KR101374865B1 - Ventilation system - Google Patents

Abstract

The present invention relates to a multi-purpose ventilation system which is installed in such spaces as factories, large-scale buildings, pens, and green houses, in order to providing pleasant interior environments by maintaining proper temperatures and moisture. More specifically, the present invention relates to a multi-purpose ventilation system capable of letting fresh outdoor air into the indoors, by discharging polluted interior air to the outside, at the same time performing a heat exchange between the influx air and efflux air, and circulating the indoor air in order to reduce the temperature difference between upper and lower air masses.

Description

Multipurpose Ventilation System

The present invention relates to a multipurpose ventilation system installed in a factory, a large building, a barn, a glass greenhouse, and providing a comfortable indoor environment by maintaining an appropriate temperature and humidity in the room, and more specifically, contaminated indoor air is discharged to the outside. Accordingly, the present invention relates to a multi-purpose ventilation system capable of circulating internal air to reduce the temperature difference between the upper and lower parts of the room, where the fresh air from the outside is introduced into the room, and the discharged air and the introduced air are simultaneously exchanged. .

In general, the ventilation system refers to a treatment system that discharges contaminated air and supplies fresh outdoor air to the room to keep indoor air clean at all times. Such a ventilation system can be divided into a method of artificially using a fan and a method of natural ventilation.

The conventional ventilation system of the mandatory method is provided with an indoor unit which heat exchanges with indoor air and an outdoor unit which exchanges heat with outdoor air in one case, which is mainly installed in a window, etc. Alternatively, the outdoor unit attached to the ceiling and exchanging heat with the outdoor air is mainly constructed as a system installed separately from the indoor unit and installed on the balcony of the apartment or the outer wall of the building.

However, the conventional ventilation system having the above structure is configured to simply cool or heat the room while circulating the indoor air, so that temperature and humidity can be maintained, but the cleanliness of the air is significantly reduced due to fine dust and contaminated air. Problem occurs.

In addition, the conventional ventilation system is difficult to maintain a constant temperature uniformly due to the difference between the temperature of the upper air and the lower air when the ceiling of the indoor space is high, suitable for workers and livestock, cultivated crops, etc. It did not provide humidity and the like, accompanied by a problem that the amount of power consumed is increased because the cooling or heating efficiency is significantly reduced.

Therefore, by allowing fresh outside air to flow into the room to maintain a more comfortable indoor environment, the user can maintain the temperature and humidity set by the user by circulating the indoor air. There is a need for the development of a ventilation system that can control the amount of air discharged so that an outdoor pressure difference does not occur.

1. Published Patent Publication No. 10-2006-0088723 'Air Conditioning System' (Published Date 2006.08.07) 2. Registered Patent No. 10-0833171 'Air circulation device for house' (date of registration 2008. 05. 22) 3. Korean Patent Application Publication No. 10-2012-0026215 'Hybrid Ventilation Equipment' (published 2012.03.19)

The present invention is to solve the problems as described above is to discharge the indoor air contaminated so that the indoors to maintain a comfortable state and fresh air intake, to reduce the temperature difference between the upper and lower sides of the room It is an object to provide a multipurpose ventilation system capable of circulating air.

In addition, an object of the present invention is to provide a multi-purpose ventilation system with an improved heat and cooling efficiency by providing a separate heat exchanger in the vent so that the discharged air and the incoming air heat exchange.

The multi-purpose ventilation system of the present invention is installed in the interior of the building and the first ventilation fan 1100 and the first ventilation fan (rotated by the drive of the motor 1110 so as to suck out the indoor air of the building to the outside) A ventilation unit 1000 including a second ventilation fan 1200 which is passively rotated by the sucked air flow when indoor air is inhaled by 1100; A discharge pipe 2000 connected to the ventilation part 1000 and having a hollow inside to discharge the indoor air sucked from the ventilation part 1000 to the outside; Between the ventilation unit 1000 and the discharge pipe 2000, the circulation pipe (3100) is formed on both sides to discharge the indoor air sucked from the ventilation unit 1000 to the interior of the building, respectively, the ventilation unit ( A flow path control device 3000 for controlling the movement of the indoor air such that the indoor air sucked from 1000 is moved to one of the discharge pipe 2000 and the circulation pipe 3100; A connection pipe 4000 connected to the circulation pipe 3100 so as to communicate with the circulation pipe 3100; When the flow path control device 3000 discharges the indoor air to the discharge pipe 2000, the external air is communicated with the connecting pipe 4000 so that external air flows into the building due to the pressure difference between the inside and the outside of the building. Inflow pipe 5000 is introduced; A heat exchanger 6000 in communication with the discharge pipe 2000 and the connection pipe 4000 such that indoor air discharged to the discharge pipe 2000 and external air introduced to the inlet pipe 5000 are mutually heat exchanged; In order to move the indoor air to any one of the discharge pipe 2000 and the circulation pipe 3100, the flow path control device 3000 is controlled, and the suction amount of the indoor air sucked into the ventilation unit 1000 is adjusted. It characterized in that it comprises a; controller 7000 for controlling the driving of the motor 1110 to be able to.

In the present invention, the circulation pipe 3100 is the first circulation pipe 3110 formed on one side of the flow path control device 3000 and the second circulation pipe 3120 formed on the other side of the flow path control device 3000. ), The connection pipe 4000 has one side connected to an upper end of the heat exchanger 6000, and the other side connected to the first connection pipe 4100 and one side connected to the inlet pipe 5000. And a second connection pipe 4200 and a third connection pipe 4300 connected to the lower end of the 6000 and connected to the first circulation pipe 3110 and the second circulation pipe 3120, respectively. The first circulation pipe 3110 is installed to be rotatable in the vertical direction to the first circulation pipe 3110, and when the indoor air moves to the first circulation pipe 3110, external air is moved to the first circulation pipe 3110. The first opening and closing plate 3111 to seal the other side of the second connecting pipe 4200 is formed by rotating in the upward direction to block the flow into the), The second circulation pipe 3120 is rotatably installed in the second circulation pipe 3120 in the vertical direction, and when the indoor air moves to the second circulation pipe 3120, the external air is moved to the second circulation pipe. A second opening and closing plate 3121 is formed to seal the other side of the third connecting pipe 4300 by rotating upward to block the flow into the 3120.

In the present invention, it is installed at the end of the inlet pipe 5000 and forcibly sucks the outside air when the indoor air moves to the circulation pipe 3100 so that the outside air can flow into the circulation pipe 3100. A suction fan 5100 for opening the first opening and closing plate 3200 and the second opening and closing plate 3300; And a heater unit that is connected to the controller 7000 and generates heat so as to increase the temperature of the suctioned external air by contacting the external air sucked from the suction fan 5100 when a specific signal is received from the controller 7000. 5200); characterized in that is provided.

In the present invention, the heat exchanger 6000 is a plurality of heat conductive pipes 6100 in which one side is in contact with the indoor air discharged to the discharge pipe 2000 and the other side is in contact with the external air introduced into the connection pipe 4000. ); A plurality of through holes are formed to be fitted to the heat conductive pipe 6100, and a plurality of heat conductive pins 6200 are inserted into the heat conductive pipe 6100 and are arranged to be spaced apart at a predetermined interval; A case 6300 inside which is hollow so that the heat conductive pipe 6100 and the heat conductive fin 6200 are accommodated and fixed to the discharge pipe 2000 and the connection pipe 4000; A heat insulator 6400 formed inside the case 6300 and partitioning the inside of the case 6300 so that indoor air discharged to the discharge pipe 2000 and external air sucked into the connection pipe 4000 are not mixed with each other; Characterized in that it comprises a.

In the present invention, the outer heat insulating material 2200 and the upper and lower sides surrounding the outer circumferential surface of the discharge pipe 2000 and the upper and lower sides are opened on the upper end of the discharge pipe 2000 and formed with a diameter larger than the diameter of the discharge pipe 2000, the inner surface The ventilator 8000 is spaced apart from the outer surface of the discharge pipe 2000 by a predetermined interval and fastened to an upper side of the discharge pipe 2000.

In the present invention, the ventilator 1000 is provided with an encoder 1300 for measuring the rotational speed of the second ventilating fan 1200, the controller 7000 is the first measured from the encoder 1300 2 to adjust the rotation speed of the motor 1110 to rotate the first rotary blade 1130 by recognizing the suction amount of the indoor air flowing into the lower portion of the ventilation unit 1000 according to the rotation speed of the ventilation fan 1200. It is characterized by.

In the present invention, the flow path control device 3000 is installed on the upper side of the ventilation unit 1000, the upper support 3210 and the lower support 3220 is installed on the inner upper portion and the circulation pipe on the outer surface An outer frame 3200 on which 3100 is formed; A guide arm 3300 protruding upward from the lower support 3220; A driving shaft 3400 penetrating through the upper support 3210 and having one side rotatably coupled to the lower support 3220; A drive motor 3500 installed at the other side of the drive shaft 3400 to rotate the drive shaft 3400; An upper and lower sides are opened and positioned inside the outer frame 3200, and a cover fixing unit 3610 which is fastened to the driving shaft 3400 to rotate about the driving shaft 3400 is formed therein, and has an opening on an outer circumferential surface thereof. 3630 is formed and in communication with the inside, when the drive shaft 3400 is rotated to one side by a set angle, the opening 3620 and the circulation pipe 3100 is in communication with the indoor air to the circulation pipe 3100. An inner frame 3600 which moves, and when the driving shaft 3400 rotates to another side by a set angle, the opening 3620 is displaced from the circulation pipe 3100 and the outer surface seals the circulation pipe 3100; The cover fixing unit 3610 is installed to be rotatable in the vertical direction, and when the drive shaft 3400 rotates to one side by a set angle, the lower surface is gradually rotated upwards while contacting the upper end of the guide arm 3300, A blocking cover 3700 which closes the open upper side of the outer frame 3200 and gradually rotates downward when the driving shaft 3400 rotates to the other side by a set angle to open the upper side of the outer frame 3200; Characterized in that it comprises a.

The present invention by the configuration as described above can discharge the polluted air inside the building to the outside and the fresh air from the outside is automatically introduced into the building as the polluted air is discharged can always maintain a comfortable state indoors. .

In addition, the present invention can artificially circulate the air inside the building to reduce the temperature difference between the top and bottom inside the building during winter to improve the heating efficiency and to provide a heat exchanger that can recover the heat of the exhaust air outside the inflow There is an advantage that can reduce the heating cost by increasing the temperature of the air.

1 is a perspective view showing the overall appearance of the multipurpose ventilation system of the present invention.
Figure 2 is a cutaway perspective view showing the configuration of the ventilator of the present invention.
Figure 3 is an exploded perspective view showing the main configuration of the ventilator of the present invention.
4 is a cross-sectional view showing the main configuration of the ventilation unit of the present invention.
5 is a cutaway perspective view of a portion of the outer frame of the flow path control device of the present invention;
6 is an exploded perspective view showing the main configuration of the flow path control apparatus of the present invention.
Figure 7 is an enlarged view showing a cross-sectional view inside the building installed in the building multi-purpose ventilation system of the present invention and the suction fan and the heater unit installed in the flow pipe.
8 is a perspective view and a cross-sectional view showing a first opening and closing plate and a second opening and closing plate of the present invention.
9 is an exploded perspective view showing the main configuration of the heat exchanger of the present invention.
10 is a cutaway perspective view showing the main configuration of the ventilator of the present invention.
11 is a perspective view showing a connecting rod of the present invention.
12 is a flowchart illustrating a control method and a control procedure of the multipurpose ventilation system of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein.

1 is a perspective view showing the overall appearance of the multi-purpose ventilation system of the present invention, Figure 2 is a cutaway perspective view showing the configuration of the ventilator of the present invention, Figure 3 is an exploded perspective view showing the main configuration of the ventilator of the present invention, Figure 4 is a present invention 5 is a cutaway perspective view showing a part of the outer frame of the flow path control device of the present invention, FIG. 6 is an exploded perspective view showing a main configuration of the flow path control device of the present invention, FIG. 9 is an enlarged view illustrating a building interior section having a multi-purpose ventilation system of the present invention installed in a building, a suction fan and a heater installed at a flow path pipe, and FIG. Is an exploded perspective view showing the main configuration of the heat exchanger of the present invention, Figure 10 is a cutaway perspective view showing the main configuration of the ventilator of the present invention, Figure 11 shows a connecting rod of the present invention 12 is a flowchart illustrating a control method and a control procedure of the multipurpose ventilation system of the present invention.

Referring to FIG. 1, the multipurpose ventilation system of the present invention has a ventilation unit 1000. Ventilation unit 1000 is installed in the interior of the building has the purpose of discharging the indoor polluted air to the outside. The ventilation unit 1000 may include a first ventilation fan 1100 that is rotated by the driving of the motor 1110 and a second ventilation fan that is passively rotated by the flow of indoor air sucked by the first ventilation fan 1100. 1200).

Referring to FIG. 2, the ventilation part 1000 has a ventilation frame 1010 having an upper and lower side open and formed in a cylindrical tubular shape having an hollow inside. Reinforcing protrusions 1011 are formed on the outer circumferential surface of the ventilation frame 1010. The reinforcement protrusion 1011 is formed to increase the rigidity of the ventilation frame 1010 and is formed to be interconnected with the flow path control device 3000 to be described later. The reinforcement protrusion 1011 may be formed in plural along the outer circumferential surface of the ventilation frame 1010. In addition, the lower end of the ventilation frame 1010 is formed with a guide protrusion 1012 for guiding the inflow of air from the bottom.

Referring to FIG. 4, a motor housing 1020 is formed inside the ventilation frame 1010. The motor housing 1020 may be formed to have an open top and bottom sides, and a plurality of heat radiating protrusions may be formed on an outer circumferential surface thereof. The motor 1110 for driving the first fan 1100 is provided in the motor housing 1020.

2, one side is fixed to the outer side of the motor housing 1020 and the other side is fixed to the inner side of the ventilation frame 1010 so that the motor housing 1020 can be fixed to the inner side of the ventilation frame 1010. The connecting rod 1030 is formed. Therefore, the motor housing 1020 may be fixed to the inside of the ventilation frame 1010. At this time, the connecting rod 1030 is formed a plurality of spaced apart along the outer peripheral surface of the motor housing 1020.

3 and 4, the first ventilation fan 1100 is fastened to the driving shaft 1111 of the motor 1110, so that the first ventilation fan 1100 also rotates as the motor 1110 rotates. The first ventilation fan 1100 includes a first wing fixing frame 1120 fastened to the drive shaft 1111 of the motor 1110. The first wing fixing frame 1120 is bolted or riveted to the other side of the drive shaft 1111.

In addition, the first ventilation fan 1100 includes a first rotary blade 1130 fixed to the first wing fixing frame 1120. A plurality of first rotating blades 1130 are formed along the outer circumferential surface of the first wing fixing frame 1120 and are arranged at a constant interval around the drive shaft 1111 and then fixed to the first wing fixing frame 1120. . Accordingly, when the first rotary blade 1130 rotates, the air may be sucked from the lower portion of the ventilation frame 1010 to discharge the air to the upper portion of the ventilation frame 1010.

3 and 4, the rotary shaft housing 1400 is formed at the lower end of the motor housing 1020. In the center of the rotating shaft housing 1400, the rotating shaft 1410 is formed to be rotatable. The rotary shaft 1410 extends upward and downward, and a bearing 1420 is formed between the rotary shaft housing 1400 and the rotary shaft 1410 to reduce friction with the rotary shaft housing 1400, and the bearing 1420 is rotated. A plurality may be formed along the 1410.

3 and 4, the second ventilation fan 1200 includes a second wing fixing frame 1210 fixed to one side of the rotation shaft 1410 by bolts or rivets. In addition, the second ventilation fan 1200 includes a second rotary blade 1220 fixed along the outer circumferential surface of the second wing fixing frame 1210. The second rotary blades 1220 may be fixed to a plurality of spaced apart about the rotation axis 1410.

Therefore, when the first ventilation fan 1100 rotates, indoor air of the building flows into the lower part of the ventilation frame 1010, and the indoor air introduced therein may rotate the second rotary blade 1220 passively (no power). That is, when the first ventilation fan 1100 rotates rapidly, the amount of air introduced into the ventilation frame 1010 is increased, and the second rotary blade 1220 rotates faster. On the contrary, when the first ventilation fan 1100 rotates slowly, the amount of air flowing into the lower part of the ventilation frame 1010 decreases and the rotation speed of the second rotary blade 1220 decreases.

3 and 4, the rotary shaft 1410 is provided with an encoder 1300. The encoder 1300 is connected to the rotation shaft 1410 to measure the rotation speed of the rotation shaft 1410. The pulse period that can be measured by the encoder 1300 is preferably about 1 ~ 1400. Therefore, when the encoder 1300 is connected to the rotating shaft 1410, it is possible to measure a minute rotation period of the rotating shaft 1410.

Referring to FIG. 1, an exhaust pipe 2000 is formed at the upper side of the ventilation frame 1010 of the ventilation unit 1000 to guide the movement of indoor air of the building sucked from the ventilation unit 1000 and to discharge it to the outside of the building. The inside of the discharge pipe 2000 is preferably formed in a hollow shape so that air can move smoothly.

Referring to FIG. 1, a flow path control device 3000 is formed between the ventilation unit 1000 and the lower end of the discharge pipe 2000. The flow path control device 3000 has the purpose of circulating the indoor air by discharging the indoor air sucked from the ventilation unit 1000 on both sides to the outside of the building. The flow path control device 3000 for achieving the above object discharges indoor air inside the building sucked from the ventilation unit 1000 to the discharge pipe 2000 or moves the indoor air to be moved to the circulation pipe 3100. You can control the movement of. In this case, a plurality of discharge holes 3101 are formed along the circulation tube 3100 on the upper surface of the circulation tube 3100. Internal air may pass through the discharge hole 3101 to be discharged into the building.

5 and 6, the flow path control apparatus 3000 has an outer frame 3200 whose upper and lower sides are opened. The outer frame 3200 may be formed in a cylindrical tube shape of which the inside is hollow. On the outer surface of the outer frame 3200, the reinforcing projection 3201 is formed to increase the rigidity of the outer frame 3200. A plurality of reinforcement protrusions 3201 may be formed along the outer circumferential surface of the outer frame 3200. An upper support 3210 is formed on an inner upper portion of the outer frame 3200. The upper support 3210 has a plate shape having a predetermined thickness, and both sides thereof are fixed to an inner surface of the outer frame 3200. The lower support 3220 is spaced apart from the upper support 3210 by a predetermined distance downward. The lower support 3220 may be formed in the same shape as the upper support 3210 and both sides are fixed to an inner surface of the outer frame 3200.

In addition, a circulation tube 3100 is formed on an outer circumferential surface of the outer frame 3200. The circulation pipe 3100 may be formed in a hollow tubular shape and communicated with the inside of the outer frame 3200. The circulation pipe 3100 may be formed in plural so as to be symmetrical with respect to the center of the outer frame 3200.

Referring to FIG. 5, the guide arm 3300 protrudes upward from the upper surface of the lower support 3220. The guide arms 3300 may be formed in a pair, and each of the guide arms 3300 is formed to be spaced apart by a predetermined interval. A guide roller 3310 may be formed at an upper end of the guide arm 3300. The guide roller 3310 may be replaced with a bearing, a cam follower, or the like.

Referring to FIG. 6, a drive shaft 3400 penetrating the upper support 3210 is formed. The drive shaft 3400 is installed to be rotatable in the left and right directions on the upper support 3210, and a rotary bearing 3410 may be formed between the outer surface of the drive shaft 3400 and the upper support 3210 and provides frictional force to the rotary bearing. Can be reduced. In this case, the lower end of the drive shaft 3400 may be seated at the lower end of the lower support 3220 and may be fastened to the rotary bearing 3410 provided in the lower support 3220.

Referring to FIG. 6, a drive motor 3500 for rotating the drive shaft 3400 is installed at an upper end of the drive shaft 3400. The driving motor 3500 may rotate the driving shaft 3400 by an angle (rotation angle is 90 °) set in the left and right directions. In this case, the driving motor 3500 may be formed of a geared single-phase induction motor, a stepper motor, a DC motor, or a servo motor that can rotate repeatedly. .

Referring to FIG. 6, an inner frame 3600 is formed which is opened up and down and installed inside the outer frame 3200. A cover fixing unit 3610 is formed at an inner upper end of the inner frame 3600, and both ends of the cover fixing unit 3610 are fixed to the inner surface of the inner frame 3600. The inner frame 3600 has a drive shaft 3400 penetrating the cover fixing unit 3610 so that the inner frame 3600 can be rotated inside the outer frame 3200, and the driving shaft 3400 rotates so that the inner frame 3600 also rotates as the drive shaft 3400 rotates. ) And the cover fixing unit 3610 are fastened to each other. An opening 3620 may be formed on an outer circumferential surface of the inner frame 3600, and the opening 3620 may be further formed at a position symmetrical with respect to the cover holder 3610.

Therefore, when the driving shaft 3400 rotates in one direction, the opening 3620 circulates with the circulation pipe 3100 so that the interior space of the building is discharged through the circulation pipe 3100 to circulate air in the building. On the contrary, when the drive shaft 3400 rotates in the other direction, the inner frame 3600 rotates and the opening 3620 and the circulation pipe 3100 are shifted from each other, thereby preventing indoor air moving to the circulation pipe 3100.

Referring to FIG. 6, the cover fixing unit 3610 is provided with a blocking cover 3700. It may be divided into a first cover 3710 and a second cover 3720. The first cover 3710 and the second cover 3720 are installed on the cover fixing unit 3610 so as to be rotatable in the vertical direction. When the driving shaft 3400 rotates to one side and the inner frame 3600 rotates, the first cover 3710 and the second cover 3720 have a lower surface of the first cover 3710 and the second cover 3720. The upper surface of the guide roller 3310 formed in the 3300 is in contact with the guide roller 3310 and rotates gradually upward. As such, when the blocking cover 3700 rotates upward, the opening 3620 and the circulation pipe 3100 communicate with each other, and the blocking cover 3700 may seal the upper side of the outer frame 3200.

On the contrary, when the driving shaft 3400 rotates to the other side by the set angle, the first cover 3710 and the second cover 3720 gradually rotate downward. Therefore, gradually, the upper side of the outer frame 3200 is opened and the opening 3620 and the circulation tube 3100 are shifted from each other, but the inner frame 3600 seals the circulation tube 3100.

In this case, the first cover 3710 and the second cover 3720 are elastically supported by the cover fixing unit 3610 and the elastic members supporting the first cover 3710 and the second cover 3720 in the downward direction (gravity direction). It may be a pulling spring. This is because when the first cover 3710 and the second cover 3720 maintain the tension in the downward direction, the first cover 3710 and the second cover 3720 may be smoothly opened when the outer frame 3200 is opened. .

Referring to FIG. 1, the connection pipe 4000 is connected to an outer surface of the circulation pipe 3100. The connection pipe 4000 may be in communication with the circulation pipe 3100, and external air may be introduced into the interior of the building through the circulation pipe 3100.

Referring to Figure 1 is connected to the connection pipe 4000 is formed in contact with the outside of the building inlet pipe 5000 for introducing the outside air into the building. Therefore, when the outside frame 3200 of the flow path control device 3000 is opened and the indoor air of the building is discharged to the discharge pipe 2000, the air inside the building through the inflow pipe 5000 due to the pressure difference between the inside and the outside of the building. Flows into.

Referring to FIG. 1, a heat exchanger 6000 is provided in the discharge pipe 2000 and the connection pipe 4000. The heat exchanger 6000 is in communication with the internal space of the discharge pipe 2000 and the inlet pipe 5000 so that the indoor air discharged into the discharge pipe 2000 and the external air introduced into the inlet pipe 5000 can be exchanged with each other. Therefore, since the cold outside air introduced into the winter inlet pipe 5000 passes through the heat exchanger 6000, it is possible to minimize the heat loss in the room.

Referring to Figure 7 (a) to control the rotation of the drive motor 3500 of the flow path control device 3000 to move the indoor air of the building to any one of the discharge pipe 2000 and the circulation pipe 3100, ventilation A controller 7000 is formed to control the motor 1110 in a differential power control manner so as to adjust the suction amount of the indoor air sucked into the unit 1000.

The controller 7000 may be connected to the encoder 1300 and may receive the rotation speed of the rotation shaft 1410 measured from the encoder 1300. That is, since the second ventilation fan 1200 rotates according to the suction amount of the indoor air flowing into the ventilation frame 1010, the suction amount of the indoor air is measured by the encoder 1300 by measuring the rotation speed of the second ventilation fan 1200. The controller 7000 can recognize. Therefore, the driving of the motor 1110 connected to the controller 7000 according to the difference between the rotation speed of the second ventilation fan 1200 and the rotation speed value of the second ventilation fan 1200 arbitrarily set by the user in the controller 7000 is performed. By adjusting the number of revolutions of the first ventilation fan 1100 can be adjusted.

In addition, the controller 7000 may be provided with any one or more of a temperature measuring sensor, a humidity measuring sensor, a pressure measuring sensor, a dust detecting sensor, a circulating temperature sensor, and a carbon dioxide measuring sensor connected to the controller 7000. The controller 7000 may drive the motor 1110 by comparing the measured value measured from each of the measuring sensors with a target value of the measuring sensor set by the user.

In particular, the circulation temperature sensor circulates the indoor air if the difference between the upper and lower temperatures of the building is greater than the set value, thereby operating the flow control device 3000 to reduce the difference between the upper and lower temperatures. Vent the air.

In addition, the controller 7000 is divided into stages according to the difference between the measured value of the room measured by each measuring sensor and the target value of each measuring sensor input to the controller 7000 by the user so that the user can check the image or It can be displayed through the lighting of the LED.

In addition, the controller 7000 may be operated through operation of a PC by interworking with a personal computer (PC), and may check a value measured from the plurality of measuring sensors or input a target value even with a smartphone using a wireless Internet. Can be.

Referring to FIG. 1, the circulation tube 3100 includes a first circulation tube 3110 formed at one side of the outer frame 3200 and a second circulation tube 3120 formed at the other side of the outer frame 3200. Therefore, it is possible to circulate a larger area when circulating the air inside the building.

Referring to FIG. 1, since the circulation pipe 3100 is formed of the first circulation pipe 3110 and the second circulation 3120, one side of the connection pipe 4000 is connected to the upper end of the heat exchanger 6000, and the other side is introduced. The first connecting pipe 4100 and one side connected to the pipe 5000 and one side is connected to the lower end of the heat exchanger 6000 and the other side is connected to the first circulation pipe 3110 and the second circulation pipe 3120, respectively Connector 4200 and third connector 4300.

Referring to FIG. 8, a first opening and closing plate 3111 for sealing the other side of the second connection pipe 4200 is formed in the first circulation pipe 3110. The first opening and closing plate 3111 is installed to be rotatable in the vertical direction in the first circulation pipe 3110. At this time, the first opening and closing plate 3111 rotates in the moving direction of the indoor air moving to the first circulation pipe 3110. It rotates upward due to the pressure of the indoor air when the indoor air moves to the first circulation pipe 3110 to seal the other side of the second connecting pipe 4200.

On the other hand, the lower surface of the first opening and closing plate 3200 receives a moving air resistance, the first opening and closing plate 3111 is moved upwards to close the other side of the second connection pipe 4200 more tightly (a first blade ( 3111-1) are formed to protrude. Therefore, since the first opening and closing plate 3111 is further subjected to resistance of the indoor air moving through the first blades 311-1, the first opening and closing plate 3111 can smoothly move upward. In this case, a packing (not shown) in contact with the other side of the second connection pipe 4200 may be formed on an upper surface of the first opening and closing plate 3111. Since the packing is provided, the sealing efficiency of the first opening and closing plate 3200 and the second connection pipe 4200 is improved.

In addition, the second circulation pipe 3120 is provided with a second blade 3121-1 formed on the lower surface of the second opening and closing plate 3121 and the second opening and closing plate 3121. The second opening and closing plate 3121 and the second blade 312-1 have the same configuration and effect as the first opening and closing plate 3111 and the first blade 311-1, and thus, the first opening and closing plate 3111 and the above-mentioned. It follows from the description of the first blade 3111-1.

Referring to FIG. 7B, the inlet pipe 5000 is provided with a suction fan 5100 and a heater part 5200. First, the suction fan 5100 is installed at the end of the inlet pipe 500 and is formed to forcibly suck the outside air of the building. This has the purpose of forcibly opening the first opening and closing plate 3111 and the second opening and closing plate 3121 when the indoor air moves to the circulation pipe 3100 to introduce external air into the room. The suction fan 5100 is connected to the controller 7000 and may be operated by a user's manipulation.

The heater unit 5200 includes a control unit 5210 connected to the controller 7000 and a heating coil 5220 for generating heat by receiving power from the control unit 5210. When the controller 7000 receives the specific signal, the controller 5210 heats the heating coil 5220. At this time, when the outside air is sucked from the suction fan 5100, the outside air is in contact with the heating coil (5220) and the temperature of the contacted outside air is increased. As such, the outside air having a temperature rise is introduced into the building through the circulation pipe 3100, thereby minimizing heat loss inside the building. The heater unit 5200 is preferably used in winter when the temperature of the outside air is low.

Referring to FIG. 9, the heat exchanger 6000 includes a heat conduction pipe 6100, a heat conduction fin 6200, a case 6300, and a heat insulator 6400.

The heat conductive pipe 6100 is in contact with the indoor air discharged to the discharge pipe 2000, one side and the external air introduced into the inside through the connection pipe 4000. The heat conduction pipe 6100 may be formed as a heat pipe having a heat conducting fluid therein, and a plurality of heat conduction pipes 6 may be provided at a predetermined interval so that heat exchange can be made quickly.

The thermal conductive fin 6200 is formed in a thin plate shape and a plurality of through holes are formed to allow the thermal conductive pipe 6100 to be inserted therein. The heat conduction pipe 6100 may be inserted into the through hole, and a plurality of heat conduction pipes 6100 may be provided along the heat conduction pipe 6100. The heat exchange efficiency is improved through the heat conduction fins 6200.

The case 6300 is an upper case 6310 which is fastened to the lower end of the discharge pipe 2000 and the first connection pipe 4100 and a lower case to which the discharge pipe 2000 and the second and third connection pipes 4200 and 4300 are fastened. 6320. The inside of the upper case 6310 and the lower case 6320 is hollow to accommodate the heat conduction pipe 6100 and the heat conduction fin 6200.

The insulation 6400 is formed inside the case 6300 and partitions the inside of the case 6300 so that indoor air discharged through the discharge pipe 2000 and external air introduced through the connection pipe 4000 are not mixed with each other.

Referring to FIG. 10, an outer insulation 2200 is formed at an upper end of the discharge pipe 2000. The outer insulation 2200 is formed to surround the outer circumferential surface of the discharge pipe 2000 exposed to the roof of the building. When the external insulation 2200 is formed in the discharge pipe 2000 exposed to the outside, the condensation phenomenon caused by the difference between the temperature of the indoor air discharged from the discharge pipe 2000 and the external temperature can be prevented. By preventing the phenomenon of corrosion can improve the durability of the discharge pipe (2000).

In addition, the ventilator 8000 is installed above the discharge pipe 2000. The ventilator 8000 is open to the upper and lower sides, extends in the vertical direction and is formed to have a diameter larger than the diameter of the discharge pipe 2000. At this time, one side is fixed to the inner surface of the ventilator 8000, the other side is provided with a connection angle tube 8100 fixed to the outer surface of the discharge pipe (2000). A plurality of connection angle tube 8100 is formed along the outer surface of the discharge tube 2000 to fix the ventilator 8000.

Through such a ventilator 8000, rain water may be prevented from entering the discharge pipe 2000, and at the same time, an upper portion of the ventilator 8000 may be opened to smoothly discharge indoor air discharged to the discharge pipe 2000. have. In addition, since the discharge pipe 2000 and the ventilator 8000 are spaced apart from each other by the connection angle tube 8100, when the wind blows from the outside, the outside air flows into the space and is discharged to the ventilator 8000. In this way, when the outside air flows into the space between the ventilator 8000 and the discharge pipe 2000, the air pressure of the upper side of the discharge pipe 2000 is lowered, thereby preventing an over-vented phenomenon in which indoor air is discharged to the outside. have.

Referring to FIG. 10, a support panel 2100 is formed in the discharge pipe 2000. The support panel 2100 is integrally formed with the discharge pipe 2000 to fix the discharge pipe 2000 to the top of the roof of the building.

Referring to FIG. 11, a connecting table 9000 connecting the ventilation unit 1000 and the flow path control device 3000 is formed. The connecting table 9000 is formed in a ring shape surrounding the outer surface of the ventilation unit 1000 and the flow path control device 3000. That is, the connecting table 9000 is inserted into the reinforcement protrusion 1011 formed in the ventilation unit 1000 and the reinforcement protrusion 3201 formed in the flow path control device 3000, and then fix both ends thereof with bolts and fastening clips. Therefore, the inner surface of the connecting table 9000 and the outer surface of the ventilation unit 1000 and the flow path control device 3000 are in close contact with each other so that the ventilation unit 1000 and the flow path control device 3000 may be connected to each other. On the other hand, the connecting table 9000 may be used for each connecting portion when connecting the flow path control device 3000 and the discharge pipe 2000, the heat exchanger 6000 and the inlet pipe 5000.

Hereinafter, a control method of the controller 7000 will be described.

Referring to FIG. 7, a plurality of multi-purpose ventilation systems of the present invention may be installed inside a large building such as a factory or a barn. Each multi-purpose ventilation system may be independently controlled by each controller 7000, and may be connected to a main controller 10000 that can collectively control a plurality of controllers 7000 to connect each controller 7000. Integrated control is possible. At this time, the controller 7000 and the main controller 10000 is communicated wirelessly or wired to send and receive a specific signal.

FIG. 12 illustrates a sequence and method for controlling each controller 7000 through the main controller 10000 when a plurality of multipurpose ventilation systems of the present invention are installed in a building having a large indoor space such as a factory or a barn. 1 to N ventilation systems N each controller 7000 is connected in the same communication as RS485 and the main controller 10000 is also connected to each controller 7000 in the same communication as RS485. The main controller 10000 or the controller 7000 connected as described above may control a cooling device, a heating device, a humidifier, and the like, which are separately provided.

In addition, the main controller 10000 is connected to a personal computer (PC) through a communication means such as RS485, and establishes a data server to data and graph the temperature, humidity, ventilation amount, carbon dioxide concentration, and fine dust concentration of the indoor environment of the building. It can be saved by PC and data server.

In addition, it is possible to provide users with a more efficient ventilation system by configuring a system that includes Internet surveillance control function to check and control the indoor environment status inside the building anytime, anywhere by using Internet and smart phone applications.

1000: ventilation unit 1010: ventilation frame
1011: reinforcement protrusion 1012: guide protrusion
1020: motor housing 1030: connecting rod
1100: first ventilation fan 1111: drive shaft
1110: motor 1120: first wing fixing frame
1130: first rotary blade 1200: second ventilation fan
1210: second wing fixing frame 1220: second rotary wing
1300: encoder 1400: rotary shaft housing
1410: shaft 1420: bearing
2000: discharge pipe 2100: support panel
3000: flow path controller 3100: circulation pipe
3110: first circulation pipe 3111: first opening and closing plate
3120: second circulation pipe 3121: second opening and closing plate
3200: external frame 3201: reinforcement protrusion
3210: upper support 3220: lower support
3300: guide arm 3310: guide roller
3400: drive shaft 3410: rotary bearing
3500: Drive motor 3600: Internal frame
3610: cover holder 3620: opening
3700: blocking cover 3710: first cover
3720: second cover 4000: connector
4100: first connector 4200: second connector
4300: third connector 5000: inlet pipe
6000 heat exchanger 6100 heat conduction pipe
6200: heat conduction pin 6300: case
6400: Insulation 7000: Controller
8000: Ventilator 8100: Connecting angle pipe
9000: Connecting Rod 10000: Main Controller

Claims (7)

The indoor air is installed by the first ventilation fan 1100 and the first ventilation fan 1100 which are installed inside the building and rotated by the driving of the motor 1110 to suck and discharge the indoor air of the building to the outside. A ventilation part 1000 including a second ventilation fan 1200 which is passively rotated by the sucked air flow when inhaled;
A discharge pipe 2000 connected to the ventilation part 1000 and having a hollow inside to discharge the indoor air sucked from the ventilation part 1000 to the outside;
Between the ventilation unit 1000 and the discharge pipe 2000, the circulation pipe (3100) is formed on both sides to discharge the indoor air sucked from the ventilation unit 1000 to the interior of the building, respectively, the ventilation unit ( A flow path control device 3000 for controlling the movement of the indoor air such that the indoor air sucked from 1000 is moved to one of the discharge pipe 2000 and the circulation pipe 3100;
A connection pipe 4000 connected to the circulation pipe 3100 so as to communicate with the circulation pipe 3100;
When the flow path control device 3000 discharges the indoor air to the discharge pipe 2000, the external air is communicated with the connecting pipe 4000 so that external air flows into the building due to the pressure difference between the inside and the outside of the building. Inflow pipe 5000 is introduced;
A heat exchanger 6000 in communication with the discharge pipe 2000 and the connection pipe 4000 such that indoor air discharged to the discharge pipe 2000 and external air introduced to the inlet pipe 5000 are mutually heat exchanged;
In order to move the indoor air to any one of the discharge pipe 2000 and the circulation pipe 3100, the flow path control device 3000 is controlled, and the suction amount of the indoor air sucked into the ventilation unit 1000 is adjusted. A controller 7000 for controlling the driving of the motor 1110 to be able to;
Versatile ventilation system comprising a. The method of claim 1,
The circulation pipe 3100 includes a first circulation pipe 3110 formed at one side of the flow path control device 3000 and a second circulation pipe 3120 formed at the other side of the flow path control device 3000.
The connection pipe 4000 has one side connected to the upper end of the heat exchanger 6000 and the other end connected to the first connection pipe 4100 and one side to the lower end of the heat exchanger 6000. The second connection pipe 4200 and the third connection pipe 4300 connected to the other circulation pipe 3110 and the second circulation pipe 3120 and the other side,
The first circulation pipe 3110 is installed to be rotatable in the vertical direction to the first circulation pipe 3110, and when the indoor air moves to the first circulation pipe 3110, the external air is the first circulation pipe A first opening and closing plate 3111 is formed to rotate upward to block the flow into the 3110 to seal the other side of the second connecting pipe 4200.
The second circulation pipe 3120 is installed to be rotatable up and down in the second circulation pipe 3120, and when the indoor air moves to the second circulation pipe 3120, external air is moved to the second circulation pipe 3120. Multi-purpose ventilation system, characterized in that the second opening and closing plate (3121) is formed to rotate in the upward direction to block the flow into the (3120) to seal the other side of the third connecting pipe (4300). 3. The method of claim 2,
The first opening and closing plate is installed at the end of the inlet pipe 5000 and forced to suck external air when the indoor air moves to the circulation pipe 3100 so that external air can flow into the circulation pipe 3100. A suction fan 5100 for opening the 3111 and the second opening and closing plate 3121; And
The heater unit 5200 is connected to the controller 7000 and generates heat so as to increase the temperature of the suctioned external air in contact with the external air sucked from the suction fan 5100 when a specific signal is received from the controller 7000. Multipurpose ventilation system, characterized in that is provided. The method of claim 1,
The heat exchanger 6000
A plurality of heat conductive pipes 6100 having one side in contact with indoor air discharged to the discharge pipe 2000 and the other side in contact with external air introduced into the connection pipe 4000;
A plurality of through holes are formed to be fitted to the heat conductive pipe 6100, and a plurality of heat conductive pins 6200 are inserted into the heat conductive pipe 6100 and are arranged to be spaced apart at a predetermined interval;
A case 6300 inside which is hollow so that the heat conductive pipe 6100 and the heat conductive fin 6200 are accommodated and fixed to the discharge pipe 2000 and the connection pipe 4000;
A heat insulator 6400 formed inside the case 6300 and partitioning the inside of the case 6300 so that indoor air discharged to the discharge pipe 2000 and external air sucked into the connection pipe 4000 are not mixed with each other;
Multipurpose ventilation system comprising a. 5. The method according to any one of claims 1 to 4,
The upper end of the discharge pipe 2000, the outer insulation 2200 surrounding the outer peripheral surface of the discharge pipe 2000 and the upper and lower sides are opened and formed with a diameter larger than the diameter of the discharge pipe 2000, the inner surface is the discharge pipe (2000) Multi-ventilation system, characterized in that the ventilator 8000 is fastened to the upper side of the discharge pipe (2000) spaced apart from the outer surface of the). The method of claim 1,
The ventilation unit 1000 is provided with an encoder 1300 for measuring the rotational speed of the second ventilation fan 1200,
The controller 7000 recognizes the suction amount of the indoor air flowing into the lower part of the ventilation part 1000 according to the rotation speed of the second ventilation fan 1200 measured from the encoder 1300 and the first rotary blade ( Multipurpose ventilation system, characterized in that for controlling the number of revolutions of the motor (1110) for rotating. The method of claim 1,
The flow path control device 3000
An outer frame 3200 installed at an upper side of the ventilation part 1000 and having an upper support 3210 at an inner upper side and a lower support 3220 at an inner lower side and the circulation pipe 3100 formed at an outer side thereof;
A guide arm 3300 protruding upward from the lower support 3220;
A driving shaft 3400 penetrating through the upper support 3210 and having one side rotatably coupled to the lower support 3220;
A drive motor 3500 installed at the other side of the drive shaft 3400 to rotate the drive shaft 3400;
An upper and lower sides are opened and positioned inside the outer frame 3200, and a cover fixing unit 3610 which is fastened to the driving shaft 3400 to rotate about the driving shaft 3400 is formed therein, and has an opening on an outer circumferential surface thereof. 3630 is formed and in communication with the inside, when the drive shaft 3400 is rotated to one side by a set angle, the opening 3620 and the circulation pipe 3100 is in communication with the indoor air to the circulation pipe 3100. An inner frame 3600 which moves, and when the driving shaft 3400 rotates to another side by a set angle, the opening 3620 is displaced from the circulation pipe 3100 and the outer surface seals the circulation pipe 3100;
The cover fixing unit 3610 is installed to be rotatable in the vertical direction, and when the drive shaft 3400 rotates to one side by a set angle, the lower surface is gradually rotated upwards while contacting the upper end of the guide arm 3300, A blocking cover 3700 which closes the open upper side of the outer frame 3200 and gradually rotates downward when the driving shaft 3400 rotates to the other side by a set angle to open the upper side of the outer frame 3200;
Multipurpose ventilation system comprising a.

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