to the outlet of the inlet pipe 10 and installed in a plurality parallel to each other in a second direction perpendicular to the first direction, a plurality of neighboring flow pipes 30 and flow pipes 30 are sequentially connected through the connecting pipe 40 . Although connected, the connecting pipe 40 may alternately connect the upper and lower portions of the flow pipe 30 to form a 'R'-shaped zigzag flow path.

The heating element 50 is installed in each flow pipe 30 to generate hot water by applying heat to the water passing through the flow pipe 30, in the longitudinal direction of the flow pipe 30 in each flow pipe 30 (ie, the second direction) A vortex can be formed in the flow pipe 30 by spirally guiding the flow path of water flowing in through the inlet of each flow pipe 30 and flowing out through the outlet.

The outlet pipe 60 is connected to the rear end of the plurality of flow pipes 30 in the first direction and passes through the flow pipe 30 while being covered by the heating element 50 and formed in a vortex to discharge hot water to which the driving force is added. It can be provided as 70 or directly provided to the outside so that it can be used as domestic hot water for washing dishes or food.

The hot water supply tank 70 is installed at the outlet of the outlet pipe 60 to store a certain amount of hot water and supply it as needed.

The circulation pipe 75 circulates the hot water discharged from the hot water supply tank 70 in a predetermined path and then returns it to the inflow pipe 10 , and may be used as, for example, a boiler pipe.

The hot water supply tank 70 and the circulation pipe 75 may be selectively configured.

The water purifying device 110 generates positive or negative ions and dissolves the generated ions under pressure, and is injected into room temperature water introduced through the inlet of the inlet pipe 10 or hot water flowing into the inlet pipe 10 through the circulation pipe 75 . it is to do

The sensor unit 120 includes a temperature sensor for detecting temperature, a water pressure sensor for detecting water pressure, and a pollution sensor for detecting the degree of contamination of water, and the temperature sensor is an outlet pipe 30 or a hot water supply tank ( 70) The temperature of the hot water and the heating temperature of the heating element 50 are sensed in real time, and the water pressure sensor can sense the water pressure of the hot water discharged from the outlet pipe 30 or the hot water supply tank 70 in real time.

The control unit 130 determines the degree of heat generation of the heating element 50, the degree of vibration of the vortex generator 20, and vortex generation based on various temperature information, water pressure information, and/or contamination information detected through the sensor unit 120 . It is for controlling the degree, ion generation and input amount.

The control unit 130, for example, if the temperature of the hot water is lower or higher than the set standard, by controlling the degree of heat generation of the heating element 50 so that the temperature of the hot water is the set standard, as another example, the set standard of the water outlet pressure of the hot water. If it is lower than that, it is possible to control the degree of vortex generation of the vortex generator 20 so that the water outlet pressure of the hot water is greater than or equal to a set standard. By controlling the amount and amount of ions generated and input, it is possible to purify contaminated water with good quality water.

The power supply unit (or referred to as a power supply device) 140 is for providing power to the hot water supply device 1 , and for example, may use energy accumulated using a solar power generation device (not shown).

3 is a configuration diagram of a heating element 50 according to an embodiment of the present invention.

Referring to (a) of FIG. 3 , the heating element 50 includes a rod-shaped heating member 51 and a rod-shaped heating member 51 located in the center of the flow tube 30 along the longitudinal direction of the flow tube 30 . It may be formed to include a spiral heating member 53 formed of spiral blades having a spiral surface maintaining a predetermined angle with the longitudinal direction of the flow pipe 30 around the.

Referring to (b) of FIG. 3 , the heating element 50 includes a rod-shaped heating member 51 and a rod-shaped heating member 51 located in the center of the flow tube 30 in the longitudinal direction of the flow tube 30 . A spiral heating member 53 formed of a spiral blade having a spiral surface maintaining a predetermined angle with the longitudinal direction of the flow pipe 30 on the periphery, and a plurality of projections 55 protruding on the surface of the spiral blade 53 can be formed including.

4 is a configuration diagram of a heating element according to another example of the present invention.

Referring to FIG. 4A , the heating element 50 may include a spiral heating member 53 having a spiral surface of a predetermined width maintaining a predetermined angle with the longitudinal direction of the flow pipe 30 .

Referring to (b) of FIG. 4 , the heating element 50 includes a spiral heating member 53 having a spiral surface of a predetermined width maintaining a predetermined angle with the longitudinal direction of the flow pipe 30 , and a spiral heating member 53 . ) may be formed to include a plurality of protrusions 55 protruding on the surface of the spiral surface.

According to the above-described embodiment of the present invention, a vortex is formed by the vortex generator 20 and the spiral heating element 50, so that the temperature of the introduced water can be raised to a high temperature state within a short time, thereby maximizing energy efficiency with a low current. And when the working water flows out, the pressure rises, and hot water can be transferred to a long distance without heat loss.

That is, the water obtained by the primary vibration heating in the vortex generator 20 and formed into a vortex flow pipe 30 flows while being guided spirally along the spiral surface 53 of the spiral blade of the spiral heating element 50, so that the water Since the water is heated while maximizing the contact area between the heating element and the heating element 50, the thermal efficiency is maximized and the driving force is further improved by forming a secondary vortex.

In addition, it is possible to control the degree of vortex generation of the vortex generator 20 so that the water outlet pressure of the hot water is greater than or equal to a set standard, and the type and amount of ions generated in the water purification device 110 according to the contamination degree of the hot water And by controlling the input amount, the contaminated water can be purified with good quality water.

Therefore, it is possible to reduce the cost of hot water production by increasing the thermal efficiency compared to the amount of electricity input, and by increasing the outflow pressure to send high-temperature working water over a long distance, it can be used in large capacity for agricultural and industrial purposes. It can be usefully used for washing dishes, food, etc.

In addition, by applying communication technology such as IoT, the controller (control unit) of the hot water supply device automatically controls the function of the device (boiler) by itself, and it is linked with the control system through a communication network such as a wireless network so that the user can control it remotely. By doing so, it is possible to prepare for unexpected errors through the Internet-based control system and to provide a real-time monitoring service.

The above description is merely illustrative of the technical spirit of the present invention, and various modifications and variations will be possible without departing from the essential characteristics of the present invention by those skilled in the art to which the present invention pertains. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical spirit of the present invention, but to explain, and the scope of the technical spirit of the present invention is not limited by these embodiments. The protection scope of the present invention should be construed by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

10: inlet pipe
20: vortex generator
30: flow pipe
40: connector
50: heating element
60: outlet pipe
70: hot water supply tank
75: circulation pipe
100, 1: Hot water supply (high temperature generator)
110: water purification device
120: sensor unit
130: control unit
140: power unit
150: display device
160: remote communication module
170: communication network
180: management server
190: user terminal

Claims (5)

an inlet pipe in a first direction; a vortex generator installed in the inlet pipe to apply vibration to room temperature water introduced through the inlet of the inlet pipe and generate a vortex; a plurality of flow pipes connected to the outlet of the inlet pipe and installed parallel to each other in a second direction perpendicular to the first direction; a connecting pipe sequentially connecting the plurality of neighboring flow pipes, but alternately connecting the upper part and the lower part; a heating element helically installed in each of the flow pipes in the second direction to spirally guide a flow path of water flowing in through the inlet of the flow pipe and flowing out through the outlet; an outlet pipe in a first direction connected to the rear ends of the plurality of flow pipes; a hot water supply tank installed at the outlet of the outlet pipe; a water purifying device for generating ions and dissolving the generated ions under pressure to inject the generated ions into room temperature water introduced through the inlet of the inlet pipe; A temperature sensor for detecting the temperature of the hot water in the hot water supply tank and the temperature of the heating element, a pollution sensor for detecting the degree of contamination of the hot water, and a water pressure sensor for detecting the water pressure of the hot water discharged from the hot water supply tank a sensor unit; and the degree of heat generation of the heating element based on the sensed temperature information, the degree of contamination information, and the water pressure information, the type of ions generated in the water purification device, the amount and input amount of ions, and the degree of vibration and the degree of vortex generation of the vortex generator Hot water supply device including a control unit for controlling;
a display device for visually or audibly displaying status information including at least one of a temperature abnormality state for hot water, a water pollution state presence or absence state, and a water pressure abnormality state according to the control of the controller; and
At least one of information sensed through the sensor unit and information displayed through the display device is transmitted to a remote management server or manager terminal under the control of the controller, and a remote control command from the management server or the manager terminal Including; a remote communication module for receiving information;
The controller is a hot water supply system having a remote control function, characterized in that for controlling the hot water supply device according to the remote control command. According to claim 1,
The heating element is a spiral heating member formed of a rod-shaped heating member located at the center of the flow tube along the longitudinal direction of the flow tube, and spiral blades having a spiral surface maintaining a predetermined angle with the longitudinal direction of the flow tube around the supporter. And, a hot water supply system having a remote control function, characterized in that it is formed to include a plurality of projections formed to protrude on the surface of the spiral blade. According to claim 1,
The heating element is a hot water supply system having a remote control function, characterized in that it is formed including a spiral heating member having a spiral surface of a predetermined width to maintain a predetermined angle with the longitudinal direction of the flow pipe. According to claim 1,
The hot water supply system having a remote control function, characterized in that it further comprises a circulation pipe for circulating the hot water discharged from the hot water supply tank in a predetermined path and then returning it to the inlet pipe. 5. The method of claim 4,
The water purifying device is a hot water supply system having a remote control function, characterized in that the input to the hot water flowing into the inlet pipe through the circulation pipe dissolved ions under pressure.

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