KR101652081B1 - Hot-water supply system - Google Patents

Abstract

The present invention relates to first and second electrode boilers driven independently of each other; A storage tank connected to the first and second electrode boilers and storing hot water heated by the first and second electrode boilers; And a controller for individually controlling operations of the first and second electrode boilers.

Description

{HOT-WATER SUPPLY SYSTEM}

The present invention relates to an electrode boiler hot water supply system, and more particularly, to an electrode boiler hot water supply system capable of remarkably reducing the time required for heating hot water.

It is not easy to raise the boiler temperature at low temperatures even in large facilities such as hot springs, buildings, saunas, vinyl houses, greenhouses, and even small houses including general households.

For example, when the boiler is operated for the use of hot water, it can be seen that the temperature is raised very slowly at an initial low temperature and then rapidly heated at a certain point in time, for example, when the temperature of the water becomes 45 ° C or higher. There are many restrictions on the initial temperature control of hot water.

In particular, when hot water is poured in order to take a shower in winter, it takes about several minutes to several tens of minutes for the boiler to completely heat the hot water, so it is often necessary to wait until the hot water comes out Considering this, it is necessary to develop a new and advanced type of hot water supply system that can overcome these problems.

Korea Patent Office Application No. 10-1987-0004314 Korea Patent Office Application No. 10-1991-0011250 Korea Patent Office Application No. 10-2005-0095776 Korea Patent Office Application No. 20-1997-0025745

It is an object of the present invention to provide an electrode boiler hot water supply system which can shorten the time required for heating hot water to a remarkably shorter time than in the prior art.

The object of the present invention can be achieved by first and second electrode boilers driven independently of each other; A storage tank connected to the first and second electrode boilers and storing hot water heated by the first and second electrode boilers; And a controller for individually controlling the operation of the first and second electrode boilers.

The controller can control to turn on only the operation of the first line pump when the hot water is heated to the heating turning temperature formed between the temperature of the hot water and the target heating temperature.

Wherein the controller further turns on the operation of the second line pump when the temperature of the water supplied from the heat storage tank reaches the heating turning temperature so that the operation of the first and second electrode boilers causes the water It can be controlled to be heated.

Both the first and second electrode boilers include first and second boiler bodies; First and second electrode rods arranged in a pair in the first and second boiler bodies to heat water; First and second water discharge units provided at lower ends of the first and second boiler bodies and through which water is discharged from the first and second boiler bodies; And first and second water inflow portions provided at the upper ends of the first and second boiler bodies and into which water flows into the first and second boiler bodies.

First and second water discharge lines connecting the storage tank and the first and second water discharge portions, respectively; First and second water inflow lines connecting the storage tank and the first and second water inflow sections, respectively; And first and second line pumps respectively provided in the first and second water inflow lines and for pumping water flowing along the first and second water inflow lines.

And first and second check valves provided on the first and second water inflow lines, respectively, for blocking reverse flow of water on the first and second water inflow lines.

And a temperature sensor coupled to the second electrode boiler and sensing a temperature of water flowing in the heat storage tank.

According to the present invention, there is an effect that the time required for heating hot water can be remarkably shortened compared with the conventional one.

Particularly, according to the present invention, since the time required for heating hot water is shortened, the hot water can be used instantly without having to wait even when hot water is used, so that convenience in use of hot water can be greatly improved and even though a small amount of hot water is used And it is possible to reduce the time or economic loss due to the large amount of water to be heated.

1 is a temperature rise curve of a general water.
2 is a configuration diagram of an electrode boiler hot water supply system according to a first embodiment of the present invention.
3 is a control block diagram of the electrode boiler hot water supply system shown in FIG.
4 is a configuration diagram of an electrode boiler hot water supply system according to a second embodiment of the present invention.
5 is a control block diagram of the electrode boiler hot water supply system shown in FIG.
6 is a configuration diagram of an electrode boiler hot water supply system according to a third embodiment of the present invention.
7 is a control block diagram of the electrode boiler hot water supply system shown in FIG.

BRIEF DESCRIPTION OF THE DRAWINGS The advantages and features of the present invention, and how to accomplish them, will become apparent by reference to the embodiments described in detail below with reference to the accompanying drawings.

The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein.

In the present specification, the present embodiment is provided to complete the disclosure of the present invention and to fully disclose the scope of the invention to a person having ordinary skill in the art to which the present invention belongs. And the present invention is only defined by the scope of the claims.

Thus, in some embodiments, well known components, well known operations, and well-known techniques are not specifically described to avoid an undesirable interpretation of the present invention.

Like reference numerals refer to like elements throughout the specification. And (used) terms used herein are for the purpose of illustrating embodiments and are not intended to limit the invention.

In the present specification, the singular form includes plural forms unless otherwise specified. Also, components and acts referred to as " comprising (or comprising) " do not exclude the presence or addition of one or more other components and operations.

Unless defined otherwise, all terms (including technical and scientific terms) used herein may be used in a sense commonly understood by one of ordinary skill in the art to which this invention belongs.

Also, commonly used predefined terms are not ideally or excessively interpreted unless they are defined.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

1 is a temperature rise curve of a general water.

As shown in this figure, when water is heated by a conventional boiler, for example, the first electrode boiler 110 or the second electrode boiler 120 according to the present embodiment, at a very low speed It can be seen that the temperature rises and the water temperature rises at a steep rate above 45 ° C.

In other words, it is known that the water is heated at a very high speed when the hot water is heated to the heating turning temperature formed between the temperature of the hot water and the target heating temperature (P1) .
That is, the heating turning temperature is a heating-up rapid-increase conversion temperature which is a temperature of a transition point at which the temperature of the hot water starts to rise sharply at a steep rate when the hot water is heated to the target heating temperature.

The electrode boiler hot water supply system according to the present embodiment is designed in consideration of the heating characteristics of the water.

Hereinafter, the electrode boiler hot water supply system according to the present embodiment will be described in detail with reference to FIG. 2 and FIG.

FIG. 2 is a configuration diagram of an electrode boiler hot water supply system according to a first embodiment of the present invention, and FIG. 3 is a control block diagram of the electrode boiler hot water supply system shown in FIG.

Referring to these drawings, the electrode boiler hot water supply system according to the present embodiment can remarkably reduce the time required for heating hot water, and the first and second electrode boilers 110 and 120, the heat storage tank 130, , And a controller (190).

First, the first and second electrode boilers 110 and 120 are boilers for heating hot water to make hot water. In the present embodiment, two of the first and second electrode boilers 110 and 120 are independently arranged and driven. That is, the first and second line pumps 161 and 162 can be independently turned on / off by the controller 190.

The first and second electrode boilers 110 and 120 applied to the present embodiment are boilers of a totally different concept differentiated from conventional electric boilers.

A conventional electric boiler is a method in which a heater rod not shown in the drawing is heated and a heated heater rod heats the water.

However, in the case of the first and second electrode boilers 110 and 120, there is no heater rod, and the first and second electrode rods 112 and 122 are applied.

No heat is generated in the first and second electrode rods 112 and 122 even if electricity is supplied. Instead, when electricity is applied to the first and second electrode rods 112 and 122, water between them is ionized, and water molecules act as a flow resistance to generate Joule heat of 860 Kcal / Kw. As the water temperature increases, the resistance value of the water increases more rapidly, so that the desired high temperature water can be obtained in a shorter time.

The generated heat is vaporized at a low temperature due to the heat medium flow path in the first and second electrode rods 112 and 122 to further enhance the thermal conductivity and amplify heat to water by rapid thermal diffusion. Heat quickly.

It is known that the first and second electrode boilers 110 and 120 have an energy saving efficiency of 20% or more as compared with the conventional electric boiler. However, in this embodiment, the first and second electrode boilers 110 and 120, .

Since the two first and second electrode boilers 110 and 120 are arranged in parallel, the structures thereof are the same.

That is, the first electrode boiler 110 includes a first boiler body 111 forming a space into which water is introduced, a first electrode rod 112 disposed in a pair in the first boiler body 111 to heat water, ). A second boiler body 121 forming a space into which water is introduced into the second electrode boiler 120 and a second electrode 122 disposed in the second boiler body 121 to heat water, .

A first water discharge portion 113 through which water in the first boiler body 111 is discharged is provided at a lower end of the first boiler body 111. A second water discharge portion 123 through which water in the second boiler body 121 is discharged is provided at a lower end of the second boiler body 121.

A first water inflow part 114 through which water flows into the first boiler body 111 is provided at the upper end of the first boiler body 111. A second water inflow part 124 through which water flows into the second boiler body 121 is provided at the upper end of the second boiler body 121.

Next, the heat storage tank 130 is connected to the first and second electrode boilers 110 and 120, and the hot water heated by the first and second electrode boilers 110 and 120 is stored. The capacity of the tank can be changed at any time.

First and second water discharge lines 141 and 142 and first and second water inflow lines 151 and 152 are provided for connecting the heat storage tank 130 and the first and second electrode boilers 110 and 120.

The first and second water discharge lines 141 and 142 are pipes connecting the heat storage tank 130 and the first and second water discharge units 113 and 123 respectively and the first and second water inflow lines 151 and 152, (130) and the first and second water inflow sections (114, 124), respectively.

The first and second water inflow lines 151 and 152 are provided with first and second line pumps 161 and 162 for pumping water flowing along the first and second water inflow lines 151 and 152, respectively.

The first and second water inflow lines 151 and 152 of the first and second line pumps 161 and 162 are provided with first and second check valves 171, 172).

In this embodiment, unlike the first electrode boiler 110, the second electrode boiler 120 is provided with a temperature sensor 180 for sensing the temperature of water flowing in the heat storage tank 130.

The temperature sensor 180 may be coupled to the second boiler body 121 at a location adjacent to the second water inlet 124.

Finally, the controller 190 controls the operation of the first and second electrode boilers 110 and 120 individually.

That is, in this embodiment, the controller 190 controls the operation of the first line pump 161 only when the room temperature water is heated up to the heating turning temperature formed between the temperature of the hot water and the target heating temperature, The operation of the second line pump 162 is further turned on when the temperature of the water supplied from the tank 130 reaches the heating turning temperature so that the operation of the first and second electrode boilers 110, Control to be heated.
2, the first electrode boiler 110 and the second electrode boiler 120 are connected to each other. Even if the second line pump 162 is not operated, the water in the storage tank 130 Can flow to both the first electrode boiler (110) and the second electrode boiler (120). Accordingly, the temperatures of the water in the first and second electrode boilers 110 and 120 are substantially the same.
Therefore, when the controller initially operates only the first electrode boiler 110 and the temperature of the water reaches a predetermined temperature (heating turning temperature) by sensing the temperature sensor 180 on the second electrode boiler 120 side, The boiler 120 can be operated together to heat the hot water more quickly.

The controller 190 may include a central processing unit 191 (CPU), a memory 192 (MEMORY), and a support circuit 193 (SUPPORT CIRCUIT).

The central processing unit 191 controls to turn on only the operation of the first line pump 161 when the room temperature water is heated up to the heating turning temperature formed between the temperature of the hot water and the target heating temperature in this embodiment, The operation of the second line pump 162 is further turned on when the temperature of the water supplied from the storage tank 130 reaches the heating turning temperature so that the operation of the first and second electrode boilers 110, May be one of a variety of computer processors that may be industrially applicable to control heating.

The memory 192 (MEMORY) is connected to the central processing unit 191. The memory 192 is a computer-readable recording medium that may be installed locally or remotely and may be any of various types of storage devices such as, for example, random access memory (RAM), ROM, floppy disk, hard disk, At least one or more memories.

A support circuit 193 (SUPPORT CIRCUIT) is coupled with the central processing unit 191 to support the typical operation of the processor. Such a support circuit 193 may include a cache, a power supply, a clock circuit, an input / output circuit, a subsystem, and the like.

The controller 190 controls the operation of the first line pump 161 only when the hot water is heated up to the heating turning temperature formed between the temperature of the hot water and the target heating temperature, The operation of the second line pump 162 is further turned on when the temperature of the water supplied from the first and second electrode boilers 130 and 130 reaches the heating turning temperature so that the water is heated by the operation of the first and second electrode boilers 110 and 120 .

At this time, when the hot and cold water is heated up to the heating turning temperature formed between the temperature of the hot water and the target heating temperature, only the operation of the first line pump 161 is controlled to be turned on and the water supplied from the heat storage tank 130 A series of processes for controlling the water to be heated by the operation of the first and second electrode boilers 110 and 120 by further turning on the operation of the second line pump 162 when the temperature reaches the heating turning temperature May be stored in the memory 192. Typically, software routines may be stored in memory 192. The software routines may also be stored or executed by other central processing units (not shown).

Although processes according to the present invention are described as being performed by software routines, it is also possible that at least some of the processes of the present invention may be performed by hardware. As such, the processes of the present invention may be implemented in software executed on a computer system, or in hardware such as an integrated circuit, or in combination of software and hardware.

When the hot water is turned on, only the first line pump 161 is operated to reduce the supply of water into the first boiler body 111 of the first electrode boiler 110, When the temperature of the water supplied from the heat accumulation tank 130 reaches a predetermined temperature, that is, the heating turning temperature (see FIG. 1), the second line pump 162 is operated to maintain the water temperature for a long time So that the temperature of the water in the heat storage tank 130 can be increased at a high speed by the first and second electrode boilers 110 and 120.

According to the present embodiment having such a structure and action, the time required for heating the hot water can be remarkably reduced compared with the conventional one.

Particularly, according to the present embodiment, since the time required for heating the hot water is reduced, the hot water can be used instantly without having to wait even when using the hot water in the cold winter, It is possible to reduce the temporal or economic loss due to the need to heat a large amount of water.

FIG. 4 is a configuration diagram of an electrode boiler hot water supply system according to a second embodiment of the present invention, and FIG. 5 is a control block diagram of the electrode boiler hot water supply system shown in FIG.

Referring to these drawings, the electrode boiler hot water supply system according to the present embodiment also includes first and second electrode boilers 110 and 120, a heat storage tank 130, and a controller 190.

Meanwhile, the electrode boiler hot water supply system according to the present embodiment includes an input unit 280, a timer 285, and a controller 270 in addition to the above structure.

The input unit 280 is a panel operated by the user for using hot water. It may be a fixed type installed on a wall, or it may be a remote type movable type.

Accordingly, the user checks the use of the hot water through the button of the input unit 280. Then, the controller 270 drives the first electrode boiler 110 for a predetermined time, for example, 3 seconds, by the timer 285, and when the predetermined time is completed, the second electrode boiler 120 is driven by the first electrode boiler 110, (110) so that hot water supply is possible.

The time required for heating the hot water can be remarkably reduced even when the present embodiment is applied. In particular, since the time required for heating the hot water is reduced, the hot water can be used instantly without having to wait even when using the hot water in the cold winter season. Thus, the convenience of use of the hot water can be greatly improved and a large amount of water It is possible to reduce the time or economic loss due to the heating.

FIG. 6 is a configuration diagram of an electrode boiler hot water supply system according to a third embodiment of the present invention, and FIG. 7 is a control block diagram of the electrode boiler hot water supply system shown in FIG.

Referring to these drawings, the electrode boiler hot water supply system according to the present embodiment also includes first and second electrode boilers 110 and 120, a heat storage tank 130, and a controller 190.

In addition to the above structure, the electrode boiler hot water supply system according to the present embodiment includes a first water temperature sensor 381 disposed in the water inlet area of the heat storage tank 130 to check the water temperature in the water inlet area, And a second water temperature sensor 382 arranged in the water outlet area in the water outlet area for checking the water temperature in the water outlet area.

In this structure, the controller 370 receives and compares the water temperature values of the water inlet area and the water outlet area from the first and second water temperature sensors 381.382, and when the water temperature comparison value is equal to or less than a preset value, So that the operation of the two-line pump 162 is turned on.

In other words, at the initial stage of driving, only the first line pump 161 is operated to heat the water, and when the water temperature comparison value of the water inlet area and the water outlet area of the heat storage tank 130 is equal to or less than a predetermined value, The pump 162 is further actuated to allow water to be heated more quickly.

The time required for heating the hot water can be remarkably reduced even when the present embodiment is applied. In particular, since the time required for heating the hot water is reduced, the hot water can be used instantly without having to wait even when using the hot water in the cold winter season. Thus, the convenience of use of the hot water can be greatly improved and a large amount of water It is possible to reduce the time or economic loss due to the heating.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. It is therefore intended that such modifications or alterations be within the scope of the claims appended hereto.

110: first electrode boiler 111: first boiler body
112: first electrode rod 113: first water discharge portion
114: first water inflow section 120: second electrode boiler
121: second boiler body 122: second electrode rod
123: second water discharging part 124: second water inflow part
130: heat storage tank 141, 142: first and second water discharge lines
151, 152: first and second water inflow lines 161, 162: first and second line pumps
171, 172: first and second check valves 180: temperature sensor
190: controller

Claims (7)

First and second electrode boilers driven independently of each other;
A storage tank connected to the first and second electrode boilers and storing hot water heated by the first and second electrode boilers;
A first water temperature sensor disposed in a water inlet area of the heat storage tank to check a water temperature of the water inlet area;
A second water temperature sensor disposed in a water outlet area in the storage tank for checking a water temperature in the water outlet area; And
A controller for individually controlling operations of the first and second electrode boilers; , ≪ / RTI &
The first electrode boiler includes a first boiler body, a first electrode rod disposed in a pair in the first boiler body to heat water, and a second electrode rod provided at a lower end of the first boiler body, A first water inflow part provided at an upper end of the first boiler body and through which water flows into the first boiler body, and a second water inflow part provided at an upper end of the first boiler body, A first water inflow line connecting the heat storage tank and the first water inflow section and a first line pump provided in the first water inflow line and pumping water flowing along the first water inflow line; And a first check valve provided in the first water inflow line and blocking reverse flow of water on the first water inflow line,
The second electrode boiler includes a second boiler body, a second electrode rod disposed in a pair in the second boiler body to heat water, and a second electrode rod provided at a lower end of the second boiler body, A second water inflow part provided at an upper end of the second boiler body and through which water flows into the second boiler body, and a second water inflow part provided at an upper end of the second boiler body, for connecting the heat storage tank and the second water discharge part A second water inflow line connecting the storage tank and the second water inflow section, and a second line pump provided in the second water inflow line for pumping water flowing along the second water inflow line, And a second check valve provided on the second water inflow line and blocking reverse flow of water on the second water inflow line,
The controller controls to turn on the operation of the first line pump when the hot water is heated to the heating turning temperature formed between the temperature of the hot water and the target heating temperature, the water temperature values of the water inlet area and the water outlet area from the first and second water temperature sensors are compared with each other, and when the water temperature comparison value is equal to or less than a predetermined value, To control the operation of the first switch
Wherein the electrode boiler is connected to the electrode boiler. delete delete delete delete delete delete

Images