KR20190080531A - Scale-free boiler and water heating apparatus - Google Patents

Abstract

According to the present invention, a scale-free boiler comprises: a boiler case; a main flow path provided inside the boiler case and directly or indirectly connected to a heating flow path provided outside the boiler case to provide heating; a heat source unit for heating water flowing along the main flow path; and a filter unit including ion exchange resin which removes ionic substances contained in water flowing along the main flow path or water to be supplied to the main flow path by using a chemical reaction to prevent generation of scale.

Description

SCALE-FREE BOILER AND WATER HEATING APPARATUS

The present invention relates to a scale pre-boiler and a water heater.

A water heater such as a boiler or a water heater can supply heating water for heating by supplying water, or can provide hot water directly. However, water such as tap water supplied to a water heater usually contains an ionic substance such as calcium ion (Ca ²⁺ ) or magnesium ion (Mg ²⁺ ). The calcium or magnesium ion in the water can be precipitated as a carbonate in the form of calcium carbonate (CaCO ₃ ) or magnesium carbonate (MgCO ₃ ) by heat, and the precipitated carbonate can be fixed to the inner wall of a pipe or heat exchanger of a water heater have. Such a carbonate is referred to as a scale.

Such a scale fixation can cause cracks (cracks) in pipes, heat exchangers, etc., which leads to deterioration of durability and reduction in service life in the water heater. In spite of such a problem, a technique for preventing occurrence of scale as described above has not been developed so far.

An object of the present invention is to provide a scale-free boiler and a water heater in which the generation of scale is prevented in advance, the durability is increased, and the service life is extended.

A scale-free boiler according to an embodiment of the present invention includes a boiler case; A main flow path provided inside the boiler case, the main flow path being provided outside the boiler case and directly or indirectly communicating with a heating flow path for providing heat; A heat source unit for heating water flowing along the main flow path; And a filter unit including an ion exchange resin which removes water flowing along the main flow path or an ionic material contained in water to be supplied to the main flow path by using a chemical reaction in order to prevent the scale from being generated do.

A scale-free water heater according to an embodiment of the present invention includes a case, a main flow path provided inside the case, through which water flows to provide heating or hot water, An ion exchange resin which removes the ionic material contained in the water flowing through the main flow channel or the water supplied to the main flow channel by using a chemical reaction in order to prevent the scale from being generated And a filter unit.

Accordingly, by removing the ionic substance contained in the water flowing along the flow path of the boiler, the scale can be prevented from occurring, thereby increasing the durability of the boiler and prolonging its service life.

Without additional valve construction and valve operation, when the life of the filter is naturally shortened, it is possible to allow water to flow through only the main flow channel.

The filter can be easily replaced.

1 is a conceptual diagram conceptually showing a boiler according to a first embodiment of the present invention.
2 is a conceptual diagram conceptually showing a boiler according to a second embodiment of the present invention.
3 is a conceptual diagram conceptually showing a boiler according to a modification of the second embodiment of the present invention.
4 is a conceptual diagram conceptually showing a boiler according to a third embodiment of the present invention.
5 is a conceptual diagram conceptually showing a boiler according to a modification of the third embodiment of the present invention.
6 is a conceptual diagram conceptually showing a boiler according to a fourth embodiment of the present invention.

Hereinafter, some embodiments of the present invention will be described in detail with reference to exemplary drawings. It should be noted that, in adding reference numerals to the constituent elements of the drawings, the same constituent elements are denoted by the same reference symbols as possible even if they are shown in different drawings. In the following description of the embodiments of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the difference that the embodiments of the present invention are not conclusive.

In describing the components of the embodiment of the present invention, terms such as first, second, A, B, (a), and (b) may be used. These terms are intended to distinguish the constituent elements from other constituent elements, and the terms do not limit the nature, order or order of the constituent elements. When a component is described as being "connected", "coupled", "communicated", or "connected" to another component, the component may be directly connected or connected to the other component, It should be understood that another component may be "connected "," coupled ", "connected"

First Embodiment

1 is a conceptual diagram conceptually showing a boiler according to a first embodiment of the present invention. Referring to FIG. 1, the boiler according to the present embodiment includes a boiler case 110, a main flow path 130, a heat source 150, and a filter 160.

The boiler case (110)

The boiler case 110 is for accommodating therein the main flow path 130, the heat source 150, the filter 160, and other components to be described later. The boiler case 110 may be formed in a generally rectangular parallelepiped shape, but the shape of the boiler case 110 is not limited to such a shape.

In the main flow path 130,

The main flow path 130 is provided inside the boiler case 110 so that water (heating water) flows inside the boiler case 110.

The heating water flows along a heating flow path C provided in a heating target requiring heating, and provides heating to the heating target. After providing the heating, the heating water is returned to the boiler through the main flow path 130 communicated with the heating flow path C. The heating water is heated through the heat exchangers H1 and H2 by the heat source unit 150 which will be described later while flowing along the main flow path 130. [ The heating flow path C and the main flow path 130 communicate with each other directly or indirectly.

The main flow path 130 may be a flow path through which the heating water flows in the boiler case 110 except the flow path portion connected to the filter portion 160. First, the main flow path 130 may be realized by a pipe provided inside the boiler case 110. For example, the main flow path 130 includes an expansion tank S for accommodating the volume expansion of the heating water, and a flow control valve (not shown) for pressurizing the heating water in the main flow path 130, And a pump P for forcing the pump P to be connected to each other. Next, the main flow path 130 may be realized by a flow path provided in the heat exchangers H1 and H2. For example, the main flow path 130 may be realized by a passage provided in the latent heat exchanger H1 and the sensible heat exchanger H2, which are included in the heat exchangers H1 and H2. In addition, the main flow path 130 can be realized by a flow path provided inside the hot water generating section H3, which reaches the heating water passing through the heat exchangers H1 and H2. Therefore, the hot water generating section H3 can be used to warm the direct water introduced from the outside to hot water of high temperature and send it to hot water. The heating water that has passed through the hot water generating section H3 has a temperature lower than that when it is introduced into the hot water generating section H3 because heat is supplied to the hot water generating section H3, Flows into the expansion tank (S), the pump (P), and the like.

1, the pump P may be provided in the main flow path 130 on the downstream side of the second flow path 132 based on the flow direction of the heating water.

In the specification of the present invention, the criteria for distinguishing the upstream and downstream from the flow direction of the heating water are the heat exchangers H1 and H2, the hot water generating section H3, and the heating flow path C. Since the heating water is circulated through the heating flow path C and the hot water generating section H3 and flows through the main flow path 130, the portion where the water discharged from the heating flow path C and the hot water generating section H3 meet each other is the heating water It is the most upstream of the flow. Conversely, since the heating water flows into the heat exchangers H1 and H2, one portion of the main flow path 130 in which water is drawn into the heat exchangers H1 and H2 becomes the most downstream of the heating water flow.

In the heat source unit 150,

The heat source unit 150 is for heating water (heating water) flowing along the main flow path 130 and is provided inside the boiler case 110. The heat source unit 150 may be a conventional burner that receives air and fuel gas, and mixes and burns them.

The heat source unit 150 may heat the heating water through the generated flame or may heat the heating water through the exhaust gas generated during the generation of the flame. A boiler that utilizes this dual heat is called a condensing boiler. In order to realize such a condensing boiler, a sensible heat exchanger (H2) that heats the heating water using sensible heat of the heat source unit (150), a latent heat exchanger (H2) that recovers the latent heat of condensation of steam in the exhaust gas, (H1, H2) positioned adjacent to the heat source (150).

The heat source unit 150 is positioned adjacent to the heat exchangers H1 and H2 and can transmit heat to the heat exchangers H1 and H2. The heat exchanger is connected to a part of the main flow path 130 and transfers heat generated by the heat source unit 150 to the heating water flowing along the main flow path 130.

The filter unit 160,

The filter unit 160 removes the ionic material in water (heating water) by using an ion exchange resin in order to prevent scale from occurring. For this, the filter unit 160 is connected to the main flow path 130, receives the heating water from the main flow path 130, removes the ionic material from the supplied heating water, Return. The filter unit 160 may be provided to directly or indirectly communicate with the main flow path 130 from the outside of the boiler case 110.

The filter unit 160 in the first embodiment has the first flow path 131 and the second flow path (hereinafter, referred to as " first flow path ") at a location on the downstream side of the expansion tank S, 132, respectively. The first flow path 131 draws the heating water from the main flow path 130 to the filter section 160 and the second flow path 132 flows the heating water from the filter section 160 to the main flow path 130. It is preferable that the portion where the first flow path 131 communicates with the main flow path 130 is higher in pressure than the portion where the second flow path 132 communicates with the main flow path 130. [ This is because the flow of the heating water passing through the filter portion is formed by the pressure difference between two places. However, even if the pressure difference is different from that described above, a small amount of water may flow to the filter unit 160 through the first flow path 131.

The filter unit 160 includes an ion exchange resin which removes ionic substances contained in the supplied water (water for heating and water supplied to the main flow path) by using a chemical reaction. This is to prevent scale from occurring.

The water usually contains calcium ions (Ca2 +) and carbonate ions (CO ₃ ^2- ) or bicarbonate ions (HCO ₃ ⁺ ), which are formed by the dissolution of carbon dioxide. The calcium ions in the water can be precipitated as calcium carbonate (CaCO ₃ ) by heat (see Chemical Formula 1 below). The precipitated calcium carbonate can be fixed to the inner wall of the pipe or the heat exchangers H1 and H2. Fixation of calcium carbonate can lead to non-uniform transfer of heat, resulting in local overheating, and local overheating can cause cracks (cracks) in the pipe or heat exchanger due to thermal stresses.

According to this embodiment, the calcium ions, which are ionic substances in the heating water, are removed through the filter portion 160 of the ion exchange resin system, thereby preventing precipitation / sticking of the calcium carbonate, that is, scale generation in advance, Scale-free boiler can be implemented.

Since the filter unit 160 of this embodiment can remove ionic substances, it is possible to remove not only calcium ions but also other cationic substances contributing to scale generation such as magnesium ions. Thus, the ion exchange resin of the filter section 160 may be a cation exchange resin that removes the cationic material. When the cation exchange resin is used, the cost is low and the ion exchange capacity is large, which is suitable for long-term use, and the cost for holding the filter portion 16 is low, which is economical.

In addition, the filter unit 160 may remove anions such as carbonate ions or bicarbonate ions that bind to calcium ions or magnesium ions to form carbonates. Therefore, the ion exchange resin of the filter unit 160 may be an anion exchange resin for removing the anionic material.

Further, the ion exchange resin of the present invention may include both a cation exchange resin and an anion exchange resin. The cation exchange resin and the anion exchange resin are connected in series so that the cation and the anion can be sequentially removed from the incoming water.

The ion exchange resin using both the cation exchange resin and the anion exchange resin is composed of a predetermined ratio of the cation exchange resin and the anion exchange resin. Such an ion exchange resin may preferably be constituted by a ratio of the anion exchange resin to the proportion of the cation exchange resin. The pH value of the finally discharged water can be increased by the ion exchange resin formed so that the specific gravity of the anion exchange resin is relatively higher. As the pH value of water increases, there is a high possibility that a slight amount of residual cationic material in water will crystallize and precipitate. Therefore, the possibility that the salt formed by the cation on the inner wall of the pipe is adhered is reduced. Taking this into consideration, the ratio of the anion exchange resin in the ion exchange resin can be determined based on the pH value of the water discharged from the filter section.

For reference, H type resins in cation exchange resins have a problem of lowering the pH of discharged water instead of having a high ion exchange rate. When an OH type resin is used together with an anion exchange resin, the pH of discharged water can be increased again Therefore, the ion exchange rate can be increased without lowering the pH as described above.

As can be seen from the connected structure, the filter unit 160 functions as a bypass bypassing the main flow path 130. Accordingly, water may flow along the main flow path 130 and may flow through the first flow path 131 and the second flow path 132 communicated with the filter part 160. However, since the filter unit 160 includes an ion exchange resin to remove the ionic substance from the water passing through the filter unit 160, the life of the filter unit 160 becomes longer as the use of the filter unit 160 is repeated. The ion exchange resin bonds through a chemical reaction with the ionic substance to be removed, thereby curing the ionic substance while removing the ionic substance. Therefore, when the ionic material is supplied in a predetermined amount, the ion-exchange resin is hardly solidified and hardly passes through the water, and ions are not trapped. Accordingly, when the lifetime of the ion exchange resin is shortened, water can no longer flow through the filter unit 160, and water flows only through the main flow path 130. Therefore, when the life of the filter part is shortened, the water does not bypass through the first flow path 131 without a separate valve device, and water flows only into the main flow path 130.

On the other hand, the generation of scale is largely affected by heat. Accordingly, the scale mainly occurs in the heat exchangers H1 and H2. In consideration of this, the filter unit 160 of this embodiment can communicate with the upstream side of the heat exchanger H1 based on the flow direction of the heating water.

Eurobu

The boiler of this embodiment may further include a flow path portion. The flow path is for guiding at least one of water flowing along the main flow path 130 and water supplied from the outside of the boiler case 110 to the filter unit 160. The flow path is for guiding the filtered water by the filter unit 160 to the main flow path 130. The filter unit 160 includes a first flow path 131 for communicating the inlet of the filter unit 160 with the main flow path 130 and a second flow path 131 for communicating the outlet of the filter unit 160 with the main flow path 130. [ A replenishing flow path 132, and a replenishing flow path 136 to be described later.

The number of heating water in the expansion tank S can be reduced. Therefore, the heating water can be additionally supplied to the expansion tank S through the supply flow path 135 to supplement the heating water. Generally, in the case of the boiler, the supply passage 135 is connected to the expansion tank S in order to keep the water level of the expansion tank S constant. In the case of the other embodiments of the present invention, the supply passage 135 can be utilized for replenishing the heating water.

In addition, a heating water outlet 196 for discharging the heating water from the main flow path 130 may be provided. In the embodiment of the present invention, the heating water outlet 196 is positioned adjacent to the heating water passage C, but the position of the heating water outlet 196 is not limited thereto.

The sensing unit 191,

The sensing unit 191 is a component that senses TDS (Total Dissolved Solid) of the heating water in order to obtain the amount of the ionic material in the heating water. The sensing unit 191 may further include a TDS sensor. The amount of the soluble substance in the solution affects the electrical conductivity of the solution. The TDS sensor 191 measures the electrical conductivity of the solution and estimates the TDS of the solution.

It is not easy to directly obtain the amount of ionic substance in the heating water. However, there is a correlation between the TDS of the solution and the amount of ionic substance in the solution. Therefore, the boiler of the present embodiment can adopt a method of estimating the amount of the ionic material in the heating water based on the TDS of the heating water obtained through the TDS sensor 191.

The sensing unit 191 is provided in the main flow path 130 on the upstream side of the connection point between the first flow path 131 and the main flow path 130 and can sense the TDS of the heating water flowing along the main flow path 130 have. Also, the sensing unit 191 may be provided in the first flow path 131 to sense the TDS of the heating water flowing along the first flow path 131. In the present specification, the amount of the ionic substance can be obtained based on TDS as described above.

Measured values measured at the TDS sensor can be stored. Through this, it is possible to continuously monitor the water quality of the originally supplied water or the additional supplied water.

Second Embodiment

2 is a conceptual diagram conceptually showing a boiler according to a second embodiment of the present invention.

Referring to FIG. 2, the boiler according to the second embodiment of the present invention differs from the boiler according to the first embodiment in that the basic difference in the connection of the filter unit 160 and the arrangement of the pump P . For the sake of reference, the same or substantially equivalent components as those in the above-described configuration are denoted by the same or substantially the same reference numerals, and a detailed description thereof will be omitted.

In the second embodiment, the pump P is disposed immediately after the expansion tank S based on the flow direction of the heating water. The inlet of the filter unit 160 in the second embodiment is communicated with the inlet of the filter unit 160 through the first flow path 231 at a position downstream of the expansion tank S and the pump P and upstream of the heat exchangers H1 and H2, do. The outlet of the filter unit 160 communicates with the expansion tank S and the pump P via the second flow path 232 at a location upstream of the pump. The portion on the upstream side of the pump P will have a lower pressure than the portion on the downstream side of the pump. The heating water is introduced into the filter unit 160 through the first flow path 231 at one portion of the main flow path 130 which is the downstream side of the pump P and the inflowing heating water flows through the main flow path 130 to the main flow path 130 through the second flow path 232.

Modification of Second Embodiment

3 is a conceptual diagram conceptually showing a boiler according to a modification of the second embodiment of the present invention.

3, the boiler according to the modified example of the second embodiment of the present invention is different from the boiler according to the second embodiment described above in that the difference in the connection of the second flow path 2321 of the filter part 160 . For the sake of reference, the same or substantially equivalent components as those in the above-described configuration are denoted by the same or substantially the same reference numerals, and a detailed description thereof will be omitted.

In the modification of the second embodiment, the outlet of the filter portion 160 is communicated through the second flow path 232. The second flow path 2321 is communicated with the downstream side of the heat exchangers H1 and H2 based on the flowing direction of the heating water. The distance from the pump P to the portion where the second flow path 2321 communicates with the main flow path 130 is longer than the distance from the pump path to the portion where the first flow path 2311 communicates with the main flow path 130 , A pressure difference occurs between the portions where the two flow paths communicate with each other. Therefore, the heating water can flow from the first flow path 2311 to the second flow path 2321 through the filter section 160.

Third Embodiment

4 is a conceptual diagram conceptually showing a boiler according to a third embodiment of the present invention.

Referring to FIG. 4, the boiler according to the third embodiment of the present invention has a fundamental difference in the connection of the filter unit 160 as compared with the boiler according to the above-described embodiment. For the sake of reference, the same or substantially equivalent components as those in the above-described configuration are denoted by the same or substantially the same reference numerals, and a detailed description thereof will be omitted.

In the third embodiment, the pump P is disposed immediately after the expansion tank S based on the flow direction of the heating water. The inlet of the filter unit 160 communicates with the expansion tank S and the pump P via the first flow path 331 at a location upstream of the pump P in the third embodiment. The outlet of the filter unit 160 is connected to the second flow path 332 at a position upstream of the expansion tank S and the pump P and at a downstream side of the position where the first flow path 331 and the main flow path 130 meet, Respectively.

A flow rate sensor 181 may be disposed in the first flow path 331. Therefore, the flow rate of the heating water flowing along the first flow path 331 can be measured through the flow rate sensor 181. The flow rate of the heating water passing through the filter unit 160 can be grasped as the flow rate sensor 181 measures the flow rate of the heating water flowing through the first flow path 331.

The flow rate sensor 181 is electrically connected to the state determiner 182 and can transmit an electrical signal according to the measurement to the state determiner 182. The state determination unit 182 determines the state of the filter unit 160 according to the flow rate of the measured flow path portion.

When the measured flow rate of the flow path portion is smaller than or equal to the predetermined reference flow rate, the state determination portion 182 generates a signal informing the user that the filter portion 160 needs to be replaced.

The state determination unit 182 may notify the user of the flow rate value indicated by the received electric signal through the display device, or may transmit the flow rate value in the form of data using the communication means.

Modification of Third Embodiment

5 is a conceptual diagram conceptually showing a boiler according to a modification of the third embodiment of the present invention.

Referring to FIG. 5, a boiler according to a modification of the third embodiment of the present invention differs from the boiler according to the above-described embodiment in the additional piping connected to the filter unit 160. For the sake of reference, the same or substantially equivalent components as those in the above-described configuration are denoted by the same or substantially the same reference numerals, and a detailed description thereof will be omitted.

In the modified example of the third embodiment, the filter unit 160 receives the direct water from the direct water flow path 330 through the direct water first flow path 333, removes the ionic material, To the direct flow path (330). The direct water first flow path 333 is a flow path for communicating the inlet of the filter portion 160 and the direct flow path 330 so that direct water is supplied from the direct flow path 330 to the filter portion 160. The direct water second flow path 334 communicates the outlet of the filter part 160 with the direct flow path 330 to direct the direct water from the filter part 160 to the direct flow path 330. As the direct water is supplied to the filter unit 160 and filtered, it is possible to prevent the scale from being formed in the pipe constituting the direct water flow path 330. In addition, when the filter unit 160 can not pass water to the filter unit 160 due to a short life, the direct water also does not flow through the direct water first flow path 333.

The first flow path 331 may include a first flow path valve 3311 which is a valve capable of controlling the heating water flow by controlling the opening and closing of the first flow path 331. Further, the filter unit 160 may be detachably coupled to the first flow path 331 and the second flow path 332. The first flow path valve 3311 can be closed and the ion exchange resin of the filter portion 160 can be replaced when the life of the ion exchange resin of the filter portion 160 is shortened as the first flow path valve 3311 is disposed . This is to prevent the heating water from flowing and leaking through the first flow path 331 when the filter unit is separated from the first flow path 331 and the second flow path 332.

Fourth Embodiment

6 is a conceptual diagram conceptually showing a boiler according to a fourth embodiment of the present invention.

Referring to FIG. 6, the boiler according to the fourth embodiment of the present invention differs from the boiler according to the above-described embodiment in that there is an additional flow passage connected to the filter unit 160. For the sake of reference, the same or substantially equivalent components as those in the above-described configuration are denoted by the same or substantially the same reference numerals, and a detailed description thereof will be omitted.

In the fourth embodiment, the pump P is disposed on the downstream side of the expansion tank S with respect to the flow direction of the heating water. In the fourth embodiment, the inlet of the filter unit 160 communicates with the downstream side of the expansion tank S through the first flow path 431 at a location on the upstream side of the pump P. The outlet of the filter section 160 is located downstream of the expansion tank S and upstream of the pump P at a location downstream of the location where the first flow path 431 and the main flow path 130 meet, (432).

In the fourth embodiment, the filter unit 160 receives water to be supplied to the flow path 130, for example, water to be supplied from the outside of the boiler case to the main flow path 130, It is possible. The flow path portion of the boiler of the fourth embodiment further includes a supplementary flow path 136 that communicates the first flow path 231 with the supply flow path 135. Therefore, the supplementary flow passage 136 can guide the water supplied from the outside of the boiler casing 110 to the filter section 160.

The boiler of the present embodiment further includes a supplementary three-way valve 433 provided at a connection point between the first flow path 431 and the supplementary flow path 136. Therefore, the replenishing three-way valve 433 can be used to determine a flow path for supplying water to the filter portion 160 of the first flow path 431 and the supplementary flow path 136. The boiler of this embodiment may further include a supply three-way valve (not shown) at a connection point between the supply passage 135 and the supplementary passage 136.

A scale-free water heater according to an embodiment of the present invention includes a case, a main flow path provided inside the case, through which water flows to provide heating or hot water, An ion exchange resin which removes the ionic material contained in the water flowing through the main flow channel or the water supplied to the main flow channel by using a chemical reaction in order to prevent the scale from being generated And a filter unit. The description of each embodiment of the boiler can also be applied to the present scale-free water heater to prevent scale from occurring in the flow path or each component of the water heater.

While the present invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not limited to the disclosed embodiments. That is, within the scope of the present invention, all of the components may be selectively coupled to one or more of them. Furthermore, the terms "comprises", "comprising", or "having" described above mean that a component can be implanted unless otherwise specifically stated, But should be construed as including other elements. All terms, including technical and scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs, unless otherwise defined. Commonly used terms, such as predefined terms, should be interpreted to be consistent with the contextual meanings of the related art, and are not to be construed as ideal or overly formal, unless expressly defined to the contrary.

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

110: boiler case 130: main flow path
131, 231, 331, 431, 2311:
132, 232, 332, 432, 2321:
135: Supply flow channel 136: Replacement flow channel
150: heat source unit 160: filter unit
181: Flow rate sensor 182:
191: sensing unit 196: heating water outlet
330: direct water flow path 333: direct water first flow path
334: Direct water second flow path 433: Replacement three-way valve
3311: first flow path valve C: heating flow path
H1: latent heat exchanger H2: sensible heat exchanger
P: pump S: expansion tank

Claims (18)

Boiler case;
A main flow path provided inside the boiler case, the main flow path being provided outside the boiler case and directly or indirectly communicating with a heating flow path for providing heat;
A heat source unit for heating water flowing along the main flow path; And
And a filter portion including an ion exchange resin that removes water flowing along the main flow path or an ionic material contained in water to be supplied to the main flow path by using a chemical reaction in order to prevent generation of scale , Scale-free boiler. The method according to claim 1,
A first flow path communicating the main flow path with an inlet of the filter portion; And
And a second flow path communicating the main flow path and the outlet of the filter section. 3. The method of claim 2,
The flow-
At least a part of the water flowing through the main passage is guided to the inlet of the filter section through the first passage and the water filtered through the filter section is guided to the main passage through the second passage, Scale-free boiler. 3. The method of claim 2,
And a heat exchanger positioned adjacent to the heat source unit and connected to a part of the main flow channel to transfer heat generated by the heat source to the water flowing along the main flow channel. 5. The method of claim 4,
Further comprising a pump for pressurizing the water so that the water flows along the main flow path,
A flow direction of the water flowing along the main flow path,
Wherein the first flow path communicates with the main flow path at a location downstream of the pump and upstream of the heat exchanger and the second flow path communicates with the main flow path at a location upstream of the pump. 5. The method of claim 4,
Further comprising a pump for pressurizing the water so that the water flows along the main flow path,
A flow direction of the water flowing along the main flow path,
Wherein the first flow path communicates with the main flow path at a location downstream of the pump and upstream of the heat exchanger and the second flow path communicates with the main flow path at a location downstream of the heat exchanger. 5. The method of claim 4,
A flow direction of the water flowing along the main flow path,
Wherein the first flow path is communicated with the main flow path at a location upstream of the heat exchanger, the second flow path is located at an upstream side of the heat exchanger, and the first flow path is located downstream of a portion communicating with the main flow path, A scale-free boiler that is connected to the main flow path. 5. The method of claim 4,
Further comprising an expansion tank located on an upstream side of the heat exchanger with respect to a flow direction of the water flowing along the main flow path and accommodating a volume expansion of the water flowing along the main flow path,
Wherein the flow path communicates with the main flow path at a location upstream of the heat exchanger and downstream of the expansion tank. 5. The method of claim 4,
Further comprising an expansion tank located on an upstream side of the heat exchanger with respect to a flow direction of the water flowing along the main flow path and accommodating a volume expansion of the water flowing along the main flow path,
And the flow path communicates with the main flow path at a position on the upstream side of the expansion tank. The method according to claim 1,
Wherein the ion exchange resin of the filter section is a cation exchange resin for removing a cationic substance or an anion exchange resin for removing an anionic substance. The method according to claim 1,
Wherein the ion exchange resin of the filter portion is provided with a cation exchange resin for removing a cationic substance and an anion exchange resin for removing an anionic substance are connected in series. 12. The method of claim 11,
Wherein a ratio of the anion exchange resin in the ion exchange resin is determined based on a pH value of water discharged from the filter portion. 3. The method of claim 2,
Wherein the first flow path is provided with a first flow path valve capable of controlling opening and closing of the first flow path,
And the filter portion is detachably coupled to the flow path portion. 3. The method of claim 2,
Wherein the flow path portion further comprises a flow rate sensor capable of measuring a flow rate of the water flowing along the flow path portion,
Further comprising: a state determination unit for determining a state of the filter unit according to a flow rate of the flow passage measured by the flow sensor. 15. The method of claim 14,
Wherein the state determining unit generates a signal informing a user that replacement of the filter unit is required when the measured flow rate of the flow path portion is smaller than or equal to a predetermined reference flow rate. 3. The method of claim 2,
Wherein the flow path portion further comprises a replenishing flow path for guiding the water supplied from the outside of the boiler case to the filter portion. The method according to claim 1,
Wherein the filter portion further communicates with the direct water flow path to receive the direct water and further removes the ionic material contained in the direct water and returns the ionic material to the direct water flow path. case;
A main flow path provided inside the case, through which water flows to provide heating or hot water;
A heat source unit for heating water flowing along the main flow path; And
And a filter portion including an ion exchange resin that removes water flowing along the main flow path or an ionic material contained in water to be supplied to the main flow path by using a chemical reaction in order to prevent generation of scale , Scale-free water heater.

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