KR200247535Y1 - Heat recovery device - Google Patents

Abstract

The present invention recovers the heat energy according to the ventilation of the indoor and outdoor air more efficiently, and directly utilizes it in the vertical direction of the longitudinal direction of the thin thin plate in which a large number of internal and external contacts are laminated in order to maximize the efficient use of energy. The present invention relates to a heat recovery apparatus that maximizes heat recovery by increasing its contact distance and contact area while being cross-exchanged.

The present invention is the air inlet passages (12, 13) and the air outlet passages (14, 15) are formed in the front, rear, respectively, above and below the gas (10), the respective air inlet passages (12, 13) And the blower motors 30 and 40 are installed at the upper and lower sides of the air blower 14 and 15, and the air circulation path 53 and the outside air between the upper and lower blower motors 30 and 40. By installing heat exchange unit 50 in which a myriad of heat exchanger thin plates 51 and 52 are stacked and assembled so as to have a smooth passage 54 alternately, internal and external air by the respective blower motors 30 and 40 is vertical. It is possible to reduce the size of the device according to the installation space by cross-circulating circulating up and down while circulating cross-circulating, and to perform heat exchange while cross-circulating circulating inside and outside vertically and vertically to efficiently waste heat by maximizing contact area. It has a recovery effect.

Description

Heat recovery device {HEAT RECOVERY DEVICE}

The present invention relates to a heat recovery apparatus, and more particularly, by directly recovering and directly using heat energy due to the ventilation of indoor and outdoor air, the internal and external contact is increased in order to maximize the efficient use of energy. Cross-exchange in the vertical direction of the laminated thin sheets in the longitudinal direction to maximize the heat recovery rate by increasing the contact distance and contact area, and the effective operation of the device by minimizing the discharge pressure in the effective discharge angle according to the discharge of the internal and external air The present invention relates to a heat recovery device provided.

In recent years, as the energy problem emerges, a number of techniques for efficiently using energy have been disclosed.

It is well known that the waste heat is recycled while intersecting air or water having a temperature difference between them.

As a representative example, air conditioning or heating installed indoors by preheating or lowering the temperature of incoming air by exchanging heat (heating heat and cooling heat) of indoor air ventilated for ventilation in a building with newly introduced air. The energy consumption of air conditioners such as appliances is minimized.

Effective heat exchange to increase energy efficiency should ensure the maximum contact area between media with different temperatures, and at the same time, the heat exchange time should be made to minimize the temperature deviation between them as quickly as possible. The discharge load of the blower should be low to provide effective heat exchange by minimizing the load of the blower motor.

However, the conventional heat recovery apparatus has a structure in which heat exchange due to waste heat recovery is not efficient.

That is, in the conventional heat recovery apparatus, the height of the air passage space of the heat exchange medium is large so that rapid heat exchange between the intersecting media is not provided, and the heat exchange medium is provided at the horizontal intersection to provide a plurality of cross spaces for high efficiency. This necessitates a disadvantage that the entire apparatus is enlarged, making it difficult to downsize.

The present invention has been researched and developed to effectively solve the above disadvantages of the prior art,

The object of the present invention is to provide heat dissipation medium having a temperature difference between the upper and lower sides of the heat exchange medium, and to maximize the contact area by minimizing the width of the device as much as possible and increasing the length in the discharge direction in relation to the entire apparatus. It is to provide a heat recovery device that can maximize the heat exchange efficiency.

The purpose of the present invention is to provide a heat exchange medium by providing a unique structure of the heat exchanger thin plate constituting the heat exchange unit, which is easy to assemble according to the specification of the device, and is provided in a myriad of laminated structures so that the passage space of the heat exchange medium crosses with each other as little as possible. It is to provide a more efficient heat recovery apparatus is provided that provides a quick heat exchange of, and miniaturization is provided.

An object of the present invention is to minimize the load according to the operation of the device by forming a predetermined discharge angle in the discharge port to minimize the discharge load according to the discharge while the heat exchange medium having a mutual temperature difference cross-discharge in the vertical direction, The present invention provides a heat recovery device that provides maximum life.

The object of the present invention is a gas provided with a plurality of air inlet passages and outlet passages of the indoor side and the outdoor side, the heat exchange unit mounted inside the gas, and the air inlet passage and the outlet passage is provided to force air It consists of a blowing motor to flow,

The air inlet passage and the air outlet passage are formed at the front and the rear of the gas, respectively, above and below, and are installed with the blower motors above and below the respective air inlet passage and the outlet passage. A heat exchange unit in which a number of heat exchanger thin plates are stacked and assembled so that the air circulation path and the air outdoor passage alternately exist between blower motors is installed. And by a heat recovery device configured to be discharged.

1 is a schematic configuration diagram of a heat recovery device of the present invention,

2 is a front configuration diagram of a heat exchange means of the present invention,

3 is a partially omitted enlarged cross-sectional view taken along the line A-A of FIG.

4 is a partially omitted enlarged cross-sectional view taken along the line B-B of FIG.

5 is a front view of a heat exchange thin plate as a constituent member of the present invention,

Figure 6 is a perspective view showing the assembly process of the heat exchanger thin plate of the present invention,

7 and 8 are a cross-sectional view and side cross-sectional view of the assembly process of the heat exchanger thin plate according to FIG.

9 is an operation according to the use of the present invention.

<Description of the reference numerals for the main parts of the drawings>

10: gas 30, 40: blowing motor

50: heat exchange unit 51, 52: heat exchange sheet

53: bet circulation passage 54: outside circulation passage

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

That is, according to the present invention, as shown in FIGS. 1 to 8, the air inlet passages 12 and 13 and the air outlet passages 14 and 15 are respectively located at the front and the rear of the body 10. The blower motors 30 and 40 are formed between the air inlet passages 12 and 13 and the outlet passages 14 and 15, respectively, and are respectively provided with the blower motors 30 and 40. Each of the blower motors is installed by installing a heat exchange unit 50 in which numerous heat exchange thin plates 51 and 52 are stacked and assembled so that the internal air circulation passage 53 and the external air pure passage 54 alternately exist between the 40 and 40. The internal and external air by (30) and (40) is made to exchange heat and discharge while cross-circulating circulating upward and downward in the vertical direction.

The heat exchange unit 50 includes heat exchange plates 51 and 52 such that the heat exchange plates 51 and 52 made of aluminum are stacked to be alternately formed such that the internal air circulation path 53 and the external air circulation path 54 are formed. Alternately sealing the adjacent two pairs of sides to alternately seal the upper and lower plates 21a and 21b and the front and rear plates 26a, which have air inlet passages 22 and 23 and outlet passages 24 and 25, respectively. 26b) is assembled to both side plates 27a and 27b by a fastening member such as a conventional screw to form an enclosure shape, and is assembled to the base 10 in a storage state.

That is, four vertices of each of the heat exchange thin plates 51 and 52 are formed by cutting the cutting grooves 55a and 55b, and two adjacent sides in the diagonal direction are upwardly bent ends 56a and 56b and downwardly bent ends 57a and 57b. ) Is formed, and each of the upwardly bent ends 56a and 56b is extended by the extension ends 56c and 56d, and the downwardly bent ends of the heat exchanger thin plates 52 are formed at the upwardly bent ends 56a of the heat exchanger thin plates 51. 57b) in the state of bending the extended end 56c of the upward bend end 56a to seal the adjacent head side, the next heat exchange thin plate laminated on the up bend end 56b of the heat exchange plate (52) ( In the state of facing down bending end 57a of 51), alternately stacking assembly for bending the extension end 56d of the up bending end 56a in the same direction of the extension end 56c to seal the adjacent head side to seal. As a result, the internal circulation passage 53 and the external air circulation passage 54 are alternately formed between the heat exchange thin plates 51 and 52,

Assembling each support frame 60 in each of the cutting grooves 55a and 55b and sealing them with conventional silicon to fasten both ends of the two side plates 27a and 27b in the same manner as ordinary screws. It is achieved by assembling and fixing with members.

At this time, the heat exchange thin plate 51, 52 is a linear embossing projection (58a, 58b) to the size of the bending height of the up bending end (56a, 56b) so as to maintain the gap between the inner and outer circulation passages (53, 54). ) And a plurality of hemispherical embossing protrusions 59a and 59b protrude from each other, and their positions are eccentrically staggered so as to contact the horizontal surfaces of the respective heat exchanger plates 51 and 52 at the time of assembly so as to maintain the same gap.

In addition, each of the heat exchange plates 51 and 52 is formed in a parallelogram formed at an acute angle of 68 to 72 degrees with respect to the side of the vertical direction adjacent to the upper side and the lower side. It is configured to have an obtuse angle b so that a load is not applied to the discharge flow of air.

The present invention, as shown in Figure 9, the air inlet passage 12 and the air outlet passage 14 of the gas 10 by the blocker 100, such as the wall of the building to the indoor side and the outdoor The air inlet passage 13 and the air outlet passage 15 are located on the side or vice versa.

In this state, by applying power, the blower motors 30 and 40 installed above and below the body 10 are operated.

By the operation of the blower motors 30 and 40, the air on the indoor side and the air on the outdoor side pass through the air inflow passages 12 and 13 of the gas 10. The inner and outer circulation passages 54 alternately formed by the heat exchanger plates 51 and 52 stacked innumerably while passing through 23 are cross-circulated vertically upward and downward, and withdraw passages 24. And 25 are discharged in a state where heat exchange is made between the draw passages 14 and 15 of the gas 10.

Therefore, by effectively exchanging the heat between the inside and the outside air having a temperature difference, it is possible to effectively save the energy of the cooling mechanism and heating mechanism such as the air conditioner by the waste heat recovery.

The features of the present invention are internally and internally, such as air convection, cross-crossing the inner and outer air in the vertical direction up and down innumerably stacked, the internal circulation is formed alternately between the heat exchange plate 51, 52 of a very thin aluminum material Fast heat exchange is made in the passage 53 and the outside air circulation passage 54 in a short time, so that the recovery of waste heat becomes more efficient.

In addition, the discharge angles of the drawing passages 24 and 25 of the heat exchange unit 50 according to the discharge of the internal and external air are formed at an obtuse angle to minimize the operation load of the blower motors 30 and 40 by minimizing the discharge load. .

The heat exchange unit 50 according to the present invention has a side width of the base 10 set in accordance with the laminated assembly thickness of the heat exchange thin plates 51 and 52, thereby making it possible to be miniaturized and enlarged according to the installation space.

The blower motors 30 and 40 may be installed in plural or more as necessary.

As described in detail above, the present invention is capable of miniaturization of the device, and is determined by the assembly size of the heat exchange unit, which is an important component according to the installation space, thereby providing the variability of the installation occupancy and providing reliability of the device.

Contact area is achieved by cross-circulating circulating internal and external air by vertically and vertically by each blower motor with a heat exchanger unit having an internal air circulation path and an external air pure passage alternately formed between numerous heat-exchanged thin plates. It has an efficient waste heat recovery effect by maximizing

Since the discharge angle of the obtuse angle is formed to enable natural discharge with respect to the traveling direction of the inside and outside air, there is an effect of maximizing the life of the device by minimizing the load of the blower motor.

Claims (4)

The air inlet passages 12 and 13 and the air outlet passages 14 and 15 are formed at the front and the rear of the body 10, respectively, respectively, and the respective air inlet passages 12 and 13 and the outlet passages ( The blower motors 30 and 40 are installed above and below 14 and 15, and the air circulation path 53 and the outside air pure passage 54 between the blower motors 30 and 40 above and below. ) Is installed so that the heat exchange unit (50) in which numerous heat exchange thin plates (51) (52) are stacked and assembled so that internal and external air by the respective blower motors (30) and (40) is vertically up and down. A heat recovery device, characterized in that the heat exchange and discharge while cross-cross circulation. The method of claim 1, The heat exchange unit 50 has the upper and lower plates 21a having the air inlet passages 22 and 23 and the outlet passages 24 and 25 on the outside of the heat exchange thin plates 51 and 52 laminated with a predetermined thickness. , 21b) and the front and rear plates (26a, 26b) and wrapped between the side plates (27a, 27b) and assembled into a housing composed of a conventional fastening member is assembled and stored in the base 10, The four vertices of each of the heat exchange thin plates 51 and 52 are formed by cutting the cutting grooves 55a and 55b, and two adjacent sides of the diagonal direction are upwardly bent ends 56a and 56b and downwardly bent ends 57a and 57b. Is formed, each of the upward bend end (56a, 56b) is extended end (56c, 56d) is extended so that the downward bend end (57b) of the heat exchanger thin plate (52) to the up bend end (56a) of the heat exchange thin plate (51) ) And bending the proximal end side by sealing the extended end (56c) in the state of), and the downward bent end (57a) of the next heat exchange thin plate (51) to the upward bent end (56b) of the heat exchange thin plate (52). The bet circulation passage between the heat exchange thin plates 51 and 52 by alternating lamination bending to bend the extension end 56d in the same direction of the extension end 56c in the butted state to seal the adjacent two sides. (53) and the open air circulation passage 54 are formed alternately, Each of the cutting grooves 55a and 55b is sealed with ordinary silicon in a state in which each support frame 60 is assembled, and both ends thereof are fastened to the inside of the side plates 27a and 27b. Heat recovery apparatus, characterized in that the assembly is made of. The method according to claim 1 or 2, The heat exchange thin plates 51 and 52 are eccentric with the line-shaped embossing protrusions 58a and 58b and the plurality of hemispherical embossing protrusions 59a and 59b at the bending heights of the upwardly bent ends 56a and 56b, respectively. A heat recovery device, characterized in that it is assembled to maintain a gap between the internal air passage 53 and the outdoor air circulation passage 54, The method according to any one of claims 1 to 3, Each of the heat exchanging thin plates 51 and 52 is formed in a parallelogram formed at an acute angle of 68 to 72 degrees with respect to the side in the vertical direction where the upper side and the lower side are configured such that the air discharge angle drawn out has an obtuse angle of 108 to 102 degrees. Heat recovery device characterized in that.