KR20160018036A - Heat Exchange and Dust Collector - Google Patents

Abstract

Provided is a dust collector combined with a heat exchanger, which comprises: a main body having a cylindrical shape and having a first flow path and a second flow path installed to be disposed respectively at both sides of a twister-shaped heat transfer barrier inside; a first end-inlet installed on one end of the main body to introduce fluid into the first flow path; a first end-outlet installed on one end of the main body to discharge the fluid from the inside of the second flow path; a second end-inlet installed on the other end of the main body to introduce fluid into the second flow path; a second end-outlet installed on the other end of the main body to discharge the fluid from the inside of the first flow path; a first transfer fan installed to transfer the fluid via the first flow path; a second transfer fan installed to transfer the fluid via the second flow path; and a centrifugal dust collector installed to use centrifugal force to remove foreign substances from the fluid for purification, which is transferred through the first flow path or the second flow path, wherein heat can be exchanged between the fluids passing through the two flow paths and foreign substances can be removed from the fluid to enable energy saving and air purification.

Description

[0001] Heat Exchange and Dust Collector [

The present invention relates to a heat exchange dust collector, and more particularly, to a heat exchange dust collector capable of performing heat exchange and collecting foreign matter.

In general, heat exchange refers to the transfer of heat from one object to another, and the device for performing heat exchange is referred to as a heat exchanger.

The heat exchanger is installed to exchange heat between two fluids, i.e., liquid and liquid, liquid and gas, and gas, and is used for various purposes such as recovery of waste heat, cooling and heating.

Recently, as the concern about depletion of fossil energy has increased, technology development related to energy saving has become very important. Therefore, technology for recovering waste heat using heat exchanger has been actively developed as one method for energy saving ought.

Patent Publication No. 0764730 discloses a technique for recovering waste heat during ventilation of air.

In the waste heat recovery ventilator using the cyclone dust collector, the air supply duct for supplying the outdoor air sucked through the air supply fan to the room, and the indoor air sucked through the ventilation fan for exhaust are discharged to the outside A body in which an exhaust duct is partitioned by a partition wall; A heat exchanger for performing heat exchange between outdoor air and indoor air introduced into the main body; An air supply cyclone dust collecting unit installed in the air supply fan for supplying air to the air supply fan for generating a centrifugal force in the outdoor air to separate contaminants and clean air; A first dust discharge pipe communicating between the air supply cyclone dust collecting unit and the exhaust duct so that the pollutants separated from the air supply cyclone dust collecting unit are discharged to the outside through the exhaust duct; And a supply duct communicating between the supply cyclone dust collecting unit and the supply fan for supplying the clean air separated from the supply cyclone dust collecting unit to the supply fan for the supply fan.

When the length of the waste heat recovery ventilator flow path using the conventional cyclone dust collector constructed as described above is prolonged, the installation length or the installation area occupies a large amount.

Frictional resistance is generated when the air is moved, so that there is a problem that the amount of intake air and the amount of exhaust are easily lowered.

SUMMARY OF THE INVENTION The present invention has been made in view of the above points, and it is an object of the present invention to provide an air conditioner which has a pair of flow paths formed on opposite sides of a whirl-shaped partition wall, Which is capable of reducing the amount of air supplied to the heat exchanger, thereby improving the airflow amount.

The heat exchange dust collector proposed by the present invention comprises a body having a tubular shape and having a first flow path and a second flow path with a whirl-shaped heat transfer partition wall interposed therebetween, A first end outlet installed to discharge a fluid from the inside of the second flow path at one end of the body, and a second end outlet installed at the other end of the body for discharging fluid, A second end outlet provided to discharge fluid from the inside of the first flow path at the other end of the body, and a second end outlet provided to discharge fluid from the inside of the first flow path, A second conveying fan installed to convey the fluid through the second flow path, and a second conveying fan that is provided to convey the fluid to the first flow path or the second flow path, Being It comprise a centrifugal precipitator of the foreign substances contained in the body, which is installed to purify by using the centrifugal force.

The heat exchange dust collector proposed by the present invention comprises a first body in which a first flow path and a second flow path are respectively installed with a whirl-shaped heat transfer partition wall interposed therebetween, and a second body A first end outlet installed to discharge the fluid from the inside of the second flow path of the first body at one end of the body, A second body in which a first flow path and a second flow path are provided with a whirl-shaped heat transfer partition wall interposed therebetween, one end face of which faces the other end face of the first body and is connected to the other end face, A second end inlet installed at the other end of the body for introducing fluid into the first flow path of the second body and a second end inlet for introducing fluid into the second flow path from the other end of the body. A first communication port connecting the first flow path of the first body to the first flow path of the second body and a second communication path connecting the second flow path of the first body to the second flow path of the second body, A first communicating port, a first conveying fan installed to convey the fluid through the first passage of the first body and the second body, and a second conveying fan installed between the first passage and the second passage, And a centrifugal precipitator installed to purify foreign matter contained in the fluid transferred to the first flow path or the second flow path by centrifugal force.

Wherein the centrifugal dust collector has a cylindrical shape having a lower end surface opened and has a lower inflow end into which a fluid is introduced and an upper end of which is formed a discharge port through which foreign substances centrifuged from the inflow fluid are discharged, A foreign matter collecting unit installed on a lower end surface of the chamber and configured to induce a vortex of a fluid flowing into the chamber through a lower end surface of the chamber, And an intake passage formed in the shape of a pipe, one end of which is connected to the first flow path or the second flow path and the other end of which is disposed inside the chamber As shown in Fig.

The centrifugal dust collector may further include a discharge induction propeller installed inside the chamber and discharging the foreign matter to the discharge port while disturbing the foreign matter as it is rotated by the air flow of the fluid.

According to the heat exchanging dust collector according to the embodiment of the present invention, since the pair of flow paths are formed on both sides with the whirl-shaped partition walls interposed therebetween, the flow path can be formed longer than the installation area, And it is possible to improve the airflow amount by reducing the frictional resistance at the time of transferring the air.

According to the heat exchanging dust collector according to the embodiment of the present invention, it is possible to remove foreign matter from the air introduced by using the centrifugal separator, so that it is possible to purify the air simultaneously with the heat exchange.

Further, according to the heat exchange dust collector according to the embodiment of the present invention, since the propeller installed in the chamber of the centrifugal separator disturbs the floating foreign matter and forms the air flow so as to be discharged to the discharge port, foreign substances are not stagnated or accumulated in the chamber, So that the filtration efficiency can be improved.

1 is a perspective view showing a heat exchange dust collector according to a first embodiment of the present invention.
2 is a front view showing a heat exchange dust collector according to a first embodiment of the present invention.
3 is a side sectional view showing a heat exchange dust collector according to a first embodiment of the present invention.
4 is a sectional view taken along the line AA in Fig.
5 is an exploded perspective view showing a centrifugal separator in the heat exchange dust collector according to the first embodiment of the present invention.
6 is an assembled cross-sectional view illustrating a centrifugal separator in the heat exchange dust collector according to the first embodiment of the present invention.
7 is a plan sectional view showing a collecting cylinder of a centrifugal cleaner in the heat exchange dust collector according to the first embodiment of the present invention.
8 is a perspective view showing an interferer of the centrifugal separator in the heat exchange dust collector according to the first embodiment of the present invention.
9 is a plan sectional view showing an inlet guide of the centrifugal separator in the heat exchange dust collector according to the first embodiment of the present invention.
10 is a side sectional view showing a discharge induction propeller of a centrifugal cleaner in a heat exchange dust collector according to a first embodiment of the present invention.
11 is a perspective view showing a heat exchange dust collector according to a second embodiment of the present invention.
12 is a front view showing a heat exchange dust collector according to a second embodiment of the present invention.
13 is a side sectional view showing a heat exchange dust collector according to a second embodiment of the present invention.
14 is a sectional view taken along line BB of Fig.
15 is a cross-sectional view taken along line CC of Fig.

Next, a preferred embodiment of a heat exchange dust collector according to the present invention will be described in detail with reference to the drawings.

In the following description, the same reference numerals are used for the same technical elements, and detailed descriptions for avoiding redundant description are omitted.

The embodiments described below are intended to illustrate the preferred embodiments of the present invention in an effective manner and should not be construed to limit the scope of the present invention.

1 to 5, the heat exchanging dust collector according to the first embodiment of the present invention includes a body 10, a first end inlet 20, a first end outlet 30, a second end inlet 40, A second end outlet 50, a first conveying fan 60, a second conveying fan 70, and a centrifugal separator 80.

The body 10 has a substantially cylindrical shape.

A first flow path 11 and a second flow path 12 are respectively installed in the body 10 with a heat transfer partition wall 13 intervening between them.

The internal space of the body 10 is partitioned into the first flow path and the second flow path through the heat transfer barrier 13 so that air flowing through the first flow path 11 and the second flow path 12 And the like are transferred in the form of a whirl (spiral or vortex).

The heat transfer barrier ribs 13 are made of a metal material so as to have a good thermal conductivity.

That is, the heat transfer barrier rib 13 is connected to the fluid to be transferred to the first flow path 11 and the second flow path 12 as the fluid such as air is transferred through the first flow path 11 and the second flow path 12 And is made of a material capable of rapid heat exchange between the fluids to be transferred.

As the material of the heat transfer barrier 13, copper, aluminum, synthetic resin, or the like can be used.

The first end inlet 20 is installed to introduce fluid from one end of the body 10 into the first flow path 11.

The first end outlet 30 is installed to discharge fluid from the inside of the second flow path 12 at one end of the body 10.

The second end inlet (40) is installed to introduce fluid from the other end of the body (10) into the second flow path (12).

The second end outlet (50) is installed to discharge fluid from the inside of the first flow path (12) at the other end of the body (10).

The first end outlet 30, the second end inlet 40 and the second end outlet 50 are provided as described above, the fluid to be delivered to the first flow path 11, The fluids transferred to the second flow path 12 are transferred in opposite directions to perform heat exchange.

The first transfer fan (60) is installed to transfer the fluid through the first flow path (11).

The first conveying fan 60 is formed using a blower or the like and installed at the first end inlet 20 or the second end outlet 50.

The second transfer fan (70) is installed to transfer the fluid through the second flow path (12).

The second conveying fan 70 is formed using a blower or the like and installed at the second end inlet 40 or the first end outlet 30.

The centrifugal dust collector 80 is installed to purify the foreign substances contained in the fluid transferred to the first flow path 11 or the second flow path 12 by centrifugal force.

The centrifugal dust collector 80 is installed at the inlet of the first flow path 11 or the inlet of the second flow path 12.

That is, the centrifugal dust collector 80 is connected to the first end inlet 20 or the second end inlet 40.

5 to 7, the centrifugal dust collector 80 includes a chamber 81, a foreign matter collecting portion 83, an inlet guide 86, an intake pipe 88, and a discharge induction propeller 90 .

The chamber 81 is formed in a cylindrical shape with a lower end surface thereof opened. A fluid is introduced into the lower end surface of the chamber 81, and an outlet 82 is formed at the upper end of the chamber 81 to discharge foreign substances centrifugally separated from the fluid.

The discharge port 82 is formed at a plurality of locations around the upper end portion and the upper end surface of the chamber 81 at regular intervals.

The foreign matter collecting unit 83 is installed to form a space for collecting foreign matter discharged to the discharge port 82 along the outer circumferential periphery of the chamber 81.

The foreign matter collecting unit 83 is installed in a substantially cylindrical shape.

It is also possible that an interfering body 84 is provided inside the foreign matter collecting part 83 to interfere with the foreign matter 2 flowing and obstruct the flow of the foreign matter 2 by the air current.

As shown in FIG. 8, the interfering body 84 is formed by using a perforated plate and is formed in a substantially wavy shape along the inner circumference of the foreign matter collecting part 83.

The interfering body 84 may be made of any one of a mesh net, a fiber, a porous body, a foamed resin, a foamed metal, a nonwoven fabric, and a paper.

The interfering body 84 may be formed in a zigzag shape along the inner circumference of the foreign matter collecting part 83.

The inlet guide 85 has a substantially cylindrical shape and is installed on the lower end surface side of the chamber 81 and has a plurality of A vortex inducing vane 86 is installed.

As shown in FIG. 9, the inlet guide 85 has a hollow cylindrical shape, and a plurality of vanes 86 formed in a rod-like shape are installed at regular intervals along the circumferential direction, An inflow space 86a is formed so that the inflow of the external gas is performed.

The upper end of the inlet guide 85 is connected to the lower end of the chamber 81.

The wings 86 can be formed to be elongated in the diagonal direction so that the external gas can flow more naturally through the inflow space 86a between the blades 86 and the blades 86 .

The inflow space 86a between the blades 86 and the blades 86 is elongated obliquely by providing the blades 86 obliquely so that the gas flowing into the inflow space 86a It is possible to increase the inflow amount of the gas and to effectively perform the centrifugal separation of the foreign matter 2 since it induces the spiral movement (vortex phenomenon) while flowing in the oblique direction.

The intake pipe 88 is formed in a pipe shape and forms an intake passage and has one end connected to the first flow path 11 or the second flow path 12 and the other end connected to the inside of the chamber 81 As shown in FIG.

The intake tube 88 is installed along the center axis of the intake guide 85.

And a bottom plate 87 through which the intake pipe 88 penetrates may be installed at the center of the inlet guide 85. [

The lower end of the chamber 81 may be provided with a cylindrical bracket 81a extending around the side surface of the inflow guide 85 at a predetermined interval.

10, the discharge induction propeller 90 is installed inside the chamber 81 and discharges the foreign matter 2 to the discharge port 82 while disturbing the foreign matter 2 as it is rotated by the air flow of the fluid.

The discharge inducing propeller 90 is provided with a plurality of the discharge inducing vanes 91 at regular intervals along the circumferential direction and is rotatable around the center axis of the chamber 81.

The shaft 92 is installed on the discharge inducing propeller 90 so that the center is rotatably engaged with the chamber 81 or the foreign matter collecting part 82.

11 to 15, the heat exchanging dust collector according to the second embodiment of the present invention includes a first body 10a, a first end inlet 20, a first end outlet 30, The second communication port 52, the first conveying fan 60, the second conveying port 51, the second conveying passage 51, the second conveying passage 52, the first conveying fan 60, the second body 10b, the second end inlet 40, the second end outlet 50, A fan 70 and a centrifugal dust collector 80.

The first body 10a has a substantially cylindrical shape, and a first flow path 11 and a second flow path 12 are respectively installed in the inside of the first body 10a with a whirl-shaped heat transfer barrier 13 interposed therebetween.

The internal space of the first body 10a is partitioned into the first flow path 11 and the second flow path 12 through the heat transfer barrier 13, The fluid, such as air, to be transported through the nozzle 12 is transferred in the form of a whirl (spiral or vortex).

The first end inlet 20 is installed at one end of the first body 10a to introduce fluid into the first flow path 11 of the first body 10a.

The first end outlet 30 is installed at one end of the first body 10a to discharge fluid from the inside of the second flow path 12 of the first body 10a.

remind The second body 10b has a substantially cylindrical shape and is provided with a first flow path 11 and a second flow path 12 so as to overlap with each other with a whirl-shaped heat transfer barrier 13 interposed therebetween, And faces the other end surface of the first body 10a.

The second end inlet 40 is installed to introduce fluid into the first flow path 11 of the second body 10b from the other end of the second body 10b.

The second end outlet 50 is installed to introduce fluid into the second flow path 12 from the other end of the second body 10b.

The first communication hole 51 connects the first flow path 11 of the first body 10a and the first flow path 11 of the second body 10b to communicate with each other.

The second communication port 52 connects the second flow path 12 of the first body 10a and the second flow path 12 of the second body 10b to communicate with each other.

The fluid introduced into the first end inlet 20 passes through the first communication hole 51 through the first flow path 11 of the first body 10a and then flows into the second end 10b of the second body 10b, And then discharged through the first flow path 11 to the second end outlet 30.

The fluid flowing into the second end inlet 50 passes through the second communication hole 52 through the second flow path 12 of the second body 10b and flows into the first end of the first body 10a Is discharged through the second flow path (12) to the first end outlet (30).

As described above, the first body 10a and the first end inlet 20, the first end outlet 30, the second body 10b, the second end inlet 40, the second end outlet 50, It is possible to improve the heat exchange performance while extending the lengths of the first flow path 11, the second flow path 12 and the heat transfer barrier 13 by providing the one communication hole 51 and the second communication hole 52 .

The first transfer fan 60 is installed to transfer fluid such as air through the first flow paths 11 and 12 of the first and second bodies 10a and 10b.

The second transfer fan 70 is installed to transfer fluid such as air through the first and second bodies 10a and 10b.

The first transfer fan (60) may be installed at the first end inlet (20) and / or the second end outlet (40).

The first transfer fan (60) can be additionally installed in the first communication hole (51)

The second conveying fan 70 may be installed at the second end inlet 50 or the first end outlet 30.

The second transfer fan (70) may be additionally installed in the second communication port (52).

The centrifugal dust collector 80 is installed to purify the foreign substances contained in the fluid transferred to the first flow path 11 or the second flow path 12 by centrifugal force.

The first end inlet 20, the first end outlet 30, The configuration of the second end inlet 40, the second end outlet 50, the first conveying fan 60, the second conveying fan 70, and the centrifugal cleaner 80 is the same as that of the first embodiment And therefore detailed description thereof will be omitted.

The heat-exchanging dust collector according to the embodiment of the present invention can be used as a ventilator in buildings such as factories, offices, homes, etc. In this case, efficient energy can be utilized while preventing waste of heat energy.

As shown in Figs. 2, 4, 12, 14 and 15, cold air (indicated by a dashed arrow in the figure) is transferred to the outdoor side to the first flow path 11, The indoor air and the outdoor air are heat-exchanged with each other through the heat-conductive partition wall, so that heat is recovered from the air discharged from the room to the outside and recovered It is possible to raise the temperature of the air introduced from the outside by the heat.

In the heat exchange dust collector according to the embodiment of the present invention configured as described above, the foreign substances contained in the air can be removed by the centrifugal dust collector 80, so that the contaminated air can be purified.

That is, when the outdoor air flows into the room through the first flow path (or the second flow path), clean air can be introduced into the room by removing the foreign substances from the outdoor air, so that a pleasant indoor environment can be maintained.

10: Body 10a: First Body
10b: second body 20: first end inlet
30: first end outlet 40: second end inlet
50: second end outlet 60: first feed fan
70: Second conveying fan 80: Centrifuge
81: chamber 82: outlet
83: foreign matter collecting part 84:
85: inlet guide 88: intake pipe
90: discharge inducing propeller

Claims (4)

A body in which a first flow path and a second flow path are provided, respectively, with a thermal conductive partition wall in the form of a whirl,
A first end inlet installed at one end of the body for introducing fluid into the first flow path,
A first end outlet installed at one end of the body to discharge fluid from the interior of the second flow path,
A second end inlet installed at the other end of the body for introducing fluid into the interior of the second flow path,
A second end outlet installed at the other end of the body to discharge fluid from the interior of the first flow path,
A first transfer fan installed to transfer the fluid through the first flow path,
A second transfer fan installed to transfer the fluid through the second flow path,
And a centrifugal precipitator installed to purify foreign matter contained in the fluid transferred to the first flow path or the second flow path by centrifugal force. A first body in which a first flow path and a second flow path are installed, respectively, with a thermal conductive partition wall in the form of a whirl,
A first end inlet installed at one end of the first body to introduce fluid into the first passage of the first body,
A first end outlet installed at one end of the body to discharge fluid from the second flow path of the first body,
And a first flow path and a second flow path are respectively installed in the inside of the body and a whirl-shaped heat transfer partition wall is interposed therebetween, and one end face faces the other end face of the first body and is connected A second body,
A second end inlet installed at the other end of the second body for introducing fluid into the first channel of the second body,
A second end outlet installed to introduce fluid into the second flow path from the other end of the body,
A first communication port connecting the first flow path of the first body and the first flow path of the second body,
A second communication port connecting the second flow path of the first body and the second flow path of the second body,
A first transfer fan installed to transfer the fluid through the first flow path of the first body and the second body,
A second transfer fan installed to transfer the fluid through the second flow path of the first body and the second body,
And a centrifugal precipitator installed to purify foreign matter contained in the fluid transferred to the first flow path or the second flow path by centrifugal force. The method according to claim 1 or 2,
Wherein the centrifugal dust collector has a cylindrical shape having a lower end surface opened and has a lower inflow end into which a fluid is introduced and an upper end of which is formed a discharge port through which foreign substances centrifuged from the inflow fluid are discharged, A foreign matter collecting unit installed on a lower end surface of the chamber and configured to induce a vortex of a fluid flowing into the chamber through a lower end surface of the chamber, And an intake passage formed in the shape of a pipe, one end of which is connected to the first flow path or the second flow path and the other end of which is disposed inside the chamber And a heat exchanger disposed in the heat exchanger. The method of claim 3,
Wherein the centrifugal dust collector further comprises a discharge induction propeller installed in the chamber and discharging the foreign matter to the discharge port while disturbing the foreign matter as it is rotated by the air flow of the fluid.

Images