KR100456397B1 - Purification device for condensing boiler - Google Patents

Abstract

The present invention relates to a condensing water purification device of a condensing boiler for neutralizing acidic condensate generated in the condensing boiler with neutral water harmless to the environment and removing unburned content contained in the condensing water. The perforated plate 60 and the diaphragm 70 are installed horizontally and vertically, respectively, so that a first compartment 110 is formed below the perforated plate 60, and the second compartment 120 and the diaphragm 70 are bounded. Body 100 having a third compartment 130 is formed, the upper portion of the second compartment 120, the condensate inlet 121 is connected to the condensation outlet of the boiler, the upper portion of the one side of the third compartment (130) Calcium oxide (CaO) and silicon (Si) mixtures are contained in the condensate discharge port 131, the filter 24, the activated carbon 28, and the third compartment 130 accommodated in the second compartment 120. Porous neutralizing agent (20) made of a curing and made in an autoclave, Characterized in that the lid 30 is coupled to the upper body 100.

Description

Condensing water purifier of condensing boiler

The present invention relates to a condensation water purification device of a condensing boiler for neutralizing acidic condensate generated in the condensing boiler with neutral water harmless to the environment, and to remove unburned content contained in the condensing water. The present invention relates to a condensing water purification device of a condensing boiler capable of increasing the neutralizing effect of condensate by increasing the contact area per unit volume of condensate and neutralizing agent, and at the same time miniaturizing the neutralizing device and removing unburned content contained in the condensate.

Conventional condensing boilers increase heat efficiency by recovering heat from hot exhaust gases. To this end, the condensing boiler is provided with a separate latent heat exchanger in addition to the sensible heat exchanger, and condensed water is generated when the temperature of the exhaust gas deprived of heat from the latent heat exchanger falls below the dew point.

However, since the exhaust gas contains a small amount of acidic substances such as CO₂, NOx and SOx, the condensed water cooled in the latent heat exchanger is acidic, so if the condensate is drained to the sewer without additional neutralization, the stream is acidified. There is a problem that can adversely affect the river ecosystem and the surrounding environment and there was a problem of corroding sewage pipes.

In order to solve this problem, the applicant has devised a neutralizing device of the hot water boiler of Patent Application No. 2001-61380, but since the neutralizing agent is filled in the form of fine powder, when the condensate is introduced, a mass is formed and the reaction with the condensate occurs. Not evenly achieved sufficient neutralization effect was not obtained. In addition, since the powdered neutralizing agent uses chemicals (such as calcium hydroxide or magnesium hydroxide), care must be taken when handling.

In addition, condensate is discharged with a small amount of unburned powder, but the existing neutralizer is equipped with only a neutralizing agent, and does not have a separate filter for removing unburned powder, which is causing a serious increase in water pollution due to unburned powder. It is true.

The present invention has been made in view of the above, and provides a condensing water purification device of a condensing boiler which can obtain the neutralization effect as much as possible without being lumped in water and remove unburned content contained in the condensate. Its purpose is to.

1 is an exploded perspective view according to an embodiment of the present invention

Figure 2 is a perspective view of the combination according to an embodiment of the present invention

3 is a cross-sectional view according to an embodiment of the present invention.

<Description of Symbols for Major Parts of Drawings>

100: body 110: first compartment

120: second compartment 121: condensate inlet

130: third compartment 131: condensate discharge outlet

13, 14: screw portion 15: fitting portion

20: neutralizer 24: filter

28: activated carbon 30: lid

40: O-ring 50: check valve

60: porous plate 61: support piece

62: groove 70: plate

Condensate water purification device of the present invention condensing boiler for achieving the above object, the upper surface is open and the perforated plate and the diaphragm are installed horizontally and vertically therein, the first compartment is formed below the perforated plate and the diaphragm A body having a second compartment and a third compartment formed as a boundary, a condensate inlet formed on one side of the second compartment and connected to the condensate outlet of the boiler, a condensate outlet formed on one side of the third compartment, and the second compartment A porous neutralizing agent made of a mixture of calcium oxide (CaO) and silicon (Si) and cured in an autoclave, the filter and activated carbon housed in a compartment, and the third compartment; It is characterized by consisting of a lid.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is an exploded perspective view according to an embodiment of the present invention, a cylindrical body 100 having a bottom surface closed and an open top surface is formed with a screw portion 13 on an outer circumferential surface thereof, and the screw portion 13. Below the condensate inlet 121 and the condensate discharge port 131 is formed, respectively. In addition, the inner surface is formed in the longitudinal direction in the vertical direction and the groove 15 is grooved in the longitudinal direction is formed.

The condensate inlet 121 is formed with a screw portion 14 that can be easily connected to the condensate outlet of the boiler, which is located inside the screw portion 14 so that it can be easily fixed by a tool such as a spanner during the pipe joint The outer circumferential surface is formed in the shape of hexagon nut.

In addition, although the condensed water discharged from the boiler flows into the body 100 through the condensed water inlet 121, the condensed water stored in the body 100 flows back to the boiler through the condensed water inlet 121. Check valve 50 is installed so as not to be.

The condensate discharge port 131 formed on the opposite side to the condensate inlet 121 is formed at a lower position than the condensate inlet 121 so that condensed water introduced through the condensate inlet 121 can be easily discharged, and foreign substances from the outside. Or it is bent downward so that rainwater does not flow. At this time, the condensate discharge port 131 may be connected to a separate hose or pipe so that the condensate stored in the body 100 can be easily discharged to the surrounding drain.

On the other hand, in the interior of the body 100, several supporting pieces 61 are protruded in the lower side and the perforated plate 60 in which a plurality of holes are formed is inserted and installed in the lower part of the body 100 as shown in FIG. The first compartment 110 is formed. At this time, the porous plate 60 is formed with a groove 62 so as not to interfere with the fitting portion 15, and is maintained at a constant height on the bottom surface of the body 100 by the support piece 61.

As shown in FIG. 3, the inner space of the body 100 formed on the porous plate 60 is installed by coupling the rectangular plate 70 through the fitting portion 15 to the upper portion of the porous plate 60. Separated into two compartments 120 and the third compartment (130). In this case, the filter 24 and the activated carbon 28 are accommodated in the second compartment 120, and the neutralizer 20 is accommodated in the third compartment 130.

After storing the activated carbon 28, the filter 24, and the neutralizer 20 in the second compartment 120 and the third compartment 130 formed in the body 100, the thread part formed on the upper outer circumferential surface of the body 100 ( 13, the lid 30 is fastened to form a purification device of a simple and miniaturized type as shown in FIG. When the purification device is assembled, the O-ring 40 is coupled between the lid 30 and the threaded portion 13 so that rain water does not penetrate through the opening of the upper portion of the body 100, and is assembled at the edge of the upper portion of the lid 30. The groove is formed at regular intervals so that it can be easily released and released by pressing the wrench when removing it.

The porous neutralizing agent 20 is made by curing a mixture of calcium oxide (CaO), silicon (Si) and magnesium oxide (MgO) at high temperature and high pressure in an autoclave. Thus formed neutralizing agent 20 has a number of hollows are formed because the weight is lighter than the volume, there is an advantage that does not lump even in contact with the condensate.

In addition, the porous neutralizing agent 20 has a merit that it is easy to replace and is not discharged to the outside together with condensate, unlike a conventional neutralizing agent in powder form. In addition, conventionally, because it is made of a powder form, the amount of outflow during natural drying and drying time is long rather than reused due to the disadvantages, but the porous neutralizing agent 20 is made of the hollows formed on its own smoothly inflow of air through a short time There is an advantage that can be easily reused by drying naturally because it is made in.

3 is a cross-sectional view showing a state of use according to an embodiment of the present invention, the body 100 inside the first plate 110 is formed below the porous plate 60 is installed on the porous plate 60 The second compartment 120 and the third compartment 130 are formed around the diaphragm 70.

The filter 24 and the activated carbon 28 are accommodated in the second compartment 120 formed on the left side of the diaphragm 70, and the porous neutralizer 20 is formed in the third compartment 130 formed on the right side of the diaphragm 70. ) Is housed. In addition, the upper outer peripheral surface of the second compartment 120 is formed with a condensate inlet 121 connected to the condensate outlet of the boiler, the condensate discharge port 131 is formed on the upper outer peripheral surface of the third compartment (130).

Therefore, when the acid condensate discharged from the boiler flows into the second compartment 120 through the check valve 50 connected to the condensate inlet 121, the third compartment 130 is formed by the diaphragm 70. After passing through the filter 24 and the activated carbon 28 sequentially, the first compartment 110 formed in the lower portion of the porous plate 60 is moved to the third compartment 130. In this process, the unburned powder contained in the condensate is removed by the filter 24 and the activated carbon 28 accommodated in the second compartment 120.

When the condensate continues to flow in and the level of the condensate stored in the first compartment 110 is increased, the condensate is filled into the second compartment 120 and the third compartment 130 and flows into the third compartment 130. The condensed water is discharged through the condensate discharge port 131. At this time, since the porous neutralizer 20 is accommodated in the third compartment 130, the condensed water from which unburned content is removed while passing through the second compartment 120 is neutralized in the third compartment 130.

Therefore, the acidic condensed water introduced through the condensate inlet 121 always passes through the second compartment 120 in which the filter 24 and the activated carbon 28 are stored, and then the third compartment in which the neutralizer 20 is stored. 130, only neutral condensed water from which unburned content is removed is discharged through the condensate discharge port 131.

As described above, according to the condensate purification device of the condensing boiler of the present invention, it is possible to reduce the weight of the neutralization device and increase the reaction efficiency with the condensate by using the neutralizing agent of the porous material. By removing the unburned powder there is an effect that can keep the surrounding rivers more clean.

In addition, since the neutralizing agent is formed in one solid phase unlike the prior art, it is easy to replace and can be reused by drying, and the industrial waste can be reduced by reprocessing and recycling the neutralizing agent which has reached the end of life unlike the conventional one.

Claims (1)

The upper surface is open and the perforated plate 60 and the diaphragm 70 are installed horizontally and vertically therein, so that a first compartment 110 is formed below the perforated plate 60 and borders the diaphragm 70. The body 100 is formed with the second compartment 120 and the third compartment 130, the condensate inlet 121 is formed on one side of the second compartment 120 and connected to the condensing outlet of the boiler, the second Condensate discharge port 131 is formed on one side of the three compartments 130, the filter 24 and the activated carbon 28, the third compartment 130 is accommodated in the second compartment 120 is stored in the calcium oxide ( Condensate purification of condensing boiler, characterized in that consisting of a porous neutralizing agent 20 made of a mixture of CaO) and silicon (Si) and curing in an autoclave, and a lid 30 coupled to the upper portion of the body 100 Device.