KR101117523B1 - Enthalpy exchanger - Google Patents

Abstract

PURPOSE: A total heat exchanger is provided to facilitate installation by forming a flow path using width of a case. CONSTITUTION: A total heat exchanger comprises a case(10), a duct, a flow path forming part, a total heat exchange element(30), and a bypass part. The case comprises a bottom plate, side covers, and a top cover. The duct comprises a suction port for sucking outdoor air, a supply port for supplying outdoor air, a ventilation port, and an exhaust port. The flow path forming part is installed on the bottom plate to form a flow path in an accommodation space of the case. The total heat exchanger element mutually heat exchanges between the outdoor air, sucked through the suction port, and the indoor air, sucked through the ventilation port. The total heat exchange element is obliquely arranged to form subsidiary installation spaces in each corner of the accommodation space. The bypass part is installed between the total heat exchange element and the ventilation port and has a damper. The damper supplies the indoor air, sucked through the ventilation port, to the total heat exchange element and the flow path.

Description

Heat exchanger {ENTHALPY EXCHANGER}

The present invention relates to a total heat exchanger.

In general, a ventilation unit is installed inside the building to discharge indoor polluted air to the outside and supply new air to the interior space.

In particular, in the case of single households such as apartments and villas, or in public facilities such as school classrooms and hospital rooms, the use of a ventilation system is essential because indoor air can be rapidly polluted. To reduce air pollution.

On the other hand, from mid-March to mid-June, and from mid-September to mid-November (commonly referred to as mid-term), air-conditioning and heating loads due to total heat exchange ventilation are simple. Since there is a tendency to increase, in the intermediate stage, the general (bypass) ventilation through simple air induction rather than the total heat exchange ventilation can reduce the heating and cooling energy.

In particular, the outside air cooling through the fresh air induction is very effective for school classrooms or hospitals where a large amount of cooling and heating energy is used, and thus, it is possible to efficiently reduce heating and cooling energy.

(Patent Document 1) relates to a ventilator provided with a bypass (Bypass) device to enable a total heat exchange ventilator and a general (bypass) ventilation, briefly described, the bypass device in the ventilator installed inside the heat exchanger Although installing the bypass device is removable, it is expected to be less space-limited according to the slimmer volume and reduced weight.

KR10-2008-0001312 A

However, the conventional heat exchanger capable of bypassing, including the above (Patent Document 1), is to install a damper on the inner side of the ventilator or install a bypass unit on the outer side so that outside air does not pass through the heat exchanger. When the damper is installed on the inner side of the ventilator, there is a problem that the installation space is restricted, and on the contrary, when the bypass device is installed on the outer side of the ventilator, inconvenience caused by the detachment is caused. There is this.

That is, when it is described in more detail, the heat exchanger is limited in the size of the horizontal, vertical due to problems in the installation space. For this reason, as in the prior art of (Patent Document 1), if a damper is formed on the inner side to form a bypass structure, a problem that requires an excessive space for installation of the ventilator may occur.

In order to solve this problem, as in the embodiment of the (Patent Document 1), if the bypass device is installed on the outer side of the ventilation device, inconvenience in use may occur due to the detachment, and the detachment may not be made depending on the installation space. There are also grievances to keep in mind.

Therefore, the present invention aims to solve the inconvenience in use as well as the installation space problem of the conventional heat exchanger capable of bypassing, including (Patent Document 1) through a new bypass structure.

It is an object of the present invention to provide a total heat exchanger which is not only easy to install but also easy to switch between a total heat exchange ventilator and a general (bypass) ventilator so as to efficiently reduce heating and cooling energy.

In order to achieve the above object,

The present invention includes a case including a bottom, a side cover surrounding the bottom, and a cover covering the accommodation space to form an accommodation space therein;

A duct provided in the case and including an air inlet for intake of outside air, an air inlet for supplying outside air inhaled through the air inlet, a ventilation port and an exhaust port for ventilating and exhausting indoor air;

A flow path forming part installed at a bottom of the flow path to form a flow path in the accommodation space;

A total heat exchange element installed in the accommodation space to exchange heat between the outside air intaked through the intake air and the indoor air intaken through the ventilation hole;

The damper is provided to supply the indoor air intake through the ventilation port to the total heat exchange element or the flow path, characterized in that it comprises a bypass portion provided between the heat exchange element and the ventilation port.

In addition, the heat exchange element according to the invention is characterized in that the inclined installation so as to form an auxiliary installation space at each corner of the receiving space.

In addition, the auxiliary installation space according to the present invention is characterized in that the blower is installed to force the air to the indoor air or to exhaust the indoor air by forced ventilation.

In addition, a control unit is installed outside the case according to the present invention, characterized in that the driving unit for driving the damper by driving through the electrical signal of the control unit is installed in the bypass unit.

In addition, the bypass unit according to the present invention includes a body disposed in the receiving space between the total heat exchange element and the ventilation port and the partition partitioning the interior of the body into the first space and the second space,

The first space communicates the ventilation port and the total heat exchange element, the second space communicates the ventilation port and the flow path, and the partition is characterized in that the first space and the second space communicate with each other.

According to the present invention, by forming a flow path using the width of the case that is relatively limited in the installation space compared to the horizontal and vertical installation space is severe, as well as the public facilities such as school classrooms, as well as a single household such as apartments, villas The heat exchanger can be easily installed in the

In addition, by switching the total heat exchange ventilation or general (bypass) ventilation through a damper provided in the bypass unit, the indoor air is exhausted, and in particular, by driving the damper from the outside in an automatic manner through a control unit and a drive unit, It is effective in improving convenience in use.

Furthermore, since the total heat exchange element is installed inclined in the accommodation space, it is possible to install a blower that can quickly reduce the air pollution in the room through forced air supply and exhaust without expanding the size of the case.

1 is a perspective view showing the inside of the heat exchanger according to the present invention in a disassembled cover.
Figure 2 is a perspective view showing each embodiment by disassembling the total heat exchanger according to the present invention.
Figure 3 is a perspective view showing a partially cut and enlarged bypass portion according to the present invention.
Figure 4 is a perspective view showing a total heat exchange ventilation through the bypass unit and the total heat exchange element according to the present invention.
Figure 5 is a perspective view showing a general (bypass) ventilation through the bypass portion and the passage forming portion according to the present invention.

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

The total heat exchanger 1 according to the present invention includes a case. As shown in FIG. 1, the case 10 has a form of a box, and a receiving space 11 is formed to install internal components such as the total heat exchange element 30 therein.

That is, the case 10 surrounds the rectangular bottom 12 with the side cover 13 to form an accommodation space 11 therein, and through the cover 12a opposing the bottom 12. The accommodation space 11 is covered and protected. At this time, the bottom 12 and the side cover 13 is formed integrally, the cover 12a is installed detachably for the convenience of replacement of the internal parts.

The case 10 is usually formed of a metal material to secure rigidity, but may be formed using other materials as long as it secures rigidity comparable to metal. In addition, the outside of the case 10 is provided with a bracket (Bracket) and the like for installation convenience.

The total heat exchanger 1 according to the invention comprises a duct. The duct is an embodiment of the inlet 14a is provided in the side cover 13 of the case 10 to intake the outside air, and the ventilation opening 15a for ventilating the indoor air on the opposite side of the inlet 14a It is showing what was equipped.

In addition, an air inlet 14b is provided on one side of the ventilation port 15a for supplying indoor air that has been inhaled through the inlet 14a, and an exhaust port 15b is provided on the opposite side of the air inlet 14b. The indoor air is exhausted to the outside.

Here, the duct is provided in the case 10 so as to share the receiving space 11 so that heat exchange through the total heat exchange element 30 is made, for this purpose, the inlet 14a and the air supply 14b, the ventilation opening ( 15a) and the exhaust port 15b are alternately formed.

That is, the outside air is discharged to the receiving space 11 through the inlet 14a, and then heat exchanges with the indoor air while passing through the heat exchange element 30, and is then provided to the room through the air supply 14b.

On the other hand, the indoor air is exchanged with the outside air while passing through the heat exchange element 30 through the ventilation port 15a, or exhausted to the outside through the exhaust port 15b without passing through the heat exchange element 30 through the flow path 21. Through this series of processes, indoor ventilation is achieved.

The total heat exchanger (1) according to the present invention includes a flow path forming portion (20). The flow path forming part 20 is installed on the bottom 12 of the case 10, thereby forming the flow path 21 by changing the width without expanding the horizontal and vertical sizes of the case 10. do.

The flow path forming part 20 is provided adjacent to the ventilation port 15a so that the ventilation port 15a and the flow path 21 can communicate with each other, and the other side to communicate the flow path 21 with the exhaust port 15b. One side is provided adjacent to the exhaust port 15b.

Thus, by installing the flow path forming portion 20 on the bottom 12 of the case 10, general (bypass) ventilation for exhausting indoor air to the outside without passing through the heat exchange element 30 is possible.

The total heat exchange element (Element) is installed in the receiving space 11 so as to exchange heat between the outside and indoor air, in particular about 45 ° so that the auxiliary installation space (11a) is formed at each corner of the receiving space (11) It is shown in an inclined state.

The pre-heat exchange element 30 is made of a rectangular shape corrugated cardboard stacked in the form of a hexahedron suitable for the pre-heat exchanger (1), by using the adsorption, decomposition, and purification by supplying the unrefined outside air to the room, Finally, the freshest air suitable for breathing is supplied to the room and ventilated.

The total heat exchange element 30 is omitted because it is well known in the art.

Here, the electrothermal exchange element 30 is shown in the embodiment that is slidably installed in the case 10 through the element guide 31 installed in the case 10.

That is, since the total heat exchange element 30 included in the present invention can be reused repeatedly by washing during contamination, the heat exchange element 30 is replaced by a device guide 31 in place of a known bracket or fixing bolt. When slidably installed in the case 10, it can be easily taken out and washed according to the degree of contamination, thereby improving management convenience.

On the other hand, as the electrothermal exchange element 30 is disposed inclined in the receiving space 11, the auxiliary installation space (11a) formed at each corner of the receiving space 11 is forced to intake the outside air in the room, or the air Blower is installed to exhaust the air by forced ventilation. Preferably, the blower is installed separately for intake and ventilation.

That is, as an example, the ventilation blower 32 is installed in the auxiliary installation space 11a so as to communicate with the ventilation port 15a and the exhaust port 15b, and exhausts the indoor air out of the building, which is a blower. It is implemented by installing in the auxiliary installation space (11a). The intake blower 33 is installed in the auxiliary installation space 11a so as to communicate with the intake port 14a and the air supply port 14b.

Therefore, as described above, the indoor air is passed through the heat exchange element 30 or the flow path 21 through the ventilation port 15a by the rotation driving of the ventilation blower 32, and through the exhaust port 15b. Finally, forced exhaust into the atmosphere.

On the contrary, the outside air is forced through the intake port 14a by the rotational drive of the intake blower 33, and passes through the total heat exchange element 30. In this process, contaminants are purified and heat exchanged with indoor air. It is finally supplied to the room through the air supply port 14b for ventilation.

The total heat exchanger 1 according to the present invention includes a bypass portion 40. The bypass unit 40 is provided with a damper (Damper) to supply the indoor air intake through the ventilation opening (15a) to the heat exchange element 30 or the flow path 21, and the heat exchange element 30 and It is provided between the ventilation openings 15a.

Here, the damper 41 is capable of driving control in a manual or automatic manner, preferably by installing a controller on the outside of the case 10, and driving through an electrical signal of the controller 42 The drive unit 43 is installed in the bypass unit 40 to drive the damper 41 in an automatic manner.

The driver 43 may include a circuit board (PCB) for receiving an electrical signal from the controller 42, a cover for storing and protecting the inside thereof, and a motor for substantially driving the damper 41. It is composed of

Therefore, by operating a remote control or the like in the room so that the electrical signal is sent from the control unit 42, the circuit board of the drive unit 43 receives this to drive the motor, as a result, the damper 41 is rotated to rotate the electrothermal exchange vent or General (bypass) ventilation will be performed.

As an example, the bypass part 40 includes a body 44 disposed in the accommodation space 11 between the electrothermal exchange element 30 and the ventilation opening 15a, and a first space (not shown) inside the body 44. The partition 45 is partitioned into 44a) and the 2nd space 44b.

The first space 44a communicates with the ventilation port 15a and the heat exchange element 30 as the damper 41 is driven. For this purpose, the first space 44a must communicate with the ventilation port 15a and the heat exchange element 30. You should also communicate with them.

Accordingly, it is shown that the first hole 44c is formed in the first space 44a, and the outside air and the indoor air are exchanged with each other in the heat exchange element 30 depending on whether the first hole 44c is opened or closed. . At this time, the first space 44a is finished through the lower panel 44d so as not to communicate with the flow path 21.

In addition, the second space 44b communicates with the ventilation hole 15a and the flow path 21 as the damper 41 is driven. For this purpose, the second space 44b is mutually connected with the first space 44a. It should communicate and also communicate with the flow path (21).

To this end, the present invention provides a partition 45 having a second hole 45a formed therein, and by installing it in the body 44, the indoor air is ventilated 15a, driven by the damper 41. The first space 44a and the second hole 45a are supplied to the second space 44b and then discharged to the flow path 21.

Here, the process of the total heat exchange ventilation in the room using the total heat exchanger (1) according to the present invention will be described in detail. As shown in FIG. 4, the outside air forcibly passing through the intake port 14a by the rotation driving of the intake blower 33 is discharged to the accommodation space 11 and then passes through the total heat exchange element 30.

On the other hand, the indoor air exchanges heat with the outside air while passing through the heat exchange element 30 through the ventilation port 15a, the first space 44a, and the first hole 44c by the rotation driving of the ventilation blower 32 for ventilation. The indoor air passing through the total heat exchange element 30 is finally exhausted to the outside via the exhaust port 15b.

Therefore, the fresh air is finally purified by the pre-heat exchange element 30 as clean air suitable for respiration by the series of ventilation processes, thereby ventilating the room.

The operation of the total heat exchanger (1) for the total heat exchange ventilation is suitable for the case where the temperature and humidity exchange is required through the crossover between the cold and cold weather indoor and outdoor air.

On the other hand, the general (bypass) ventilation of the room using the total heat exchanger (1) according to the present invention, as shown in Figure 5, the indoor air supply of the outdoor air is the same, but the heat exchange in the exhaust of the indoor air The difference is that they do not pass through the device 30.

That is, the indoor air is sequentially passed through the ventilation port 15a, the first space 44a, the second space 44b, and the flow path 21 by the rotation driving of the ventilation blower 32, and then passes through the exhaust port 15b. After that, it is finally exhausted out of the building.

The operation of the total heat exchanger (1) for general (bypass) ventilation is performed in mid-March to mid-June, in mid-September to mid-November, and in the middle of the year, without exchanging temperature or humidity. The air cooling effect can be obtained in a school classroom or a hospital room with high density of indoor rooms.

1-Heat exchanger 10-Case
20-Euro forming unit 21-Euro
30-Heat exchange element 40-Bypass unit
41-Damper 44-Body

Claims (5)

A case including a bottom, a side cover surrounding the bottom, and a cover covering the accommodation space to form an accommodation space therein;
A duct provided in the case and including an air inlet for intake of outside air, an air inlet for supplying outside air inhaled through the air inlet, a vent and exhaust port for ventilating and exhausting indoor air;
A flow path forming part installed at a bottom of the flow path to form a flow path in the accommodation space;
A total heat exchange element (Element) installed in the accommodation space to exchange heat between the air taken in through the inlet and the indoor air taken in through the vent;
A damper is provided to supply the indoor air inhaled through the ventilation port to the electrothermal exchange element or the flow path, and includes a bypass unit installed between the electrothermal exchange element and the ventilation hole.
The total heat exchange element is disposed inclined so that the auxiliary installation space is formed at each corner of the receiving space,
The auxiliary installation space is provided with a blower to exhaust the outside air by forced air supply or indoor air forced exhaust,
A controller is installed outside the case, and a driving unit for driving the damper by driving through an electrical signal of the controller is installed in the bypass unit.
The bypass unit includes a body disposed in the accommodation space between the electrothermal exchange element and the ventilation opening, and a partition partitioning the inside of the body into a first space and a second space, wherein the first space includes the ventilation opening and the heat transfer. Exchange the communication element and the second space communicates the ventilation port and the flow path, and the partition is configured to communicate with the first space and the second space,
The first space further includes a lower panel which prevents the indoor air discharged through the ventilation hole from flowing into the flow path.
The case is a total heat exchanger characterized in that it further comprises a device guide the sliding element is coupled to the total heat exchange element. delete delete delete delete

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