KR20150051698A - Waste heat recovery apparatus of home boiler - Google Patents

Abstract

The present invention relates to a waste heat recovery apparatus of household boilers and, more specifically, relates to a waste heat recovery apparatus of household boilers connected to a household boiler heating water using heat generated when burning a fuel; increases a temperature of air and water supplied inside by exchanging heat with waste heat supplied through one side as one side is connected with a stovepipe which discharges waste heat generated in combustion of the household boiler to the outside; and supplies a rise in temperature of air indoors and supplies a rise in temperature of water to the household boiler.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a waste heat recovery apparatus,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a waste heat recovery apparatus for a domestic boiler, and more particularly, to a waste heat recovery apparatus for a domestic boiler, in which waste heat generated during combustion of a domestic boiler is communicated to the outside, And the temperature of the water is raised by heat exchange between the water supplied to the inside of the waste heat recovering device and the waste heat, and the temperature of the water is increased to the domestic boiler To an apparatus for recovering waste heat of a domestic boiler, which is configured to supply warmed water.

Generally, a boiler is a combustion device for heating water for heating or hot water purposes, in which a flame generated in a lower burner heats water in a storage tank, hot water is sent to a use place by a pump, The exhaust gas is discharged to the outside through a conduit or a chimney.

At this time, since the exhaust gas is in a state of being heated by the heat generated during the combustion, discharging the exhaust gas having this heat to the outside without recycling causes waste of energy.

Therefore, although a large-sized boiler such as an industrial boiler is provided with a heat exchange unit for recovering heat contained in the exhaust gas, a small-scale apparatus such as a domestic boiler is not equipped with a heat exchange means and thus the waste heat contained in the exhaust gas can not be recovered .

In order to solve the above problems, an exhaust passage opened to both sides in the center is formed by an inner tube, a heat medium passage, which is closed at both ends by a flange, is formed on the outer periphery of the inner tube by an outer tube, A heat recovery unit unit in which a heat pipe unit is formed so as to communicate with another heat medium passage adjacent to the passage and a plurality of heat recovery unit units connected to each other by a flange formed respectively in the outer pipe and the right pipe pipe, A feature of which is disclosed in Patent Publication No. 10-0942012.

However, the above-described technique is not suitable for the heat transfer area where the waste heat generated in the boiler is transferred

The heat transfer efficiency is lowered.

Accordingly, there is a need for an apparatus for recovering waste heat of a domestic boiler that solves the above-described problems of the related art.

Patent Registration No. 10-0942012

SUMMARY OF THE INVENTION The present invention has been made in order to solve the problems of the related art as described above, and it is an object of the present invention to provide a heat exchanger, Thereby increasing the heat transfer efficiency and increasing the temperature of the water and air supplied to the inside of the waste heat recovery apparatus by using the waste heat to supply water and air with increased temperature to the domestic boiler and the room, The waste heat recovery device of the present invention.

In order to achieve the above-mentioned object, the present invention provides a fuel cell system for a fuel cell system, which is connected to a domestic boiler for heating water using heat generated during combustion of fuel, And is configured to increase the temperature of the air and water supplied to the inside by heat exchange with the waste heat supplied through the one side and supply the heated air to the inside of the room, Wherein the upper and lower portions are formed in an open shape, the space portion formed with a predetermined space is formed in the upper portion and the lower portion is formed in the lower portion, A waste heat receiving portion formed to be inclined downward so as to be narrowed inward; An air case formed in an inner side and having upper and lower sides and left and right openings formed in the inner side, and an air case which is inserted into the upper and lower portions of the air case respectively and has a wave shape symmetrical from one side to the other side, And a plurality of first airbag grooves formed in the airbag cover in a vertical direction between the airbag covers, the first airbag grooves being fitted to the first airbag grooves, A first wave plate having a shape symmetrically shaped from one side to the other so as to correspond to the first through grooves, and a second wave plate coupled to the open right side of the air case and having a plurality of through holes formed therein, And the air is supplied to the inside of the air case by being dispersedly supplied to the air case, A filter which is provided on the inside of the supply unit and removes foreign matter contained in the air supplied from the outside, A blowing fan provided between the filter and the air case for allowing the external air to be smoothly supplied to the inside of the air case, and a blowing fan provided on the opened left side of the air case, An air supply unit for supplying air having a temperature raised to the inside of the air case through heat exchange with the waste heat while passing through the inside of the air case through the inside of the air case, and a plurality of multi- A water case having a predetermined space formed inside and having an upper portion and a lower portion, And a plurality of second through grooves penetrating through the water case in a symmetrical shape from one side to the other side are formed on the inner side of each of the upper and lower portions of the water case, And a plurality of water holes are formed between the water case lids so as to be perpendicular to the water case lids between the water case lids and the water case lids, respectively, so that water is passed through from one end to the other A second wave plate having a shape in which a waveform is symmetrically formed from one side to the other side corresponding to the second through grooves, and a second wave plate which is connected to one side of the upper part in which the water case is stacked in multiple stages A water inflow section that receives water from the outside and supplies water to the inside of the water case; A water supply unit connected to a lower side of the water case for supplying heat to the domestic boiler, the water being heat-exchanged with the waste heat from the inside of the multi-stage water case; And a discharge part formed in the inside so as to discharge the waste heat to the outside.

In the waste heat recovering apparatus of the domestic boiler according to the present invention, the heat transfer efficiency of the waste heat recovering apparatus has been reduced by effectively using a plurality of first and second wave plates formed of a simple structure, It is possible to reuse the waste heat by supplying warm water and air to the inside of the waste heat recovery apparatus effectively by using the waste heat of high temperature and supplying it to the domestic boiler and the room and to simply install So that the installation is simple, but the cost and time required for installation can be saved.

1 is a sectional view of a waste heat recovery apparatus for a domestic boiler according to the present invention,
2 is a sectional view of a waste heat recovery apparatus for a domestic boiler according to the present invention,
3 is a partial cross-sectional perspective view of a waste heat recovery apparatus for a domestic boiler according to the present invention,
4 is a partial perspective view of a waste heat recovery apparatus for a domestic boiler according to the present invention,
5 is a partially exploded perspective view of a waste heat recovery apparatus for a domestic boiler according to the present invention,
6 is a partial perspective view of a waste heat recovery apparatus for a domestic boiler according to the present invention.
7 is a partially exploded perspective view of a waste heat recovery apparatus for a domestic boiler according to the present invention,
8 is a partially exploded perspective view of a waste heat recovery apparatus for a domestic boiler according to the present invention,
9 is a sectional view of the water separator according to the present invention,
10 is a perspective view of a dispersion plate according to the present invention.

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

1 to 10, a waste heat recovery apparatus for a domestic boiler according to the present invention is connected to a domestic boiler 4 that heats water using heat generated during combustion of fuel, The temperature of the air and water supplied to the inside is increased by heat exchange between the communication tube 10 for discharging the waste heat generated at the outside and the waste heat supplied through one side connected to one side, (10) is connected to one side to supply waste heat from the communication pipe (10) to the waste heat receiving unit An air case 30 having a predetermined space formed in the upper part of the waste heat receiving part 20 and an inner case 30 inserted in the upper and lower parts of the air case 30, A first wave plate 36 having a plurality of vertically arranged air case lids 34 between the air case lids 34 and the air case lids 34, A feeder 40 coupled to the right side of the air case 30 and a filter 42 disposed inside the feeder 40. The feeder 40 is connected to the feeder 40, A blowing fan 44 provided inside the supply part 40 and provided between the filter 42 and the air case 30 and an air supply part 40 provided on the opened left side of the air case 30, A water case 60 provided in an upper portion of the air case 30 and having a plurality of multi-layered layers stacked on the upper and lower portions of the water case 60, A water case cover 66 is provided between the water case cover 66 and the water case cover 66, A water inflow part 70 connected to one side of the upper part where the water case 60 is stacked in multiple stages and a water inlet part 70 connected to the water case 60 in a multi- And a discharge unit 80 provided at an upper portion of the water case 60 and formed to penetrate through the water case 60 to discharge the waste heat to the outside, .

First, a communication pipe 10 to which one side is connected to the domestic boiler 4 is provided.

At this time, the communication pipe 10 is connected to the domestic boiler 4 at one side to supply high-temperature waste heat discharged at the time of operation of the domestic boiler 4 to the waste heat receiving unit 20 to be described later .

The communication unit 10 is connected to one side to receive waste heat from the communication pipe 10, and the upper and lower portions are formed as openings. The space portion 22 having a predetermined space is formed inside, And a waste heat receiving portion 20 formed to be inclined downward so as to be narrowed inward while being extended.

At this time, the water contained in the waste heat of the domestic boiler 4 is introduced into the lower part of the waste heat receiving part 20 through the air case 30 to be described later and the first wave plate 36 provided inside the water case 60, And a water recovery pipe 28 for discharging the water that has been condensed by the heat exchange with the cold air and water when passing through the two-wave plate 68.

In addition, a dispersion opening 26 having a plurality of dispersion holes 24 is provided inside the upper portion of the waste heat receiving portion 20 such that the waste heat supplied to the waste heat receiving portion 20 is uniformly dispersed upward.

At this time, the dispersing holes 26 formed in the top of the dispersing holes 26 are formed such that the waste heat is uniformly dispersed in the upper portion of the dispersing holes 26 And the dispersion holes 24 formed in the lower part of the dispersion port 26 are formed such that the water introduced from the upper part is easily collected at the lower part of the waste heat receiving part 20 and discharged through the water recovery pipe 28 .

Meanwhile, the dispersion port 26 is preferably formed in a trapezoidal shape. However, the dispersion port 26 may be any shape as long as it is capable of distributing the exhaust gas evenly while discharging the water downward.

An air case 30 is formed in the upper part of the waste heat receiving part 20 and has a predetermined space formed inside, and the upper case, the lower case, and the left case are open.

At this time, the upper and lower portions of the air case 30 are inserted inward, respectively, and a plurality of first through grooves 32, which are penetrated in a symmetrical shape from one side to the other side, A plurality of air case lids 34 are vertically formed between the air case lids 34 and are fitted into the first through grooves 32. Each of the air case lids 34 has a first And a first wave plate 36 having a symmetrical waveform from one side to the other side corresponding to the through grooves 32 is provided.

In this case, each of the first wave plates 36 is preferably formed to have a thickness of 1 to 4 mm, and when the thickness of each of the first wave plates 36 is less than 1 mm, the strength is weak, When the first wave plate 36 is formed to have a thickness of 4 mm or more, the heat exchange between the waste heat and the air is not efficient .

In addition, the first wave plate 36 is formed in a waveform so as to efficiently increase the heat transfer area in a small space.

It is preferable that the air case 30, the air case lid 34 and the first wave plate 36 are made of stainless steel which is not corroded.

A plurality of through holes formed in the inner side of the air case 30 to distribute the air supplied from the outside to the inside of the air case 30, (Not shown).

At this time, the dispersion plate 38 serves to uniformly distribute the air to the first wave plate 36 provided inside the air case 30, and distributes the air evenly to the inside of the air case 30 The heat transfer area with the waste heat is formed to be wide, so that the heat exchange efficiency is increased.

And a supply unit 40 which is coupled to the right side of the air case 30 and penetrates the inside of the air case 30 to supply air from the outside to the inside of the air case.

A filter 42 is provided inside the supply part 40 to remove foreign substances contained in the air supplied from the outside and air is introduced into the air case 30 between the filter 42 and the air case 30. [ The air blowing fan 44 is provided so as to be smoothly supplied to the inside of the casing.

At this time, the blowing fan 44 is supplied to the inside of the air case 30 so that the air, which is heat-exchanged with the waste heat, is supplied to the room through the air supply unit 50 described later, The air blowing fan 44 is provided with a switch or the like not shown to adjust the rotation speed of the on / off or blowing fan 44 according to the user's selection, It is preferable to adjust the amount of the liquid.

The filter 42 is provided to prevent minute dust or the like contained in the air from entering the inside of the air case 30. The filter 42 is formed of a mesh net structure and the gap of the filter net is 1 to 10 mm. .

The air is passed through the inside of the air case 30 to be heat-exchanged with the waste heat, so that the temperature of the air is increased. And an air supply unit 50 for supplying air into the room.

In addition, a filter unit 100 formed by supporting 0.1-5 wt% of silver in the form of nanoparticles on the basis of the total weight of the activated carbon is coupled to the open left side of the air case 30.

At this time, the filter unit 100 primarily serves to remove foreign matter or odor contained in the air before the air, from which foreign substances or the like are removed, is supplied to the room by the filter 42, In order to reinforce the problem of replacing the filter unit 100 when the function of the activated carbon is degraded when the filter 100 is formed only of activated carbon, activated carbon is supported on the semi-spherical and highly functional nanoparticle silver, And the life of the filter unit 100 is increased.

A water case 60 having a plurality of openings is formed at an upper portion of the air case 30, and a predetermined space is formed inside the openings.

At this time, the water case (60) receives waste heat from the air case (30).

On the other hand, a plurality of second through grooves 62 penetrating through the water case 60 in a symmetrical shape from one side to the other are formed on the inside of each of the upper and lower portions of the water case 60 And a water-case cover 66 of a flat plate type in which a circulation hole 64 is formed so as to be symmetric with respect to one side and the other side in a staggered manner so as to allow the water to pass from the upper side to the lower side for each of the stacked multi- A plurality of water case covers 66 are vertically formed between the water case covers 66 so as to be fitted into the second through grooves 62. Each of the water case covers 66 is provided at one side And a second wave plate 68 having a shape in which the waveforms are symmetrical to each other.

In this case, each of the second wave plates 68 preferably has a thickness of 1 to 4 mm. When the thickness of each of the second wave plates 68 is less than 1 mm, the strength is weak, When the second wave plate 68 is formed to have a thickness of 4 mm or more, heat exchange is performed between the waste heat and the second wave plate 68. In this case, There is a problem that the heat exchange between the water and the water is not efficient.

In addition, the second wave plate 68 is formed in a waveform so as to efficiently increase the heat transfer area in a small space.

It is preferable that the water case 60, the water case cover 66, and the second wave plate 68 are made of stainless steel which is not corroded.

A water inlet portion 70 connected to one side of the upper portion of the water case 60 stacked in multiple stages and supplied with water from the outside and supplying water to the inside of the water case 60 is provided.

At this time, the water flowing through the water inflow section 70 is heat-exchanged with the waste heat through the second wave plate 68 through the second wave plate 68 provided inside the water case 60, And is moved downward along a circulation hole 64 that is symmetrically passed through one side and the other side in a staggered manner so as to allow water to pass between the multi-stage watercases 60.

The water tank 60 is connected to one side of a lower portion of the multi-stage stacked water case 60, and water, which is heat-exchanged with the waste heat inside the multi- A supply section 72 is provided.

And a discharge unit 80 provided at an upper portion of the water case 60 and formed so as to pass through the water case 60 to discharge the waste heat to the outside.

And a plurality of water separating openings 92, which are formed in a plate shape on the inside and have a zigzag shape in the upward direction, are spaced apart from each other, A separator 90 is provided at each of the upper ends of the separating openings 92, each of which is provided with a cut-off opening 94 bent downward.

At this time, the water separator (90) is provided so that water contained in the waste heat is condensed and flows to the lower part. When the water contained in the waste heat flows downward, condensation of the waste heat not yet condensed is further activated, Thereby preventing the occurrence of the white smoke phenomenon.

The waste heat recovering device 2 of the domestic boiler according to the present invention has a structure in which the heat transfer efficiency of the conventional waste heat recovering device is lower than that of the first and second wave plates 36, 68 is used to efficiently increase the heat transfer area so that the temperature of the water and the air supplied to the inside of the waste heat recovery apparatus 2 is effectively raised by using the waste heat of high temperature and supplied to the domestic boiler 4 and the room, And can be installed simply by being connected to the existing domestic boiler 4 and the communication pipe 10, so that the installation is simple and the cost and time required for the installation can be saved.

2: waste heat recovery device 4: household boiler
10: communication 20: waste heat receiving part
30: air case 36: first wave plate
40: supply part 50: air supply part
60: Water case 68: 2nd wave plate
70: Water inflow part 72: Water supply part
80: discharge part 90: water separator
100:

Claims (7)

(10) connected to a domestic boiler (4) for heating water by using heat generated by combustion of fuel and discharging the waste heat generated in the combustion of the domestic boiler (4) to the outside, The boiler 4 is configured to supply the heated water to the indoor boiler 4 by supplying the heated air to the indoor, In the waste heat recovering apparatus,
The communication unit 10 is connected to one side to receive waste heat from the communication pipe 10, and the upper and lower portions are formed as openings. The space portion 22 having a predetermined space is formed inside, A waste heat receiving portion 20 formed to extend downward so as to be narrowed inward while being extended;
An air case 30 having a predetermined space formed in the upper part of the waste heat receiving part 20 and having upper, lower, left and right openings;
And a plurality of first through grooves 32 inserted into the upper and lower portions of the air case 30, respectively, and each of which has a plurality of first through grooves 32 penetrating in a symmetrical shape from one side to the other side, An air case cover 34;
A plurality of airbag covers 34 are vertically formed between the airbag covers 34 so as to be fitted into the first through holes 32. Each of the airbag covers 34 is provided at one side A first wave plate 36 having a waveform symmetrical to the other wave plate;
A plurality of through holes formed in the inner side of the air case 30 to distribute the air supplied from the outside to the inside of the air case 30, (38);
A supply part 40 which is coupled to the right side of the air case 30 and penetrates the inside of the air case 30 to supply air from the outside to the inside of the air case;
A filter (42) provided inside the supply part (40) for removing foreign substances contained in the air supplied from the outside;
A blowing fan 44 provided between the filter 42 and the air case 30 to smoothly supply the outside air to the inside of the air case 30;
The air is passed through the inside of the air case 30 to be heat-exchanged with the waste heat, so that the temperature of the air is increased. An air supply unit 50 for supplying air into the room;
A water case 60 in which a plurality of airbags are stacked at an upper portion of the air case 30, and a predetermined space is formed inside the airbaths 30, and upper and lower portions are formed in an open shape;
A plurality of second through grooves 62 penetrating through the water case 60 in a symmetrical manner from one side to the other side are formed on the inner side of each of the upper and lower portions of the water case 60, A waterproof case cover 66 of a flat plate type in which a circulation hole 64 is formed in a staggered manner so as to be symmetrical to one side and the other side so as to allow water to pass from the top to the bottom of each stacked multi-
A plurality of water case covers 66 are vertically formed between the water case covers 66 and are fitted into the second through grooves 62. Each of the water case covers 66 has one side A second wave plate 68 having a waveform symmetrical to the other wave plate;
A water inflow part 70 connected to one side of the upper part of the water case 60 stacked in multiple stages and supplied with water from the outside and supplying water to the inside of the water case 60;
The water tank 60 is connected to one side of a lower portion of the multi-stage stacked water case 60, and water, which is heat-exchanged with the waste heat inside the multi- A supply unit 72;
And a discharge unit (80) installed at the upper part of the water case (60) and formed so as to pass through the water case (60) to discharge the waste heat to the outside. The method according to claim 1,
And a plurality of water separating openings 92, which are formed in a plate shape on the inside and have a zigzag shape in an upward direction, are spaced apart from each other, And a water separator (90) having a cut-off hole (94) formed at the upper end of each of the separating openings (92) so as to be bent downward. The method according to claim 1,
Dispersing holes 26 having a plurality of dispersing holes 24 inserted in the upper portion of the waste heat receiving portion 20 and arranged so that the waste heat supplied to the waste heat receiving portion 20 is uniformly dispersed upward, Wherein the boiler is a boiler. The method according to claim 1,
Wherein each of the first wave plate (36) and the second wave plate (68) has a thickness of 1 to 4 mm. The method according to claim 1,
Wherein a water recovery pipe (28) is formed at a lower portion of the waste heat receiving portion (20) to condense the water contained in the waste heat and discharge the introduced water. The method according to claim 1,
Wherein the filter (42) is formed in a mesh net structure, and the filter net has a gap of 1 to 10 mm. The method according to claim 1,
And a filter unit (100) coupled to the open left side of the air case (30), the filter unit being formed by supporting 0.1-5 wt% of silver in the nanoparticle state on the total weight of activated carbon. Waste heat recovery system of boiler.

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