KR100518429B1 - A inspection door mounting structure of ventilation system - Google Patents

Abstract

The present invention relates to an inspection door mounting structure of a ventilation system.

In the inspection door mounting structure of the ventilation system according to the present invention, an inspection opening 104 is provided on the front surface 50 'of the main body case to serve as an internal inspection and an internal parts replacement window, and the inspection opening 104 includes an inspection door 110. In the ventilation system opened and closed by; The front surface 50 ′ of the main body case and the inspection door 110 correspond to each other by a locking rib 120 for mounting the inspection door 110 and a rib fixing member 130 on which the locking rib 120 is engaged. The rib fixing tool 130 is provided to protrude forward on the front surface 50 'of the main body case in which the inspection hole 104 is formed, the locking rib 120 is formed in the inspection door 110 This is preferred. On the other hand, the rib fixture 130 includes a rib seating portion 134 for fixing the locking rib 120, and rib guide portion 136 for guiding the locking rib 120 to the rib seating portion 134. It is configured by. According to the present invention as described above, there is an advantage that the opening and closing of the inspection door is easier.

Description

A inspection door mounting structure of ventilation system

The present invention relates to a ventilation system, and more particularly to a mounting structure of the inspection door for shielding the inspection opening formed on the front of the main body case of the ventilation system.

In recent years, due to problems such as energy conservation and noise, the residential space of human beings is gradually becoming airtight and insulated. However, the air in these closed spaces gradually changes to carbon dioxide and contaminates over time, thereby inhibiting the breathing of life.

Therefore, places where many people stay in narrow spaces, such as offices or vehicles, should be ventilated from time to time. At this time, the ventilation apparatus using the total heat exchange system is used normally. This is for supplying the outside air while maintaining the indoor air temperature, and for exhausting the indoor air.

1 is a perspective view of an exterior of a conventional ventilation device. As shown in the drawing, the outside air inlet 12 is formed on one side of the main body case 10 forming the exterior so as to suck the outside air.

An inside of the outside air inlet 12 is formed with a suction duct (not shown) that serves as a passage for guiding the outside air sucked from the suction hole 12, and the air guided by the suction duct is discharged from the room. Transfer to a total heat exchanger (not shown) for heat exchange with the air.

The front of the body case 10 is equipped with a check door 30 to be described in detail below, the check door 30 is installed in front of the heat exchanger to facilitate the removal of the heat exchanger, while the ventilation device Make it easy to check the inside.

The control box 16 is installed at the front right end of the main body case 10. The control box 16 is equipped with various components for controlling the operation of the ventilation device.

The outside air passing through the heat exchanger (not shown) from the outside air inlet 12 is opposite to the intake hole 12 by an outside air supply unit (not shown) formed in the main body case 10. It is supplied into the room through the outside air supply hole 18 formed in the.

On the other hand, the indoor air inlet 20 is formed on the side of the external air supply hole 18, the indoor air is sucked into the main body case 10 of the ventilation device. In addition, an indoor air exhaust hole 22 through which the indoor air sucked into the inside of the ventilator from the indoor air inlet 20 is formed at a side surface of the external air inlet 12.

2 is an exploded perspective view of the mounting structure of the check door 30, Figure 3 shows a state in which the check door 30 is mounted.

As shown in these drawings, the front of the main body case 10 is formed with a check opening 40 through which the heat exchanger and the like can enter and exit, such that the check opening 40 is selectively opened and closed. do.

The inspection door 30 is composed of a substantially rectangular flat plate to shield the inspection hole 40 directly, and the side guide (34) extending vertically bent forward from the side end of the shielding surface (32) 34 '), and the upper and lower ends may be formed by bending the end portion 36 to vertically bend forward from the upper and lower ends of the shielding surface 32.

In addition, the left side guide 34 of the check door 30 has a bracket insertion groove 34a into which the left bracket 38 to be described below is inserted. The left bracket 38 is further installed on the main body case 10 to support the left side of the check door 30.

Therefore, the left bracket 38 is inserted into the bracket insertion groove 34a to fix the check door 30. That is, the right end of the left bracket 38 is inserted into the bracket insertion groove 34a and the left end is fastened to the main body case 10 so that the left side of the inspection door 30 is connected to the main body case 10. Make it tight.

On the other hand, the right side of the inspection port 40 is provided with a right bracket 42 for fixing the right side guide 34 'of the inspection door 30. The right bracket 42 is a mounting portion 42a which is a part fastened to the main body case 10, a side portion 42b extending vertically bent forward from the mounting portion 42a, and a tip end of the side portion 42b. It consists of the front part 42c formed by bending vertically from the left side.

Therefore, when the mounting portion 42a of the right bracket 42 is mounted to the main body case 10 by a screw or the like, the front portion 42c of the right bracket 42 is connected to the inspection door 30. The right side of the check guide 30 is fixed in contact with the tip of the right side guide 34 '.

The conventional ventilation device inspection door as described above has the following problems.

In the conventional inspection door 30 mounting structure, the left side of the inspection door 30 is fixed by the left bracket 38, and the right side is configured to be fixed by the right bracket 42.

That is, the right side guide 34 'of the inspection door 30 is inserted and fixed between the front portion 42c of the right bracket 42 and the front of the main body case 10, but the inspection door ( Sliding occurs between the front portion 42c and the front end portion of the right side guide 34 'by the weight of 30). As a result, the right side of the inspection door 30 sags downward. The deflection of the door 30 is well illustrated in FIG. 3.

In this case, the inspection door 30 does not completely shield the inspection opening 40, and thus the upper right side of the inspection opening 40 is partially opened as shown in FIG. 3. Therefore, while the air inside is leaked to the outside or the outside air is introduced into the ventilator, the ventilation of the room is not properly performed, while the thermal efficiency of the ventilator is reduced.

In addition, the deflection of the check door 30 as described above may occur when the right bracket 42 is not correctly mounted due to a worker's work failure. On the other hand, the check door 30 is initially correctly mounted. Even if it is, even if there is a gap between the right bracket 42 and the right side guide 34 'of the check door 30 occurs as the use continues.

Accordingly, an object of the present invention is to solve the problems of the prior art as described above, and to provide an inspection door mounting structure in which an inspection door for shielding an inspection opening of a ventilation system is correctly mounted.

Another object of the present invention is to provide an inspection door mounting structure of a ventilation system that can be easily opened and closed.

In order to achieve the above object, the inspection door mounting structure of the ventilation system according to the present invention is provided with an inspection door that forms an internal inspection and an internal parts exchange window on one side of the main body case, and the inspection door is formed by an inspection door. In the ventilation system to open and close; On one side of the main body case and the inspection door, a locking rib for mounting the inspection door and a rib fixing tool on which the locking rib is engaged are formed to correspond to each other.

The rib fixing tool is provided to protrude forward on the front surface of the main body case in which the check opening is formed, the locking rib is formed in the check door.

The rib fixing tool includes a rib seating portion provided on the front surface of the main body case, and a rib guide portion extending from the tip of the rib seating portion to guide the locking rib to the rib seating portion.

The rib guide portion of the rib fixing tool is inclined forward from the tip of the rib seating portion.

According to the inspection door mounting structure of the ventilation system according to the present invention having such a configuration, the reduction of heat exchange efficiency due to the poor coupling of the inspection door is prevented, there is an advantage that the opening and closing of the inspection door is easier.

4 schematically illustrates an example of a ventilation system according to the present invention in an exploded perspective view, and FIG. 5 shows an internal configuration of the ventilation system according to the present invention. 6, the configuration of the heat exchanger and the support frame according to the present invention is shown in cross section. On the other hand, Figure 7a shows the inspection door mounting structure according to the present invention in an exploded perspective view, Figure 7b shows an embodiment of the mounting structure of the inspection door according to the present invention in a front view.

As shown in these figures, a substantially rectangular box-shaped body case 50 forms an appearance. The body case 50 forms the appearance of the entire product, and supports the installation of the internal structure to protect, and at the same time serves to block foreign matter from entering the product from the outside.

On the left side of the main body case 50, an external air inlet 52, which is an inlet for inhaling external air, is installed to protrude laterally. An inlet mounting hole (not shown) is formed at the left end of the main body case 50 so that the external air inlet 52 is inserted and mounted therein.

Inside the outside air inlet 52, a left suction duct 54 is disposed between the outside air intake 52 and the heat exchanger 60 so that the outside air drawn from the intake 52 can reach the heat exchanger 60, which will be described below. Is formed. That is, the left suction duct 54 serves as a suction passage that guides the outside air to be sucked smoothly.

An internal heat exchanger 60 is provided at an inner central portion of the main body case 50. The heat exchanger (60) has a hexagonal columnar shape and has a cross-flow plate type structure. That is, it is configured to separate the supply and exhaust passages with a partition plate of special processed paper so that outside air and indoor air are not mixed with each other.

Therefore, the heat exchanger 60 as described above allows each air having a temperature difference to pass through different flow paths, thereby allowing moisture and sensible heat to exchange latent heat by a high-efficiency heat exchanger film forming layers of the different flow paths. Heat exchange causes heat exchange. That is, the special processing paper used for the total heat exchanger 60 is characterized by passing only heat and moisture without passing air.

The total heat exchanger (60) having the configuration described above performs electrothermal exchange between the air supply and the exhaust in the apparatus, absorbs the heat of the air from the exhaust to the outside, and transfers it to the air supplied to the room, whereby the state of the indoor air is Make it less affected.

This electrothermal ventilation mode may be implemented by the user's selection. That is, in general, the heat transfer ventilation mode as described above is mainly used in summer and winter when the temperature difference between indoor and outdoor is large. By changing the passage of the air discharged to the outside to prevent the air exhausted to pass through the heat exchanger 60, it is also possible to use in the normal ventilation mode.

On the other hand, the upper and lower ends of the heat exchanger 60 having a hexagonal cross-section is provided with a support frame 61, the heat exchanger 60 long before and after. The support frame 61 supports the load of the total heat exchanger 60 so that the total heat exchanger 60 is firmly supported, and also serves as a guide rail when the front heat exchanger 60 is attached and detached.

The support frame 61 of the heat exchanger 60 is an element support part 62 for guiding forward and backward movement while supporting the load of the heat exchanger 60, and a filter extending laterally from the element support part 62. It consists of a support part 63.

The element support portion 62 is composed of a main body contact surface 62 'contacting the main body case 50, and an element contact surface 62 "formed to protrude upward from both ends of the main body contact surface 62'. The element support portion 62 has a central portion recessed to form a tunnel shape. The lower end portion of the tunnel shape is in contact with the main body case 50, and the filter support portion 63 is formed of the element support portion 62. And an inclined surface 63 'which is formed to be inclined laterally downward from the side end, and a bent rib 63 "which is formed to be bent vertically from the inclined surface 63'.

Side guides 64 are provided at the side edges of the heat exchanger 60. The side guide 64 is composed of an element support portion 65 surrounding the edge of the heat exchanger 60, and a filter support portion 66 protruding from the element support portion 65. The filter support portion 66 is composed of a vertical surface 66 'protruding vertically from the element support portion 65, and a bending rib 66 "formed laterally bent from the vertical surface 66'.

That is, the element support portion 65 of the side guide 64 is provided in the corner of the heat exchanger 60 is formed in a substantially 'b' shape so as to be in contact with both sides of the corner at the same time, the 'b' shaped A pair of filter support portions 65 are formed to protrude from each surface of the element support portion 65.

Accordingly, the prefilter 68 is mounted to slide forward and backward between the support frame 61 and the filter support 63 of the side guide 64 facing each other. The prefilter 68 is provided to both sides of the lower portion of the total heat exchanger (60) to filter the foreign matter in the air.

That is, the pre-filter 68 provided on the lower left side of the total heat exchanger 60 into which the external air is sucked increases the cleanliness of the air supplied to the room by filtering out the foreign matter mixed in the external air, and the heat exchanger 60 ) Protects against foreign objects. In addition, the pre-filter 68 provided on the lower right side of the heat exchanger (60) filters the foreign matter mixed in the air exhausted from the inside to the outside, thereby protecting the heat exchanger (60) to extend the life. Will be

The total heat exchanger (60) is generally provided with two before and after, such a heat exchanger (60) is supported by the support frame 61 of the heat exchanger (60) and slide back and forth. Therefore, the front surface of the heat exchanger 60 is further provided with a handle 71 for facilitating forward and backward movement.

A high performance filter 73 is further provided on the upper right side of the total heat exchanger 60. The high performance filter 73 serves to filter back the dust particles in the intake air. In other words, the pre-filter 68 of the fibrous mat form, the large dust in the air is first filtered, the heat is transferred while passing through the heat exchanger 60, the air passed through the heat exchanger (60) Is filtered by the high-performance filter 73 to fine foreign matter again.

On the other hand, the left rear end of the main body case 50 is provided with an indoor air outlet 56 for discharging the indoor air to the outside, the outlet 56 is an outlet mounting hole (shown in the main body case 50) Not inserted) and fixed. In addition, an exhaust fan housing 58 is formed inside the outlet mounting hole to guide the indoor air forcedly blown by the exhaust fan 80 to the indoor air outlet 56.

An indoor air exhaust fan 80 is provided inside the exhaust fan housing 58. The exhaust fan 80 serves to forcibly blow the air sucked through the indoor air intake port 88 to be described below to the discharge port 56. Preferably, the exhaust fan 80 is configured as a siroco fan.

An external air outlet 82 is formed at the right end of the main body case 50, that is, on the side opposite to the position at which the external air inlet 52 is installed. The outlet 82 is inserted into the outlet mounting hole 84 formed on the right side of the main body case 50 and is installed to protrude in a right direction from the right side of the main body case 50 to the right side. In addition, an air supply fan housing 86 is formed in the air outlet mounting hole 84 to guide external air forcedly blown from the air supply fan 96 to the air outlet 82 to be described below.

An indoor air suction port 88 is provided at the right rear end of the main body case 50, that is, the opposite side to the position where the indoor air discharge port 56 is installed. The indoor air inlet 88 is installed to protrude from the right side of the main body case 50 to the right side, and is fixed to the circular indoor inlet mounting hole 90 formed at the rear end of the right side of the main body case 50. do. In addition, a right suction duct 92 is formed inside the indoor suction hole mounting hole 90 to guide the air sucked from the indoor air suction hole 88 to the heat exchanger 60.

On the other hand, a damper 94 is provided inside the right suction duct 92 to selectively flow the indoor air sucked through the indoor air suction port 88 to the heat exchanger 60. That is, the damper 94 opens and closes the right suction duct 92 under the control of the control box 100 to be described below. Therefore, if the damper 94 shields the right suction duct 92, the indoor air sucked through the indoor air intake port 88 does not pass through the heat exchanger 60, and the indoor air outlet 56 Is discharged to the outside through).

An air supply fan 96 is provided between the external air outlet 82 and the indoor air outlet 56 to force external air to the external air outlet 82. Therefore, the outside air sucked through the outside air inlet 52 is discharged into the room through the outside air outlet 82 by the air supply fan 96.

The front of the main body case 50 is provided with a control box 100 to be described below, the ceiling fixture 102 is further installed so that the ventilation system is installed on the ceiling of the house. On the other hand, the front opening of the main body case 50, the inspection opening 104 is formed, the front of the inspection opening 104 is provided with a check door 110 to be described below to selectively open and close the inspection opening 104 do.

The control box 100 is installed at the right end of the main body case 50. A control unit is formed inside the control box 100 to control the operating conditions of the ventilation system. That is, the power is interrupted to turn on / off the ventilation system, and the fan speed is controlled by controlling the fan rotation speed of the air supply fan 96 and the exhaust fan 80. On the other hand, by controlling the driver (not shown) of the damper 94 controls the ventilation method and the like to enable the selection of the total heat exchange mode or the general ventilation mode.

 An inspection door 110 is installed in front of the inspection opening 104 to shield the inspection opening 104. Therefore, when it is necessary to replace or inspect the internal parts including the heat exchanger 60, the inspection door 110 may be opened and the heat exchanger 60 may be taken out to work.

The inspection door 110 is formed of a substantially rectangular flat plate to shield the inspection hole 104 directly, and the left guide surface formed by extending vertically bent forward from the left end of the shield plate 112 ( 114 and a right guide surface 116 extending vertically bent forward from the right end of the shielding plate 112.

In addition, the upper and lower ends of the shielding plate 112 may be further formed with a bent end 118 that is bent forward, and a central portion of the left guide surface 114 to facilitate opening and closing of the inspection door 110. A left handle 114 'is formed at the right side, and a right handle 116' is formed at the center of the right guide surface 116.

The inspection door 110 having the above configuration is mounted to the main body case 50 by fastening means provided in the front surface 50 ′ of the main body case 50 and the inspection door 110. Therefore, the locking door 120 is formed on the inspection door 110.

The locking ribs 120 are fitted to the rib fixture 130 formed on the front surface 50 'of the main body case, which will be described below, and are preferably radially formed at four corners of the inspection door 110. .

The front surface 50 ′ of the main body case 50 is provided with a rib fixing tool 130 for mounting the inspection door 110. Preferably, the rib fixing tool 130 is formed to protrude forward from the front surface 50 'of the main body case 50, and the inspection opening 104 is a position corresponding to the locking rib 120 of the inspection door 110. Four corners are formed.

In addition, the rib fixture 130 is a mounting portion 132 is fixed to the front surface 50 'of the main body case 50 with a screw (S), and extending from the mounting portion 132 a predetermined portion protrudes forward A rib seating portion 134 for fixing the locking rib 120 and a rib guide portion 136 is formed to be inclined at a predetermined angle from the front end of the rib seating portion 134 forward.

Therefore, when the locking rib 120 is inserted into the rib seating portion 134 which is guided from the tip of the rib guide portion 136 and protrudes forward to form a predetermined groove, the opposite direction from the outside again. As long as a constant force is not applied, the inspection door 110 is fixed to the front surface 50 'of the main body case.

Hereinafter, a state in which air outside the room flows through the ventilation system according to the present invention having the configuration as described above will be described with reference to FIGS. 8 and 9.

8 shows a state of air flow through the ventilation system when the full heat ventilation mode is activated. This electrothermal ventilation mode is generally used when there is a large difference in temperature and humidity between indoors and outdoors, such as summer or winter.

Referring to the ventilation state as shown in the drawing, the damper 94 opens the right suction duct 92 according to a control command in the control box 100 according to the user's selection of the heat transfer ventilation mode.

In addition, according to the operation of the air supply fan 96, external air is sucked into the ventilation system through the external air inlet 52, and the external air is guided by the left suction duct 54 to transfer the heat. It is sucked into the total heat exchanger (60) through the lower left side of the exchanger (60). At this time, since the external air passes through the pre-filter 68 mounted on the lower left side of the heat exchanger (60), foreign matter in the air is first filtered and then sucked into the heat exchanger (60).

The air sucked into the heat exchanger (60) exchanges heat and moisture from the discharged indoor air and then is discharged through the upper right side of the heat exchanger (60). At this time, since the high-performance filter 73 is installed on the upper right side of the heat exchanger (60), foreign matters of the air passing through the heat exchanger (60) are filtered again, resulting in cleaner air.

Air passing through the heat exchanger 60 and the high performance filter 73 is forcibly blown by the air supply fan 96 through an external air outlet 82 installed on the right side of the main body case 50. It is discharged to the room.

On the other hand, the indoor air is exhausted to the outside by the operation of the exhaust fan 80, the indoor air is sucked into the ventilation system through the indoor air inlet 88 and then guided by the right suction duct 92 And is sucked into the total heat exchanger (60) through the lower right side of the total heat exchanger (60).

At this time, since the pre-filter 68 is mounted on the lower right side of the heat exchanger 60, foreign matter in the indoor air is filtered out. Therefore, since the clean air is sucked into the heat exchanger (60), the heat exchanger (60) is protected and its life is extended more.

The indoor air sucked into the heat exchanger (60) exchanges heat and moisture to outside air sucked from the outside, and then exits through the lower left side of the heat exchanger (60). The indoor air exiting the heat exchanger (60) is forcedly blown by the exhaust fan (80) and exhausted to the outside through the indoor air outlet (56) provided at the rear end of the left side of the main body case (50). .

Next, an air flow state in the general ventilation mode will be described with reference to FIG. 9. In the general ventilation mode, when indoor and outdoor temperature and humidity differences are small, such as spring or autumn, indoor air is bypassed by the heat exchanger 60 and bypassed immediately.

Therefore, when the user selects the general ventilation mode, the damper 94 shields the right suction duct 92 according to a control command inside the control box 100. In this case, the air sucked through the indoor air intake port 88 is forcibly blown to the indoor air outlet 56 by the exhaust fan 80 and discharged to the outside without passing through the heat exchanger 60.

On the other hand, when looking at the flow of the outside air, according to the operation of the air supply fan 96, the outside air is sucked into the ventilation system through the outside air inlet 52, the outside air is the left side suction duct (54) It is guided by) and is sucked into the heat exchanger 60 through the lower left side of the heat exchanger (60). At this time, since the external air passes through the pre-filter 68 mounted on the lower left side of the heat exchanger (60), foreign matter in the air is first filtered and then sucked into the heat exchanger (60).

Since the air sucked into the heat exchanger (60) does not pass through the heat exchanger (60), the discharged indoor air is discharged through the upper right side of the heat exchanger (60) without exchanging heat and moisture. At this time, since the high-performance filter 73 is installed on the upper right side of the heat exchanger (60), foreign matters of the air passing through the heat exchanger (60) are filtered again, resulting in cleaner air.

Air passing through the heat exchanger 60 and the high performance filter 73 is forcibly blown by the air supply fan 96 through an external air outlet 82 installed on the right side of the main body case 50. It is discharged to the room.

As described above, in the general ventilation mode, unlike in the case of the total heat ventilation mode, heat and moisture are not exchanged inside the heat exchanger 60.

On the other hand, looks at the detachment process of the check door 110 according to the present invention.

First, the process of mounting the inspection door 110 on the front surface 50 'of the main body case 50, first, the left handle 114' and the right handle 116 'of the inspection door 110 While holding the inspection door 110 by hand, the inspection door 110 is inclined in a clockwise direction, that is, a portion to the right, the shield plate 112 of the inspection door 110 is the main body case ( And moves rearward to closely contact the front surface 50 'of the 50).

After the inspection door 110 is in close contact with the front surface 50 'of the main body case, the inspection door 110 is held in a state where the left handle 114' and the right handle 116 'of the inspection door 110 are held. In the counterclockwise direction, the locking rib 120 is guided to the rib seating part 134 while contacting the rear surface of the rib guide part 136 of the rib fixing tool 130.

That is, the rib fixing tool 130 is in a state of elasticity because the mounting portion 132 is fixed to the front surface 50 'of the main body case by a screw (S). Therefore, when the locking rib 120 is guided to the rib guide part 136 and moved to the rib seating part 134, the rib fixing tool 130 is bent forward, so that the locking rib 120 is seated on the rib. The unit 134 is reached.

When the locking rib 120 reaches the rib seating part 134 as described above, the rib seating part 134 forms a recess that protrudes a predetermined portion forward, so that the check door 110 is fixed clockwise. As long as it does not rotate more than a force, it will maintain the state like FIG. 7B.

Next, look at the process of removing the inspection door 110 from the body case 50. The removal process of the inspection door 110 is performed in the reverse order of the mounting process described above.

That is, as shown in FIG. 7B, the left handle 114 ′ and the right handle 116 ′ are handled while the check door 110 is mounted on the front surface 50 ′ of the main body case 50. When turned to the clockwise rotation, the locking rib 120 is released from the rib seating portion 134 of the rib fixture 130 is removed via the rib guide portion 136.

In this way, the inspection door 110 according to the present invention is mounted on the front surface 50 'of the main body case by rotating the inspection door 110 in a counterclockwise direction, and is easily separated by rotating in the clockwise direction. Is completed.

The scope of the present invention is not limited to the above-exemplified embodiments, and many other modifications based on the present invention will be possible to those skilled in the art within the above technical scope.

For example, in the above embodiment, the rib fixing tool 130 is provided on the front surface 50 'of the main body case 50, and the locking rib 120 is formed on the inspection door 110. On the contrary, it may be possible to form the locking ribs 120 on the front surface 50 'of the main body case and to have the rib fixing tool 130 on the inspection door 110.

Meanwhile, in the above embodiment, the rib fixture 130 is formed as a separate structure, but configured to be mounted to the body case 50 by a screw S, but the rib fixture 130 is not formed as a separate structure. Of course, it can also be formed integrally with the main body case 50 or the inspection door 110.

According to the inspection door mounting structure of the ventilation system as described above, the front surface of the main body case is formed rib ribs protruding forward, and the inspection door is formed with a locking rib that is inserted into the rib fixture. The locking fixture includes a rib seating portion in which the locking ribs are seated and fixed, and a rib guide portion for guiding the locking ribs to the rib seating portion.

Therefore, if the inspection door is turned in the counterclockwise direction in close contact with the main body case, the installation of the inspection door is completed. In this state, the inspection door is rotated clockwise and pulled out to remove the inspection door. There is an effect of reducing the labor required to remove the inspection door.

In addition, since the inspection door is in close contact with the main body case, the sealing of the inspection opening is more secured than in the related art, and therefore, external leakage of air is prevented, thereby improving heat exchange efficiency.

As a result, since the exchange of the outside and the internal air through the inspection opening is prevented, there is an advantage that the reduction in heat exchange efficiency due to the misalignment of the inspection opening as in the prior art is prevented in advance, and the outside air flows into the room through the inspection opening. Because it is prevented will be able to maintain a more comfortable indoor environment.

1 is a perspective view of a ventilation apparatus according to the prior art.

Figure 2 is an exploded perspective view showing the configuration of the ventilation apparatus check door mounting structure according to the prior art.

Figure 3 is a front view showing an embodiment of the ventilation apparatus check door mounting structure according to the prior art.

Figure 4 is an exploded perspective view showing the main configuration of the ventilation system employing a preferred embodiment of the ventilation system check door mounting structure according to the present invention.

Figure 5 is a cut-away perspective view showing the internal configuration of the ventilation system employing a preferred embodiment of the ventilation system check door mounting structure according to the present invention.

Figure 6 is a partial front view showing the installation state of the total heat exchanger that is the main configuration of the ventilation system according to the present invention.

Figure 7a is an exploded perspective view showing the main configuration of a preferred embodiment of the ventilation system check door mounting structure according to the present invention.

Figure 7b is a front view showing a state equipped with a preferred embodiment of the ventilation system check door mounting structure according to the present invention.

8 is a state diagram showing a state in which air flows inside the ventilation system according to the present invention during the full-heat ventilation mode operation.

9 is a state diagram showing a state in which air flows inside the ventilation system according to the present invention during the normal ventilation mode operation.

Explanation of symbols on the main parts of the drawings

50. Main body case 52. External air intake

54. Left suction duct 56. Indoor air outlet

58. Exhaust Fan Housing 60. Heat Exchanger

61. Support frame 62. Device support

63. Filter support 68. Prefilter

71. Handle 73. High Performance Filter

80. Exhaust fan 82. External air outlet

84. Outlet mounting hole 86. Air supply fan housing

88. Indoor air intake port 90. Indoor air intake hole

92. Right suction duct 94. Damper

96. Air supply fan 100. Control box

102. Ceiling Fixture 104. Checking Fixture

110. Inspection door 112. Shield plate

114. Left side guide 114 '. Left handed

116. Right side guide plane 116 '. Right handed

120. Jam rib 130. Rib fixture

132. Mounting section 134. Rib mounting section

136. Rib Guide

Claims (4)

delete delete In one side of the main body case is provided with an inspection opening for the internal inspection and the internal parts replacement window, the inspection opening in the ventilation system that is opened and closed by the inspection door; A rib fixing tool is formed to protrude forward from the front surface of the main body case, and the inspection door is provided with a locking rib which is formed to correspond to the rib fixing tool and walks with each other so that the inspection door can be mounted to the main body case; The rib fixture, Ventilation characterized in that it comprises a rib seating portion provided on the front surface of the main body case for fixing the locking ribs and extending from the tip of the rib seating portion and a rib guide portion for guiding the locking ribs to the rib seating portion. Check door mounting structure of system. 4. The inspection door mounting structure of claim 3, wherein the rib guide portion of the rib fixing tool is inclined forward from the tip of the rib seating portion.