KR100705057B1 - Ventilation system - Google Patents

Abstract

The present invention relates to a ventilation system in which the fan and the motor are more easily removable.

Ventilation system according to the present invention, the fan (150, 170) for forcing the flow of air; Fan housings (152 and 172) for guiding air flowing by the fans (150 and 170); Shrouds (160, 182) partially shielding one end of the fan housing (152, 172); Motors 154 and 176 which provide rotational power to the fans 150 and 170; Motor mounts 156 and 178 for supporting the motors 154 and 176; Has an orifice (164,186) for guiding air flowing into the fan (150,170); The shrouds 160 and 182 are fixedly installed in the fan housings 152 and 172, and the fans 150 and 170, the motors 154 and 176, the orifices 164 and 186, and the motor mounts 156 and 178 are integrally formed on the shrouds 160 and 182. It is detachably installed at the same time. According to the present invention as described above, there is an advantage that the work efficiency during the after-service is improved.

Ventilation system, total heat exchange element, fan, motor

Description

Ventilation system

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

Figure 2 is a perspective view showing a pre-filter and the total heat exchange element of the ventilation system according to the prior art.

Figure 3 is an exploded perspective view of the fan and the motor constituting the ventilation system according to the prior art.

Figure 4 is a perspective view showing the appearance configuration of a preferred embodiment of the ventilation system according to the present invention.

Figure 5 is a perspective view showing the internal configuration of the ventilation system in a state in which the total heat exchange element constituting a preferred embodiment of the ventilation system according to the present invention is removed.

Figure 6 is a perspective view showing the internal configuration of the ventilation system in a state where the total heat exchange element constituting a preferred embodiment of the ventilation system according to the present invention.

7 is a right sectional view of a preferred embodiment of the ventilation system according to the present invention.

8 is an exploded perspective view of a preferred embodiment of the ventilation system according to the present invention.

9 is an exploded perspective view of a fan and a motor constituting a preferred embodiment of the ventilation system according to the present invention.

10 is a plan sectional view showing a state in which air flows through the interior of the ventilation system according to the present invention.

Figure 11 is a state diagram showing an open state of the inspection door constituting a preferred embodiment of the ventilation system according to the present invention.

Explanation of symbols on the main parts of the drawings

110. Outer case 112. Upper cabinet

114. Left side plate 116. Right side plate

120. Outside air inlet 122. Indoor air outlet

124. Indoor air inlet 126. External air outlet

130. Heat exchange element 140. Lower support

142. Upper support 144. Left support

146. Right Support 150. Air Supply Fan

152. Air supply fan housing 154. Air supply motor

156. Supply motor mount 158. Supply fan rotation shaft

160. Air supply shroud 162. Air supply

164. Supply Orifice 166. Fastening Screw

168. Air supply bracket 170. Exhaust fan

172. Exhaust fan housing 174. Exhaust fan rotation shaft

176. Exhaust Motor 178. Exhaust Motor Mount

180. Exhaust Bracket 182. Exhaust Shroud

184. Exhaust hole 186. Exhaust orifice

190. Barrier 192. Center Bracket

194.Air Guide 200.Check Door

202. Element Door 204. Fan Door

206. Hinge

The present invention relates to a ventilation system, and more particularly to a ventilation system that is easier to remove the fan and motor.

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, a place where many people stay in a narrow space, such as an office or a vehicle, should be frequently ventilated. In this case, a ventilation system using a total heat exchange method is usually used. 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 a conventional ventilation system, a heat exchanger and a prefilter of a conventional ventilation system are shown in FIG. 2, and a motor assembly mounting structure of the conventional ventilation system is shown in an exploded perspective view. .

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 intake duct (not shown) is provided inside the external air inlet 12 so as to allow external air sucked from the external air inlet 12 to reach the heat exchanger 14 to be described below. Is formed) to be a passage of external air.

In order to exchange heat between the air sucked from the outside and the air discharged from the outside to the outside, an electrothermal heat exchanger 14 as shown in FIG. 2 is provided at the inner center of the main body case 10. It is configured to have.

As described above, the total heat exchanger (14) exchanges sensible heat with moisture for exchanging latent heat by means of highly efficient heat exchange membranes that form layers of different flow paths by allowing each air having a temperature difference to pass through different flow paths. Follow the principle of electrothermal exchange by heat.

The external air passing through the heat exchanger 14 from the external air inlet 12 is provided on the side opposite to the external air inlet 12 by an external air supply unit (not shown) formed in the main body case 10. It is supplied to the room through the external air supply hole 16 is formed.

On the other hand, the indoor air inlet 18 is formed on the side of the external air supply hole 16, the indoor air is sucked into the main body case 10 of the ventilation system. In addition, an indoor air exhaust hole 20 through which the indoor air sucked into the ventilation system from the indoor air intake port 18 is formed at the side surface of the external air intake port 12.

At four corners of the heat exchanger 14, a total heat exchanger support frame 22 is formed long before and after the preheater 14, and a pre-filter 24 is installed on both lower sides of the heat exchanger 14. As shown in FIG. The prefilter 24 serves to filter foreign matter mixed in the outside air, and the prefilter 24 is formed separately from the heat exchanger 14 and is detached.

On the other hand, the left and right sides of the heat exchanger as described above are provided with a fan (pan) for forcibly discharging the indoor air to the outside, and a fan (fan) for forcing the outdoor air to flow into the room, respectively, FIG. ) And the mounting structure of the motor are shown in exploded perspective view.

As shown in the drawing, the fan assembly includes a blowing fan 30, a motor assembly 32 providing rotational power to the blowing fan 30, and a motor mount 34 supporting the motor assembly 32. And a shroud 36 to which the motor mount 34 is fastened.

The blowing fan 30 is composed of a sirocco fan, and serves to force the indoor air to the outside or to force the outdoor air into the room. In addition, one side end of the blower fan 30 is coupled to the motor assembly 32 which generates rotational power by electric force and rotates.

The bottom surface of the body case 10 is provided with a shroud 36 to be perpendicular thereto. In addition, a motor mount 34 is formed at one end of the shroud 36, and the motor assembly 32 is mounted and fixed to the motor mount 34.

On the other hand, the motor mount 34 is fastened to the shroud 36. Accordingly, a plurality of mounting holes 36 ″ in which the motor mount 34 is mounted are provided at upper and lower portions of the through holes 36 ′ formed in the shroud 36. Through-holes 34 ′ corresponding to the mounting holes 36 ″ of the shroud 36 are formed at upper and lower ends.

In addition, one side of the shroud 36 is provided with a support (40). As shown, the support 40 is provided in pairs up and down to support the shroud 36 and the motor mount 34, the support 40 is provided on the outside of the blower fan (30) And fixedly installed in a fan housing (not shown) for guiding air. In addition, the support 40 is formed with a fastening hole 40 'to which the screw 38 is fastened.

Therefore, when the screw 38 penetrates the mounting hole 36 "and the through hole 34 'and is fastened to the fastening hole 40' of the support 40, the motor mount 34 and the shroud ( 36 is fixed to the support 40 is mounted.

However, the conventional ventilation system as described above has the following problems.

In the conventional configuration as described above, the motor assembly 32, the motor mount 34, and the shroud 36 are fastened to the support 40. Therefore, in order to separate the blower fan 30 or the motor assembly 32, there is a problem in that the shroud 36 must be separated as well as the motor mount 34. That is, after-sales service work of the blower fan 30 and the motor assembly 32 is difficult.

Accordingly, an object of the present invention is to solve the problems of the prior art as described above, and to provide a ventilation system in which a fan and a motor are easily attached and detached.

Ventilation system according to the present invention for achieving the object as described above, the outer case forming the upper appearance; An electrothermal exchange element installed inside the outer case to allow heat exchange between the outside and the air; A fan installed inside the outer case to force the flow of air; A fan housing provided at an outer side of the fan to guide air flowing by the fan; A shroud provided at one side of the fan housing and partially shielding one end of the fan housing; A motor providing rotational power to the fan; Has a configuration including a motor mount for supporting the motor; The fan, the motor, and the motor mount are integrally mounted to the shroud so as to be detachably installed.

The shroud is characterized in that fixed to the fan housing.

At one side of the motor mount, an orifice for guiding air flowing into the fan is further provided.

The orifice and the motor mount are fastened to the shroud by the same fastening member.

According to the ventilation system according to the present invention having such a configuration, there is an advantage that the work efficiency during the after-service is improved.

4 shows an external perspective view of the ventilation system according to the present invention, and FIGS. 5 and 6 show internal configurations of the ventilation system according to the present invention, respectively. That is, the state in which the total heat exchange element is removed is illustrated in FIG. 5, and the state in which the total heat exchange element is installed is illustrated in FIG. 6.

7 and 8 illustrate a cross-sectional right side view and an exploded perspective view of the ventilation system according to the present invention, respectively, and FIG. 9 shows an exploded perspective view of the air supply fan and the air supply motor constituting the ventilation system according to the present invention. .

As shown in these figures, an outer case 110 having a substantially rectangular box shape forms an appearance. The outer case 110 forms the appearance of the upper side, front, rear, left and right sides of the product, supports and protects the installation of the internal structure, and at the same time serves to block foreign matter from entering the product from the outside.

The outer case 110 is largely composed of an upper cabinet 112, a left plate 114, a right plate 116, and the like. The upper cabinet 112 is to shield the upper and front and rear surfaces of the ventilation system according to the present invention, as shown in the upper plate 112a, the front plate 112b and the rear plate 112c. Therefore, the upper cabinet 112 has a '∩' shape when viewed from the side.

In the front plate 112b of the outer case 110, an external air inlet 120 through which external air is sucked is installed to protrude forward. That is, the inlet mounting hole 120 'is formed near the right end of the front plate 112b of the upper cabinet 112, and the external air inlet 120 is installed in the inlet mounting hole 120'.

The inlet mounting hole 120 'is shaped into a fan shape as shown. That is, a part of the circular shape is formed into a shielded fan shape, and the shielded part corresponds to the right end edge portion of the heat exchange element 130 to be described below.

The indoor air outlet 122 is further installed on the front plate 112b of the outer case 110. The indoor air outlet 122 is a portion that is formed to protrude to a certain portion forward like the external air inlet 120 and is coupled to a connection duct (not shown).

Therefore, the outlet mounting hole 122 'is formed near the left end of the outer case 110 and the front plate 112b. That is, the outlet mounting hole 122 ′ is formed to pass through the front plate 112 b of the upper cabinet 112, and becomes a passage for allowing air to flow through the indoor air outlet 122.

An indoor air inlet 124 is formed at the right end of the rear side (back) of the outer case 110, that is, at the opposite side to the position where the external air inlet 120 is installed. The indoor air inlet 124 is connected to the indoor suction hole mounting hole 124 ′ formed near the right end of the rear plate 112 c of the outer case 110, and is connected to the rear plate 112 c of the outer case 110. Protrudes to a predetermined size from the back.

As shown in the drawing, the indoor suction hole mounting hole 124 'is shaped like a fan like the suction hole mounting hole 120'. That is, it has a fan shape so that a portion of the rear right end of the heat exchange element 130 to be described below is shielded.

The outside air outlet 126 is installed at the left end of the rear plate 112c of the outer case 110, that is, at the opposite side of the position where the indoor air outlet 122 is installed. The external air outlet 126 is installed to protrude rearward from the rear plate (112c) of the outer case 110, the indoor exhaust outlet mounting is formed near the left end of the rear plate (112c) of the outer case (110) It is connected to the hall (not shown).

The heat exchange element 130 is provided in the inner right space of the outer case 110. The heat exchange element 130 has a rectangular pillar 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 exchange element 130 as described above typically allows each air having a temperature difference to pass through different flow paths, thereby allowing moisture and sensible heat to exchange latent heat by high-efficiency heat exchange membranes forming layers of different flow paths. Heat exchange causes heat exchange. That is, the special processing paper used for the total heat exchange element 130 is characterized in that the air can not pass through, only heat and moisture can pass through.

The total heat exchange element 130 having the above-described configuration performs the total heat exchange between the air supply and the exhaust in the apparatus, absorbs the heat of the air from the exhaust going to the outside, and transfers the air to the air supplied to the room. Make it less affected by external air.

The lower support 140 is formed at the lower end of the total heat exchange element 130. The lower support 140 is to fix and support the lower edge of the heat exchange element 130 having a rhombus cross section, and is formed long before and after the front and rear ends of the upper cabinet 112 and the front plate 112b. It is preferable to be fixed to the plate 112c, respectively.

In addition, an upper support 142 having a shape symmetrical to the lower support 140 is provided on the upper side of the total heat exchange element 130. The upper support 142 is installed long before and after the lower support 140 to securely support the upper end of the heat exchange element (130).

In addition, although not shown, one side of the heat exchange element 130 may be further provided with a pre-filter for filtering foreign matter in the air passing through the heat exchange element 130. That is, a pre-filter is provided at one side to filter foreign substances in the air flowing into the room through the electrothermal exchange element 130.

The left support 144 and the right support 146 are further provided on the left and right sides of the total heat exchange element 130, respectively. The left support 144 and the right support 146 support the left and right ends of the heat exchange element 130, respectively. The left support 144 is fixed to the barrier 190 to be described below, the right support 146 is preferably fixed to the air guide 194 to be described below.

An air supply fan 150 is installed on the left side of the total heat exchange element 130. That is, the air supply fan 150 is provided on the left side of the second half of the total heat exchange element 130.

The air supply fan 150 forcibly sucks the outside air through the outside air inlet port 120 to be forced out to the outside air outlet 126. That is, to force the flow of air, preferably composed of a sirocco fan (sirocco fan).

An air supply fan housing 152 is installed outside the air supply fan 150. The air supply fan housing 152 is installed outside the air supply fan 150 to surround the air supply fan 150, and guides a flow of air flowing by the air supply fan 150.

An air supply motor 154 is provided inside the air supply fan 150. The air supply motor 154 generates rotational power by the power supplied from the outside, and supplies the supplied air to the air supply fan 150. Therefore, the air supply fan 150 is rotated by the rotational power of the air supply motor 154.

The air supply motor 154 is fixedly supported by the air supply motor mount 156. That is, the lower end of the air supply motor 154 is fixed to the air supply motor mount 156. In addition, mount through holes 156 ′ are formed at edges of the air supply motor mount 156, respectively. The mount through hole 156 ′ is a portion through which the fastening screw 166 to be described below passes.

In addition, an air supply fan rotation shaft 158 for transmitting rotational power is installed in the air supply motor 154, and an upper end of the air supply fan rotation shaft 158 is fixed to the air supply fan 150. Therefore, the rotational power of the air supply motor 154 is transmitted to the air supply fan 150 by the air supply fan rotation shaft 158.

The air supply fan rotation shaft 158 is installed to face the rotation center of the air supply fan 150 in the vertical direction. That is, as shown, the air supply fan rotation shaft 158 is formed up and down is connected to the air supply motor 154 at the bottom, the air supply fan 150 is fixed to the upper end.

Therefore, when the air supply fan 150 rotates, air is discharged in the circumferential direction around the air supply fan rotation shaft 158. That is, when viewed from above or below, air is discharged outwardly around the air supply fan rotation shaft 158, and this air is guided by the air supply fan housing 152.

An air supply shroud 160 is further provided at a lower end of the air supply fan housing 152. As shown in the drawing, the air supply shroud 160 has a shape corresponding to that of the air supply fan housing 152. The air supply shroud 160 partially shields a lower end of the air supply fan housing 152, and an air supply hole 162 through which air flow passages are formed is penetrated inside.

The air supply shroud 160 is fastened to the air supply fan housing 152 or the outer case 110 by a fastening member such as a screw. In addition, the shroud fastening holes 160 ′ are formed through the edge portions of the air supply shroud 160, respectively. The shroud fastening hole 160 ′ is a portion to which the fastening screw 166 to be described below is fastened.

An air supply orifice 164 is provided in the air supply hole 162 of the air supply shroud 160. The air supply orifice 164 guides the air flowing into the air supply fan 150, and a plurality of orifice through holes 164 ′ are formed in the edge of the air supply orifice 164.

The air supply motor mount 156 and the air supply orifice 164 as described above are fastened to the air supply shroud 160 by a fastening screw 166 (see FIG. 9). That is, when the fastening screw 166 is fastened to the shroud fastening hole 160 'through the mount through hole 156' and the orifice through hole 164 ', the air supply motor mount 156 and air supply An orifice 164 is fastened to the air supply shroud 160.

At this time, since the air supply fan 150 and the air supply motor 154 are coupled to each other, and the air supply motor 154 is fastened by a screw to the air supply motor mount 156, the air supply fan 150 ) And the air supply motor 154 and the air supply motor mount 156 and the air supply orifice 164 are fastened to the air supply shroud 160 integrally by the fastening screw 166 simultaneously.

In addition, an air supply bracket 168 is provided at an upper end of the air supply fan housing 152. The air supply bracket 168 is formed of a flat plate corresponding to the cross section of the air supply fan housing 152 to fix the air supply fan housing 152 and shield the upper portion of the air supply fan housing 152.

An exhaust fan 170 is installed at the left side of the first half of the total heat exchange element 130. That is, an exhaust fan 170 having the same shape as the air supply fan 150 is installed at the rear of the indoor air outlet 122, and the exhaust fan 170 has air in the indoor space through the indoor air inlet 124. Forced suction is forced to be discharged to the indoor air outlet 122.

An exhaust fan housing 172 is provided outside the exhaust fan 170. The exhaust fan housing 172, like the air supply fan housing 152 described above, guides the air forcedly flowed by the exhaust fan 170.

An exhaust fan rotation shaft 174 serving as a rotation center of the exhaust fan 170 is provided at the center of the exhaust fan 170. Accordingly, the exhaust fan 170 rotates around the exhaust fan rotation shaft 174, and the exhaust fan rotation shaft 174 is also installed in the up and down direction similarly to the air supply fan rotation shaft 158 described above.

An exhaust motor 176 corresponding to the air supply motor 154 is provided inside the exhaust fan 170 to provide rotational power to the exhaust fan 170. The exhaust motor 176 is fixed by the exhaust motor mount 178. The exhaust motor mount 178 also has a shape corresponding to the air supply motor mount 156.

An exhaust bracket 180 is provided at a lower end of the exhaust fan housing 172. The exhaust bracket 180 shields a lower portion of the exhaust fan housing 172 to block air that is forcedly blown by the exhaust fan 170 from flowing downward of the exhaust fan housing 172. At the same time, it also serves to fix the exhaust fan housing 172.

The exhaust shroud 182 corresponding to the air supply shroud 160 installed at the lower end of the air supply fan housing 152 is further installed at the upper end of the exhaust fan housing 172. The exhaust shroud 182 partially shields an upper end of the exhaust fan housing 172, and an exhaust hole 184 is formed in a central portion of the exhaust shroud 182.

An exhaust orifice 186 is provided in the exhaust hole 184 of the exhaust shroud 182. The exhaust orifice 186 guides the air flowing into the exhaust fan 170. In addition, the exhaust orifice 186 and the exhaust motor mount 178, as well as the exhaust fan 170 and the exhaust motor 176 are configured to be detachably and simultaneously integrally with the exhaust shroud 182. That is, the air supply orifice 164, the air supply motor mount 156, the air supply fan 150, and the air supply motor 154 described above are the same as that of the air supply shroud 160.

On the other hand, although not shown, the control box is installed on any one surface (for example, the front plate) of the outer case 110. A control unit is formed inside the control box to control the operating conditions of the ventilation system. That is, the power supply is interrupted to turn on / off the ventilation system, and the fan speed is controlled by controlling fan rotation speeds of the exhaust fan 170 and the air supply fan 150.

In addition, one surface (eg, left and right plates) of the outer case 110 is provided with a ceiling fixture (not shown) to allow the ventilation system to be installed on the ceiling of the building.

Inside the outer case 110 is formed a barrier 190 for partitioning the inner space up and down. The barrier 190 shields the outside of the air supply fan housing 152 and the exhaust fan housing 172 to partition the inner space of the outer case 110 up and down, the heat exchange element 130 as shown. Do not mix the intake air and exhaust air that have passed through the inside of each other.

The barrier 190 is preferably made of a material having a light and sound-absorbing function such as styropole, and the left support 144 supporting the left end of the heat exchange element 130 is installed long before and after the right end.

A central bracket 192 supporting the air supply motor mount 156 and the heat exchange element 130 is further installed between the heat exchange element 130, the exhaust fan 170, and the air supply fan 150. That is, the center bracket 192 is installed up and down between the upper cabinet 112 and the inspection door 200 to be described below to support the electrothermal exchange element 130 and the air supply motor mount 156. . Accordingly, the left support 144 and the air supply motor mount 156 are fastened to the central bracket 192.

An air guide 194 is installed on the right side of the total heat exchange element 130. In more detail, an air guide 194 is installed on the left side of the right side plate 116 to guide the flow of air introduced through the external air inlet 120 and the indoor air inlet 124. The air guide 194 is formed to be inclined. That is, it is preferable to be inclined over the upper end of the rear plate (112c) from the lower end of the front plate (112b) of the upper cabinet (112).

The lower part of the outer case 110 is opened and closed by the inspection door 200. The inspection door 200 selectively shields the outer case 110, and includes an element door 202 and a fan door 204 as shown.

The element door 202 is provided below the total heat exchange element 130, and the fan door 204 is provided below the air supply fan 150 and the exhaust fan 170. Accordingly, the element door 202 is opened and closed when the electrothermal exchange element 130 is to be inspected or replaced, and the fan door 204 is used to inspect parts such as the air supply fan 150 and the exhaust fan 170. It will be opened and closed when exchanged.

The device door 202 and the fan door 204 is preferably fastened to each other by a hinge coupling, it is preferably configured to be opened and closed by selectively rotating. More specifically, the left end of the device door 202 and the right end of the fan door 204 are fixed to each other by a hinge 206 or the like, and rotate around the hinge 206 or the like.

The right end of the element door 202 and the left end of the fan door 204 are fixed to the right side plate 116 and the left side plate 114 by screws.

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. 10 is a schematic cross-sectional view of the ventilation system according to the present invention.

Referring to the ventilation state as shown, first, the user's operation setting is transmitted to the control unit inside the control box (not shown), and the ventilation system operates according to the command of the control unit.

First, outdoor air is sucked into the ventilation system through the external air inlet 120 according to the operation of the air supply fan 150, and the external air is heat exchanged through the upper right side of the heat exchange element 130. It is sucked into the element 130.

At this time, the foreign air is filtered through the pre-filter (not shown) mounted on the upper right of the heat exchange element 130, and then introduced into the heat exchange element 130.

The air introduced into the ventilation system through the external air inlet 120 is guided by the air guide 194 to the upper right side of the heat exchange element 130.

The air sucked into the total heat exchange element 130 exchanges heat and moisture from the discharged indoor air and then is discharged through the left bottom surface of the total heat exchange element 130.

Air passing through the total heat exchange element 130 is introduced into the central portion of the air supply fan 150 through the lower portion of the air supply fan 150, and then discharged radially. That is, as shown in Figure 10, the discharge from the central portion of the air supply fan 150 to the outside.

The air discharged to the outside by the air supply fan 150 is guided and rotated by the air supply fan housing 152 and discharged to the indoor space through the external air outlet 126 of the outer case 110.

On the other hand, indoor air is exhausted to the outside by the operation of the exhaust fan 170, the indoor air is sucked into the outer case 110 through the indoor air inlet 124, and then the heat exchange element ( Through the lower right side of the 130 is introduced into the heat exchange element (130). In this case, the air introduced into the outer case 110 may be guided by the air guide 194.

The indoor air sucked into the electrothermal exchange element 130 exchanges heat and moisture with the outside air sucked from the outside, and then exits through the upper left surface of the electrothermal exchange element 130.

The indoor air exiting the heat exchange element 130 flows into the central portion of the air supply fan 150 through the upper portion of the exhaust fan 170, and then is discharged radially. That is, as shown in FIG. 10, the discharge is forced outward from the center of the exhaust fan 170.

The air discharged to the outside by the exhaust fan 170 is guided and rotated by the exhaust fan housing 172 to be exhausted to the outside through the indoor air outlet 122 of the outer case 110.

On the other hand, such a ventilation system is generally installed in a high position such as a ceiling of a building, the outer case for the after-sales service due to the exchange or failure of the total heat exchange element 130 or the internal components provided in the interior of the ventilation system (110) Open the check door 200 to shield the lower portion. That is, the device door 202 or the fan door 204 is opened.

In this case, first, the screw that is fastened to the right end of the device door 202 or the left end of the fan door 204 is released. In this case, the device door 202 or the fan door 204 is rotated about the hinge between the device door 202 and the fan door 204 to open downward.

More specifically, in order to replace or check the air supply fan 150, the exhaust fan 170, and the like, the fan door 204 is opened downward as shown in FIG. 11. In this case, first, the screw that is fastened to the left end of the fan door 204 is released. In this case, the fan door 204 is rotated downward with respect to the hinge 206 of the right end to open.

Therefore, the air supply fan 150, the exhaust fan 170, or the air supply motor 154 or the exhaust motor 176 may be separated. For example, when the fastening screw 166 fastened to the air supply motor mount 156 is released, the air supply motor mount 156 and the air supply orifice 164 are simultaneously separated from the air supply shroud 160. At this time, the air supply fan 150 and the air supply motor 154 are coupled to each other, and the air supply motor 154 is fastened to the air supply motor mount 156, so that the air supply fan 150 or the air supply motor 154 ) Is also drawn downward at the same time.

That is, the air supply fan 150, the air supply motor 154, the air supply motor mount 156, and the air supply orifice 164 are simultaneously separated from the air supply shroud 160 by releasing the fastening screw 166. It is withdrawn downward.

On the contrary, even when the air supply fan 150 is mounted, the air supply fan 150, the air supply motor 154, the air supply motor mount 156, and the air supply orifice 164 are fastened by the fastening screw 166. Is simultaneously mounted to the air supply shroud 160.

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.

In the present invention as described above, the fan and the motor are coupled to each other, the motor is fastened to the motor mount, the motor mount and the orifice is configured to be fastened to the shroud simultaneously. That is, the orifice and the motor mount are detached from the shroud at the same time by the fastening screw, and the shroud is fixed to the fan housing.

Therefore, by loosening the fastening screw, a large number of parts such as a fan or a motor can be taken out at the same time. When the fan or the motor is taken out, the shroud that is separately fastened as in the prior art does not need to be removed. As a result, the workmanship is reduced when assembling the product or after-sales service.

Claims (4)

An outer case forming an upper appearance; An electrothermal exchange element installed inside the outer case to allow heat exchange between the outside and the air; An air supply fan and an exhaust fan which are respectively installed in the outer case to supply air and exhaust, forcing the flow of air; An air supply fan housing and an exhaust fan housing provided at an outer side of the air supply fan and the exhaust fan to guide air flowing by the air supply fan and the exhaust fan; An air supply shroud and an exhaust shroud provided at one side of the air supply fan housing and the exhaust fan housing to partially shield one end of the air supply fan housing and the exhaust fan housing; An air supply motor and an exhaust motor providing rotational power to the air supply fan and the exhaust fan; An air supply motor mount and an exhaust motor mount for supporting the air supply motor and the exhaust motor; The air supply fan, the air supply motor, and the air supply motor mount are integrally and detachably installed at the air supply shroud at the same time, and the exhaust fan, the exhaust motor and the exhaust motor mount are integrally installed at the same time. Ventilation system characterized in that. The method of claim 1, wherein the air supply shroud and the exhaust shroud, Ventilation system, characterized in that fixed to the air supply fan housing and the exhaust fan housing. According to claim 1 or 2, On one side of the air supply motor mount and the exhaust motor mount, And an air supply orifice and an exhaust orifice for guiding the air flowing into the air supply fan and the exhaust fan. 4. The air supply orifice of claim 3, wherein the air supply orifice and the air supply motor mount are fastened to the air supply shroud by the same fastening member; And the exhaust orifice and the exhaust motor mount are fastened to the exhaust shroud by the same fastening member.

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