KR101127006B1 - the floor type heat exchanging ventilation system - Google Patents

Abstract

The present invention provides an upper grill (102) and a lower grill (103); One side of the main body case consisting of a controller 101, the rear cover 105 and; An electrothermal exchange element 201 having an even numbered square lattice integrally formed in the rectangular tube body, and each odd column of the upper and lower lattice of the electrothermal exchange element has a bisected upper side; Each even-numbered heat is separated from the air flow path distribution plates 202a and 202b for enclosing the divided lower side, and the air flow distribution plate 202a for separating and entering the indoor air sucked into the top surface of the heat exchange element and the heat exchanged indoor air. The upper air flow path distributor 203 closely assembled and the lower air flow path distributor 204 tightly assembled to the lower portion of the air flow path distribution plate 202b, which is returned from the lower surface of the total heat exchange element and is returned, and the upper air flow path. A total heat exchange element module (200) comprising an air flow channel cover (205a; 205b) which is tightly assembled above and below the flow path distributor (203) and the lower air flow path distributor (204); Bending flange grill hood for tightly assembling the air flow channel cover 205a and 205b, the upper air channel distributor 203, the lower air channel distributor 204 and the heat exchange element 201 of the total heat exchange element module 200, respectively. (206a; 206b), the indoor air exhaust socket 211 with a bent flange, the outdoor air intake socket 212 with a bent flange, fastening angle 210, characterized in that the low-energy type stand-type total heat exchange ventilator.

Stand, Heat Exchange, Ventilation

Description

The floor type heat exchanging ventilation system

The present invention relates to a stand type total heat exchange ventilator, in particular a heat exchange element module of the flow type is a total type heat exchange ventilator for ventilating the indoor air to fresh outdoor air while preserving the heat energy of the indoor air with a wide heat transfer volume area It is about.

In general, for the purification of indoor air, the air contaminated with an anion air purifier is sucked into the fan, and dust and microorganisms up to 0.01 μm are collected by the filter to deodorize body odor or tobacco smell, (Iii) Ions are recovered by ion generators. There are three types of filters: a mechanical filter which collects using mortene or glass fibers, a high performance filter which collects fine particles using glass fibers and cellulose fibers, and a deodorizing filter using activated carbon. In addition, an electrostatic precipitator which is added to these filters to collect dust by charging dust by a high pressure discharge may be used together.

Within 2 years of building sick house syndrome, substances harmful to the human body from building materials or cement, leaking materials, grass paste, prohmaldehyde by painting, other indoor pollutants, and environmental hormones It is easily exposed to skin diseases such as atopy and respiratory diseases by contact and inhalation. To this end, the heating temperature is increased, it is good to open and close the windows frequently from several hours to several days to sufficiently ventilate.

However, ventilation due to the opening and closing of the windows and doors has the disadvantage of losing the noise and inflow of the indoor air and the heat edge of the indoor air. Recently, the ceiling-mounted type and the floor-mounted type are designed to reduce the loss of thermal energy by ventilation as well as indoor and outdoor ventilation. There is a window installation type.

The heat exchange element of the ceiling type or floor top type has low recovery rate of heat energy exhausted by the cross-crossing type, and it is necessary to construct the duct equipment through the inner wall and the outer wall of the building, so as to secure the installation space, equipment price, construction cost and installation space. It is pointed out that the fan motor power is also frequently used due to the construction cost burden and static pressure caused by the duct construction.

 Therefore, recently, a separate installation of the heat exchanger installation space in the existing windows, or grafting or applying the ventilation system to the windows or windows frame is as follows.

Document 1 KR 10-2008-0051643 A 2008.06.11 FIGS. 3,4,5

[Document 2] KR 10-0698516 B1 2007.03.15 FIGS. 1,3,6

[Document 3] KR 20-0424420 Y1 2006.08.14 FIGS. 5,6

Document 4 KR 10-2006-0020641 A 2006.03.06 FIGS. 1,2,3

In Document 1 of the above example, the window frame of the hollow body corresponding to the circumference of the window opening formed on the building wall by the window ventilation system is formed in the intake flow passage and the exhaust flow passage partitioned adjacent by the partition wall, the partition wall In one region of a plurality of element installation holes for installing the total heat exchange element is provided at a predetermined interval, the total heat exchange element is at least one intake passage through the air passing through the intake passage of the window frame, window and At least one of the exhaust passages through which the air passing through the exhaust passage of the frame passes through the exhaust passage of the frame is arranged in a counterflow manner in which the inlet and the outlet of the intake passage are located in opposite directions with each other alternately stacked. It is built.

In this manner, as shown in Fig. 4 of Document 1, the production cost rises to the structure that the window frame member of the standard that extends to the entire window opening part must form a top and bottom window frame in a tightly sealed corner portion, It is necessary to embed the heat exchanger elements at regular intervals in the device mounting holes provided between the internally spaced partitions, or to separately install an intake and exhaust fan, and then perform complicated machining steps with the upper and lower limit tightly sealed. This is accompanied by an increase in production costs.

In addition, the total heat exchange element is not able to maximize the total heat exchange area of the total heat exchange element built in the same standard because the spacing between the heat exchange elements to be assembled in the device installation is formed in a window spaced apart at regular intervals.

On the other hand, in Document 2, the main body installed in the window with the window type heat exchanger is located in the indoor part and the part located in the outdoor area, the indoor air intake port and the external air exhaust port for discharging the outside air is installed on the upper upper surface located in the room, In the lower part of the main body, which is located outdoors, the outside air inlet and the indoor air outlet are installed inside. As shown in Figs. 5 and 8 of Document 2, the window is a heat exchanger using a known heat exchanger in which indoor air and external air flow to both sides of the heat exchange membrane. It is pointed out that the main body, which is installed in the upper part protrudes out of the room, is not good in appearance, nor can maximize the total heat exchange area efficiency compared to the installation space.

Meanwhile, as shown in Document 3, the ventilation system and the outdoor unit integrated ventilation system of the air conditioner have an outdoor unit casing having a compressor and a heat exchanger installed at one side of the window installed in the window frame, and the noise of the compressor is transmitted to the room. When not in use, as shown in Fig. 5 of Document 3, after closing the shutters of the upper and lower heat exchangers, the lower casing fan is operated to introduce external air directly into the room through a filter inside the casing, or the indoor air is supplied to the upper casing fan. By operating the exhaust to the outside through the exhaust port of the upper layer, by installing the outdoor unit of the air conditioner in the window, and ventilating the indoor outdoor air through the intake and exhaust fan can not expect the effect of heat transfer.

On the other hand, Document 4 is an integrated air conditioner built-in integrated air conditioner including a compressor, an indoor heat exchanger, an expansion mechanism, an outdoor heat exchanger and a circulating pipe built into the inside of the wall, or the air conditioner and the window is integrated in a manner according to the ventilation system The total heat exchange effect cannot be expected, and in the case of the window body shown in FIG. 2 of Document 4, the interior heat exchange outer part may protrude from the window frame, or the compressor and the heat exchange pipe should be embedded in the window frame lower wall. Due to the problem of the built-in circulation pipe in the inside, there is a problem in that, in the event of a failure, the entire pipe must be replaced, or the wall must be damaged.

Accordingly, an object of the present invention is to maximize the total heat exchanger volume of the conventional cross-cross type heat exchange element by the flow-flow type heat exchange element to increase the total heat exchange effect, thereby saving energy, and the installation cost of the room at a lower cost than the window frame type. It is an object of the present invention to provide a stand type total heat exchange ventilator for easy installation at any place.

In order to achieve the above object, in the present invention, each of the upper grill 102 and the lower grill 103 at the upper and lower ends of the rectangular box body; A main body case (100) formed of a rear cover (105) for screwing on one side with a controller (101) on the back; An inner heat exchange element 201 having an even numbered square lattice integrally formed inside a rectangular tube body, and an odd side of each upper and lower lattice of the upper heat exchange element being bisected; Each even-numbered heat is separated from the air flow path distribution plates 202a and 202b for enclosing the divided lower side, and the air flow distribution plate 202a for separating and entering the indoor air sucked into the top surface of the heat exchange element and the heat exchanged indoor air. The upper air flow path distributor 203 closely assembled and the lower air flow path distributor 204 tightly assembled to the lower portion of the air flow path distribution plate 202b, which is returned from the lower surface of the total heat exchange element and is returned, and the upper air flow path. A total heat exchange element module (200) comprising an air flow channel cover (205a; 205b) which is tightly assembled above and below the flow path distributor (203) and the lower air flow path distributor (204); Bending flange-attached grille hood for assembling the air flow channel cover 205a and 205b, the upper air channel distributor 203, the lower air channel distributor 204, and the heat exchange element 201 of the total heat exchange element module 200 in close contact. (206a; 206b), an indoor air exhaust socket 211 with a bending flange, an outdoor air intake socket 212 with a bending flange, and a fastening angle 210 are provided. .

Stand type total heat exchange ventilator according to the present invention is the effect of reducing the use of indoor energy by increasing the total heat exchange effect by maximizing the total heat exchange volume by the total heat exchange element of the conventional cross-crossing type heat exchange element to the mutual flow method. And, as a compact and slip-type electrothermal heat exchange ventilator compared to the past, it is a useful invention that can be applied to various shapes at a lower cost than the window frame type.

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

1 is a perspective view of a stand-type total heat exchange ventilation apparatus according to the present invention, Figure 2 is an exploded perspective view of the main part of the present invention, Figure 3 is an external perspective view of the heat exchange element module assembled to the intake and exhaust hood, Figure 4 is a main part of the present invention (I) is an exploded perspective view of an outdoor air inflow, (ii) is an exploded perspective view of an indoor air discharge.

As shown in these drawings, the stand-type total heat exchange ventilator according to the present invention is a rectangular box body in the upper and lower portions of the upper grill 102 and the lower grill 103; A main body case (100) formed of a rear cover (105) for screwing on one side with a controller (101) on the back; An inner heat exchange element 201 having an even numbered square lattice formed integrally inside the rectangular tube body, and an odd side of each of the upper and lower lattice lines of the top and bottom gratings of the heat exchange element being bisected; Each even-numbered heat is divided into air flow distribution plates 202a and 202b for enclosing the divided lower side and air flow distribution plates 202a for separating and entering indoor air sucked into the top surface of the heat exchange element and heat exchanged indoor air. The upper air flow path distributor 203 closely assembled and the lower air flow path distributor 204 tightly assembled to the lower portion of the air flow path distribution plate 202b, which is returned from the lower surface of the total heat exchange element and is returned, and the upper air flow path. A total heat exchange element module (200) comprising an air flow channel cover (205a; 205b) which is tightly assembled above and below the flow path distributor (203) and the lower air flow path distributor (204); Bending flange grill hood for tightly assembling the air channel cover 205a and 205b, the upper air channel distributor 203, the lower air channel distributor 204 and the heat exchange element 201 of the total heat exchange element module 200, respectively. 206a and 206b, the indoor air exhaust socket 211 with the bent flange, the outdoor air intake socket 212 with the bent flange, and the fastening angle 210 are included.

The controller 101 of the main body case 100 is driven by a power supplied from a power supply unit (not shown), and it is preferable to provide and control an on / off switch of a fan that exhausts indoor air or intakes outdoor air. .

In addition, the upper grill 102 of the front upper side of the main body case 100; The lower grill 103 at the lower side is detached by magnetic force, and the indoor air is extruded from the total heat exchange element module 200 inside the main body case through the upper grill 102 and then protrudes on the top of the rear cover 105. The heat exchange element inside the body case is discharged to the outdoor through the indoor air exhaust socket 211 with the bent flange, the outdoor air intake socket 212 protrudes to the bottom of the rear cover 105. After the heat exchange with the indoor air in the module 200, it is discharged to the room over the filter 104 inherent in the lower grill (103).

The heat exchange element 201 of the heat exchange element module 200 is formed by integrally forming a square lattice of even rows in the entire length section of the rectangular tube body, and an odd column among the lattice corresponding to each lattice formed on the upper and lower surfaces of the heat exchange element is An air flow distribution plate 202a which seals the bisected upper side; The even-numbered rows are injection-molded into an integral plate-like body such that the air flow distribution plates 202b each sealing the divided lower side are in close contact with each other.

Referring to each enlarged perspective view shown in FIGS. 4 and 5 and each reference cross-sectional view of FIGS. 6 and 7 as an air flow distributor which is a main part of the present invention.

The upper air flow path distributor 203 is a rectangular body injection molded of a resin material having the same plane standard as the air flow path distribution plate 202a and a shorter height than any one side of the plane standard, and each column of the air flow path distribution plate 202a An upper air passage upper and lower through holes 203a penetrated up and down and closed in all directions so as to communicate only with the openings at the upper end of the even-numbered column; The air flow distribution plate 202a opens at the lower half of the odd-numbered compartments of the entire half row. The through-hole 203b and the other half of the left half are opened only at the left side and the bottom side, and the other half of the row is at the right side and the bottom side. The through hole 203c is formed integrally with the upper air oil which is opened and closed on all sides.

On the other hand, the lower air flow path distributor 204 is a rectangular body injection-molded with a resin material having the same plane standard as the air flow path distribution plate 202b and shorter than any one side of the plane standard, air flow distribution plate 202b Upper and lower through-holes 204a penetrated up and down and closed in all directions so as to communicate only with an opening of an upper end of an odd number column of each row of; The air flow distribution plate 202b has a left and top through-hole 204b with only the left side and the upper side open at the lower end of the odd cell in the half row of the entire half row, and the lower half of the half row has the right side and the upper side only. The right upper surface through hole 204c is integrally formed with the lower air oil opened and closed on all sides.

The upper and lower air flow path covers 205a and 205b are formed in a rectangular box in which a surface closely contacted to the upper and lower surfaces of the upper and lower air flow distributors 203 and 204 is opened.

The group arrangement of the electrothermal exchange element module 200 configured as described above is an air flow path cover 205a, an upper air flow path distributor 203, an air flow path distribution plate 202a, a heat exchange element 201, and an air flow path from above. The distribution plate 202b, the lower air flow path distributor 204, and the air flow path cover 205b are stacked in order, and the air flow path cover 205a, the upper air flow path distributor 203, and the air flow path distribution plate 202a ), One side diagonal direction stacked in the order of the total heat exchange elements 201, the total heat exchange elements 201, the air flow path distribution plate 202b, the lower air flow path distributor 204, the air flow path cover 205b The stacked one-sided diagonal edges are fastened with the assembling screw 213 to the fastening angle 210.

On the other hand, the left and right through-hole 203b of the upper air flow path distributor 203 stacked between the air flow path cover 205a and the total heat exchange element 201 in one side of the diagonal direction;

Each of the upper grill 102 and the lower grill 103 is disposed on the left and upper through holes 204b of the lower air flow path distributor 204 stacked between the heat exchange element 201 and the air flow path cover 205b. Each indoor air exhaust fan 208 and the outdoor air intake fan 209 are built into the bending flange grille hood 206a; 206b having the packing members 207a; .

In addition, the upper air flow path of the upper air flow path distributor 203 stacked between the air flow path cover 205a and the total heat exchange element 201 in another one side of the diagonal direction, and the heat transfer hole 203c; An indoor air exhaust socket 211 with a bending flange and a bending flange are provided in the lower air flow passage right and upper through holes 204c of the lower air flow distributor 204 stacked between the exchange element 201 and the air flow channel cover 205b. The outdoor air intake socket 212 is assembled to the assembly screw 213.

The stand-type total heat exchange ventilator of the present invention configured as described above will be described.

When the indoor air exhaust fan 208 and the outdoor air intake fan 209 of the stand type heat exchange ventilator according to the present invention are operated, the heat flow of the indoor air is the upper grill 102 provided on the front of the main body case 100. Through the inside of the body case, through the grill air hood 206a attached to the upper air flow path distributor 203 of the heat exchange element module 200 through the upper air flow path of the upper air flow path distributor 203 through the left and right through holes Flows into 203b.

The warm and turbid indoor air flows in through the opening of the bottom of the air flow distribution plate 202a, and the opening corresponding to the lattice of odd columns of half of the lattice of all cells corresponding to the lattice formed on the upper surface of the heat exchange element 201. While downward through the air passage distribution plate 202b, through the openings in the upper air passage cover 205b through the lower air passage upper and lower through holes 204a of the lower air passage distributor 204.

The lower air flow path distributor 204 is discharged to the upper end through the heat exchange element 201 through the air flow path distribution plate 202b communicated with the lower air flow path up and down through holes 204a on the side of the lower air flow path distributor 204. When the upper air flows in communication with the opening of the plate 202a, it is discharged into the through hole 203c and is discharged to the outside through the indoor air exhaust socket 211.

On the other hand, the heat transfer of the outdoor air is fresh and cold air introduced through the outdoor air intake socket 212 protruding under the rear cover 105 of the main body case 100 is the lower half of the compartment of the lower air flow distributor 204 The air flow path flows through the upper and right through holes 204c, and through the opening of the heat exchange element 201 compartment half through the opening of the air passage distribution plate 202b compartment half, the air passage distribution plate 202a compartment half It returns from the air flow path cover 205a on the upper air flow distributor 203 which is in close contact with the opening of the air filter.

Subsequently, the air flow distribution plate 202a, the heat exchange element 201, and the air flow distribution plate which are in close contact with each other through the openings of the upper and lower through-holes 203a of the upper air flow path distributor 203. Through the opening of the 202b, the lower air flow path of the lower air flow distributor 204, the indoor air through the lower grill 103 through the outdoor air intake fan 209 and the filter 104 through the left and top through holes 204b. Heat exchange with and will introduce the outdoor air, the temperature increased by the heat transfer into the room.

In the above, the filter 105 serves to filter foreign substances such as yellow dust in the outdoors, and is often washed by being inserted into the lower grill 103 that is detached by magnetic force.

The indoor and outdoor air is heat-exchanged with the indoor and outdoor air polluted and warm air and the fresh and cold air in the vertical vertical flow. Compared with this, the total heat exchanger area is maximized, and the heat exchange effect is high, thereby preserving indoor energy and ventilating indoor and outdoor air.

1 is a perspective view of a stand type heat exchange ventilator according to the present invention.

Figure 2 is an exploded perspective view of the main part of the present invention.

Figure 3 is an external perspective view of the heat exchange element module assembled into the intake and exhaust hood

Figure 4 is an exploded perspective view (i) is an exploded perspective view according to the outdoor air inflow, (ii) is an exploded perspective view according to the indoor air discharge.

Figure 5 is a perspective view of the air flow distributor of the main part of the present invention (i) is an enlarged perspective view of the upper air flow distributor, (ii) is an enlarged perspective view of the lower air flow distributor.

6 is a cross-sectional view taken along line A-A ', B-B', and C-C 'of FIG. 5;

7 is a cross-sectional view taken along line A-A ', B-B', and C-C 'of FIG.

※ Explanation of symbols for main parts of drawing

100 : body case

101: controller 102: upper grill

103: lower grill 104: adjustable leg

105: back cover

200 : electrothermal exchange element module

201: electrothermal exchange element 202a; 202b: air flow distribution plate

203: upper grain euro distributor 204: lower air euro distributor

205a; 205b: air passage cover

206a; 206b: grill hood 207a; 207b: packing member

208: indoor air exhaust fan 209: outdoor air intake fan

210: Tightening angle 211: Indoor air exhaust socket

212: outdoor air intake socket

213: Assembly Screw

Claims (6)

Each of the upper grille 102 and the lower grille 103 at the top and bottom of the rectangular box body; A main body case (100) formed of a rear cover (105) for screwing on one side with a controller (101) on the back; An inner heat exchange element 201 having an even numbered square lattice integrally formed inside a rectangular tube body, and an odd side of each upper and lower lattice of the upper heat exchange element being bisected; Each even row includes air flow distribution plates 202a and 202b for enclosing the divided lower sides, respectively. An air flow distribution plate 202a for separating and entering the indoor air sucked into the top surface of the heat exchange element and the indoor air heat exchanged; A rectangular body injection molded of a resin material having the same plane standard as that of the air flow distribution plate 202a and a shorter height than one side of the plane standard, so as to communicate only with an opening at the top of the even column of each row of the air flow distribution plate 202a. Upper and lower through-holes 203a penetrated up and down and closed in all directions; The air flow distribution plate 202a opens at the lower half of the odd-numbered compartments of the entire half row. The through-hole 203b and the other half of the left half are opened only at the left side and the bottom side, and the other half of the row is at the right side and the bottom side. An upper air flow distributor 203 which is formed with a through hole 203c integrally formed when the upper air oil is opened and closed on all sides, and is tightly assembled on the air flow distribution plate 202a; An air flow distribution plate 202b, which is returned from the lower surface of the total heat exchange element and is upwardly returned; A rectangular body molded by resin having the same plane standard as the air flow distribution plate 202b and a shorter height than either side of the plane standard so as to communicate only with an opening at the top of the odd column of each row of the air flow distribution plate 202b. Upper and lower through-holes 204a penetrated up and down and closed in all directions; The air flow distribution plate 202b has a left and top through-hole 204b with only the left side and the top surface open at the bottom of the odd cell bottom of the half row, and the other half of the air flow distribution plate 202b, and the other half of the row of the right half and the top side. A lower air flow path distributor 204 which is formed in a lower air flow path having an open and closed four-sided upper through hole 204c integrally and tightly assembled under the air flow path distribution plate 202b; An electrothermal heat exchange element module (200) comprising an air flow channel cover (205a; 205b) which is tightly assembled above and below the upper air flow distributor (203) and the lower air flow distributor (204); Bending flange-attached grille hoods 206a and 206b which are assembled into the upper and lower through-holes 203b and the lower and upper through-holes 204b, respectively; The upper air flow through the lower surface through-hole (203c) has an indoor air exhaust socket (211) with a bending flange assembled by the assembly screw (213); A lower air flow passage right upper surface through hole 204c includes an outdoor air intake socket 212 having a bent flange assembled with an assembling screw 213; Stand-type total heat exchange ventilation, characterized in that it comprises a fastening angle 210 is assembled to the corners of the air flow channel cover (205a; 205b), the upper air flow path distributor 203, the heat exchange element 201 in close contact with each other. Device. According to claim 1, the total heat exchange element 201 is formed in an integral square grid of even rows in the entire length section of the rectangular tube body, the odd column of the lattice corresponding to each lattice formed on the upper and lower sides of the heat exchange element is divided into the upper side An air flow distribution plate 202a for sealing; Stand even heat exchange ventilator is characterized in that the injection formed into an integral plate-like body so that the air flow distribution plate (202b) for sealing each of the divided lower side. delete delete The packing member of claim 1, wherein the upper and lower through-holes 203b are disposed in the upper air oil; and the packing members are in close contact with the inner sides of the upper grill 102 and the lower grill 103, respectively. Stand type heat transfer characterized in that each indoor air exhaust fan 208 and the outdoor air intake fan 209 are assembled into the assembling screw 213 in the bending flange grille hood 206a; 206b with the (207a; 207b) inserted therein. Exchange ventilation. delete

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