JP5099095B2 - Blower - Google Patents

Description

  The present invention relates to a blower that sucks air such as outside air into a main body through a duct and supplies the sucked air into a room or the like.

  As a blower that sucks air into the main body through the duct and blows out the sucked air, it sucks outside air into the main body through the duct, and a ventilation device that supplies air from the supply grill to the room through the main body or duct, Alternatively, a ventilator that sucks into the main body through a duct and exhausts the sucked air to the outside through the duct, and a ventilator that has both air supply and exhaust functions have been proposed.

  In such a ventilator, a configuration in which a fireproof damper is provided on an outdoor grill or a suction grill connected to a main body portion via a duct has been proposed (for example, see Patent Document 1).

Japanese Patent No. 3521733

  In the configuration where the outdoor grill connected to the main body through the duct is equipped with a fire damper, the fire damper is closed by detecting a predetermined heat to prevent the air from being exhausted from the outdoor grill above a predetermined temperature. be able to. In addition, in the configuration in which the suction grille connected to the main body part via the duct is provided with a fireproof damper, if there is a heat source outside the suction grille, the fireproof damper is closed upon detection of a predetermined heat, so that the temperature exceeds a predetermined temperature. The air can be prevented from being sucked into the duct.

  However, when the duct is a heat source, it has not been possible to prevent air having a predetermined temperature or higher from being sucked into the main body.

  The present invention has been made to solve such a problem, and an object of the present invention is to provide a blower capable of preventing air having a predetermined temperature or higher from being sucked into the main body.

In order to solve the above-described problems, the present invention has a blower unit that sucks air and blows out the sucked air, a main body unit that is installed on the back of the ceiling, and is formed in the main body unit. A suction port through which air is sucked, a duct connecting member to which a body part is detachably attached and attached to a suction port of the body part, a duct member through which air passes, and a duct connecting member are provided in the duct connecting member. Shielding means for opening and closing the opening, biasing means for biasing the shielding means to close the duct connecting member, holding the shielding means in an open state against the biasing force of the biasing means, and air sucked into the main body A temperature fuse that dissolves with heat to release the open state of the shielding means when the temperature rises to a predetermined temperature, and the temperature fuse is shielded on the upstream side of the main body with respect to the air flow sucked into the main body. For means In a direction to be the main body side, a blower disposed inside the duct connecting members.

  In the blower of the present invention, air is sucked into the main body through the duct. When the temperature of the air sucked into the main body is detected by the temperature detecting means and the temperature of the air sucked into the main body rises to a predetermined temperature, the suction of the air into the main body is blocked by the suction preventing means.

  According to the blower of the present invention, even if a duct through which air sucked into the main body passes is located in the heat source, the air suction can be blocked by the temperature rise, and thus the main body can be protected from heat.

It is an internal block diagram which shows an example of the heat exchange type | mold ventilation apparatus as 1st Embodiment. It is a top view which shows an example of the heat exchange type ventilator as 1st Embodiment. It is a front view which shows an example of the heat exchange type | mold ventilation apparatus as 1st Embodiment. It is a disassembled perspective view which shows the duct connection structure in the heat exchange type ventilation apparatus as 1st Embodiment. It is a perspective view which shows an example of the fireproof damper of this Embodiment. It is a sectional side view which shows an example of the fireproof damper of this Embodiment. It is a sectional side view which shows an example of the OA duct joint to which the fireproof damper was attached. It is a perspective view which shows an example of the external air and exhaust duct joint attachment frame provided with the OA duct joint to which the fireproof damper was attached. It is a block diagram of the building which shows the example of installation of the heat exchange type | mold ventilation apparatus as 1st Embodiment. It is an internal block diagram which shows an example of the intermediate | middle duct fan as another example of 1st Embodiment. It is an internal block diagram which shows the inspection state of the intermediate | middle duct fan as another example of 1st Embodiment. It is an internal block diagram which shows an example of the heat exchange type | mold ventilation apparatus as 2nd Embodiment. It is a functional block diagram which shows an example of the heat exchange type | mold ventilation apparatus as 2nd Embodiment. It is an internal block diagram which shows an example of the heat exchange type ventilator as 3rd Embodiment of an air blower. It is a functional block diagram which shows an example of the heat exchange type | mold ventilation apparatus as 3rd Embodiment. It is a flowchart which shows an example of operation | movement of the heat exchange type | mold ventilation apparatus as 3rd Embodiment. It is an internal block diagram which shows an example of the air purifying apparatus as other embodiment. It is a disassembled perspective view which shows an example of the air purifying apparatus as other embodiment. It is a block diagram of the building which shows the example of installation of the air purifying apparatus as other embodiment.

  Hereinafter, an embodiment of a blower of the present invention will be described with reference to the drawings.

<Configuration example of the blower according to the first embodiment>
FIG. 1 is an internal configuration diagram showing an example of a heat exchange type ventilator as a first embodiment of a blower of the present invention, and FIG. 2 is an example of a heat exchange type ventilator as a first embodiment. FIG. 3 is a front view showing an example of a heat exchange type ventilator as a first embodiment.

  A heat exchange type ventilation apparatus 1A as the first embodiment includes a main body 2A and a front panel 3. 1 A of heat exchange type | mold ventilation apparatuses are attached in the form with which the main-body part 2A is embedded in the ceiling 100 of a building, and the front panel 3 is attached to the lower surface of the main-body part 2A exposed from the ceiling panel 101 so that attachment or detachment is possible.

  1 A of heat exchange type | mold ventilation apparatuses equip the main-body part 2A with the air supply fan 4SA which is a ventilation means which produces | generates the flow of the air which draws in external air OA from the outdoors, and blows off supply air SA indoors. Further, the heat exchange type ventilation apparatus 1A includes an exhaust fan 4EA, which is a blowing unit that sucks the return air RA from the room and generates an air flow that blows out the exhaust EA to the outside. Furthermore, the heat exchanging ventilator 1A includes a heat exchange element 5 for exchanging heat between the outside air OA sucked from the outside by the supply fan 4SA and the return air RA sucked from the room by the exhaust fan 4EA in the main body 2A. Prepare.

  The heat exchange element 5 has a rectangular parallelepiped shape in which a material forming the heat exchange air passage on the supply side and a material forming the heat exchange air passage on the exhaust side are stacked in a direction orthogonal to the air passage. In the heat exchange element 5, the heat exchange air passage on the supply side and the heat exchange air passage on the exhaust side are partitioned by a partition wall that has heat conductivity and does not allow air to pass therethrough, and the air passing through the heat exchange air passage on the supply side And the air passing through the heat exchange air passage on the exhaust side.

  The main body 2A includes an air passage forming member 6 that constitutes the supply air passage 20SA and the exhaust air passage 20EA, and a cabinet 7 in which the air passage forming member 6 is accommodated. The air path forming member 6 includes an air supply fan case 40SA and an exhaust fan case 40EA made of, for example, a foam material.

  In the supply fan case 40SA, a fan suction port 42SA is formed in the upper portion along the axial direction of the supply fan 4SA, and a fan outlet 43SA is formed in the tangential direction of the supply fan 4SA. The exhaust fan case 40EA has a fan suction port 42EA formed in the upper portion along the axial direction of the exhaust fan 4EA, and is not shown in the tangential direction of the exhaust fan 4EA in the direction opposite to the fan outlet 43SA of the supply fan case 40SA. A fan outlet is formed.

  The fan motor 41M is an example of a drive unit, and is configured by a motor of both shafts. The supply fan 4SA is attached to the lower shaft, the exhaust fan 4EA is attached to the upper shaft, and the supply fan 4SA and the exhaust fan. 4EA is arranged on the same axis. The fan motor 41M is attached to a partition plate 60 that partitions the supply fan case 40SA and the exhaust fan case 40EA.

  An air supply air passage 20SA is formed in the main body 2A by the air passage forming member 6 and the cabinet 7 so that the air sucked from the fan air inlet 42SA is blown out from the fan air outlet 43SA. Further, an exhaust air passage 20EA is formed through which air sucked from the fan suction port 42EA is blown out from a fan blowout port (not shown).

  The cabinet 7 has a rectangular parallelepiped shape with an open bottom surface, and is integrally formed of a resin material, for example. The cabinet 7 is formed with an outside air inlet 70OA connected to the suction side of the supply air passage 20SA and an exhaust outlet (not shown) connected to the outlet side of the exhaust air passage 20EA, each having an opening on one side surface in the longitudinal direction. . Further, the cabinet 7 is formed with an air supply outlet 70SA connected to the outlet side of the air supply passage 20SA with an opening provided on the other side surface in the longitudinal direction.

  The heat exchange type ventilation apparatus 1 </ b> A is configured such that a pressing member 72 is sandwiched between the air passage forming member 6 and the pressing sheet metal 71, and the pressing sheet metal 71 is attached to the lower surface of the cabinet 7. The heat exchange element 5 is supported by the air passage forming member 6, the cabinet 7, and the pressing member 72 on the main body 2 </ b> A in which the pressing sheet metal 71 is attached to the cabinet 7. Further, a return air suction port 70RA connected to the heat exchange element 5 is formed by a gap between the side surface of the cabinet 7 and the presser metal plate 71.

  The heat exchange type ventilation apparatus 1A includes an OA filter 8A that cleans the outside air OA sucked by the air supply fan 4SA. The OA filter 8A is vertically attached to the main body 2A inside the outside air inlet 70OA, and opens the detachable port cover (not shown) provided on the front panel 3, so that the OA filter 8A moves vertically with respect to the main body 2A. Detachment is performed.

  The heat exchange type ventilation device 1A includes an RA filter 8B that cleans the return air RA sucked by the exhaust fan 4EA. The RA filter 8B is detachably attached to the inside of the suction grill 30 formed on the front panel 3. The front panel 3 is configured such that the suction grill 30 can be opened and closed, and the RA filter 8B is attached and detached by opening and closing the suction grill 30.

  FIG. 4 is an exploded perspective view showing a duct connection structure in the heat exchange type ventilator as the first embodiment. Next, referring to each figure, the duct connection structure in the heat exchange type ventilator 1A explain.

  The heat exchanging ventilator 1A has an outside air / exhaust duct joint mounting frame 74a in which an OA duct joint 73OA and an EA duct joint 73EA are provided on one side surface of the cabinet 7 where an outside air inlet 70OA and an exhaust outlet (not shown) are formed. Is attached. The OA duct joint 73OA is an example of a duct connection member. When the main body 2A is attached to the outside air / exhaust duct joint attachment frame 74a, the OA duct joint 73OA and the outside air suction port 70OA are connected. Further, the EA duct joint 73EA is connected to an exhaust outlet (not shown).

  In the heat exchange ventilator 1A, an air supply duct joint mounting frame 74b provided with a plurality of SA duct joints 73SA is attached to the other side surface of the cabinet 7 where the air supply outlet 70SA is formed. When the main body 2A is attached to the air supply duct joint attachment frame 74b, the SA duct joint 73SA and the air supply outlet 70SA are connected.

  The heat exchanging ventilator 1A has a sub suction duct joint mounting frame 74c in which a sub suction duct joint 73SE is provided on another side surface of the cabinet 7 where the sub suction port 70SE that exhausts air without passing through the heat exchange element 5 is formed. Is attached. When the main body 2A is attached to the sub suction duct joint mounting frame 74c, the sub suction duct joint 73SE and the sub suction port 70SE are connected.

  In the process of mounting the heat exchange type ventilation device 1A, the outside air duct 80OA shown in FIG. 2 is connected to the OA duct joint 73OA and the exhaust duct 80EA is connected to the EA duct joint 73EA on the wooden frame 102a constituting the ceiling 100 shown in FIG. To the outside air / exhaust duct joint mounting frame 74a. Further, an air supply duct joint mounting frame 74b in which all of the air supply duct 80SA or a predetermined SA duct joint 73SA is connected is attached to the wooden frame 102b constituting the ceiling 100. Further, a sub suction duct joint mounting frame 74c in which the sub suction duct 80SE is connected to the sub suction duct joint 73SE is attached to a wooden frame (not shown).

  The outside air / exhaust duct joint mounting frame 74a, the air supply duct joint mounting frame 74b, and the auxiliary suction duct joint mounting frame 74c attached to the wooden frame of the ceiling 100 are connected by a mounting bracket 75 or the like, as shown in FIG. It is configured as one unit.

  The main body 2A of the heat exchange type ventilation device 1A includes wooden frames constituting the ceiling 100, outside air / exhaust duct joint mounting frames 74a, air supply duct joint mounting frames 74b, and auxiliary suction duct joints attached to the wooden frames. It is inserted from below into an opening formed by the mounting frame 74 c, and is attached to the outside air / exhaust duct joint mounting frame 74 a and the air supply duct joint mounting frame 74 b and each wooden frame, and is fixed to the ceiling 100.

  A ceiling panel 101 is attached to the ceiling 100 to which the main body 2A of the heat exchange type ventilator 1A is fixed so that the lower surface of the main body 2A is exposed, and the front surface is exposed to the lower surface of the main body 2A exposed from the ceiling panel 101. A panel 3 is attached.

  FIG. 5 is a perspective view showing an example of the fireproof damper of the present embodiment, and FIG. 6 is a side sectional view showing an example of the fireproof damper of the present embodiment. FIG. 7 is a side sectional view showing an example of an OA duct joint to which a fire damper is attached. FIG. 8 is an example of an outside air / exhaust duct joint attachment frame having an OA duct joint to which a fire damper is attached. Next, a fireproof damper provided in the heat exchange type ventilator 1A will be described with reference to the drawings.

  The fire damper 9 is an example of a suction prevention means, and is provided in an air passage through which air sucked into the main body 2A passes. In the present embodiment, the OA duct joint 73OA through which the outside air OA sucked into the main body 2A by the operation of the air supply fan 4SA passes, and the sub-intake duct joint through which the indoor air sucked into the main body 2A by the operation of the exhaust fan 4EA passes. A fireproof damper 9 is provided at 73SE.

  The fireproof damper 9 is attached to a cylindrical air passage forming member 90, two shielding members 91 for opening and closing the air passage forming member 90 by a rotation operation about a shaft 91a, and a direction in which the shielding member 91 is opened. The spring 92 to be energized, the two shielding members 91 that opened the air passage are held in the open state, the temperature fuse 93 that releases the open state upon detection of a predetermined temperature, and the opening angle of the shielding member 91 is regulated. The metal fitting 94 is provided to prevent the temperature fuse 93 from being removed in a normal state.

  The shielding member 91 is an example of a shielding means, and is configured by a semicircular metal plate material, and linear side portions are rotatably connected by a metal shaft 91a. The spring 92 is an example of an urging means, and is constituted by a metal torsion coil spring. The coil portion is attached to the shaft 91a, and leg portions (not shown) extending from both sides of the coil portion abut against the shielding member 91, respectively.

  The two shielding members 91 are folded with the shaft 91a as a fulcrum in a direction in which the outer peripheral portion of the arc shape is brought close to each other so as to be substantially parallel to each other, thereby opening the air path in a state where the spring 92 is elastically deformed. Open. Further, the two shielding members 91 are closed by closing the air passage by opening them so as to be substantially circular with the shaft 91a as a fulcrum by the restoring force of the elastically deformed spring 92.

  The air passage forming member 90 is made of a metal plate material, and a stopper 90a with which the outer peripheral portion of the closed shielding member 91 abuts is formed on the inner periphery of the end portion on the side supporting the shaft 91a, so that the spring 92 is restored. The outer peripheral portion of the shielding member 91 that is in the closed state by the force is pressed by the stopper 90a so that the closed state can be maintained.

  The thermal fuse 93 is an example of a temperature detecting means and is made of a metal material that melts at a predetermined temperature. The thermal fuse 93 is attached to the tip portions of the two shielding members 91 in the open state, and holds the shielding member 91 in the open state. The thermal fuse 93 melts at a predetermined temperature, 72 ° C. or higher in this example, and is removed from the shielding member 91. As a result, the shielding member 91 is opened and closed by the restoring force of the spring 92.

  7 and 8, the fire damper 9 is shown attached to the OA duct joint 73OA. The fire damper 9 is attached to the inside of the OA duct joint 73OA in such a direction that the temperature fuse 93 is on the side of the main body 2A shown in FIG. The diameters of the inner circumference of the OA duct joint 73OA and the outer circumference of the air path forming member 90 of the fire damper 9 are matched, and an air path passing through the OA duct joint 73OA is formed when the shielding member 91 is open. When the shielding member 91 is in the closed state, the air path passing through the OA duct joint 73OA is closed.

  The configuration in which the fire damper 9 is attached to the sub suction duct joint 73SE is the same as the configuration in which the fire damper 9 is attached to the OA duct joint 73OA described with reference to FIGS.

<Installation example of heat exchange type ventilator>
FIG. 9 is a configuration diagram of a building showing an installation example of the heat exchange type ventilation device as the first embodiment. In FIG. 9, the building 200 is a single-family house.

  The building 200 includes a plurality of rooms R1, R2, R3, a corridor R4, and the like partitioned by walls and the like. The walls and doors that partition the rooms R1, R2, R3 and the corridor R4 are provided with a gallery not shown. An undercut is provided at the bottom of the door.

  In the building 200, for example, the heat exchange ventilator 1A is installed in the form of exposing the front panel 3 shown in FIG. An air supply grill 201 is attached to the ceiling of the rooms R1, R2, and R3.

  In the heat exchange type ventilator 1A, air supply ducts 80SA are respectively connected to four SA duct joints 73SA shown in FIG. 2 and the like, and each of the four air supply ducts 80SA is a ceiling of the rooms R1, R2, and R3. It extends to the supply air grill 201 installed in the air supply grill 201 and is connected to the supply air grill 201. Here, the room R1 is, for example, a living room, and a room with a large area such as a living room may be provided with the supply air grill 201 in two places.

  In the heat exchange ventilator 1A, an outside air duct 80OA is connected to an OA duct joint 73OA shown in FIG. 2 and the like, and the outside air duct 80OA is connected to an outdoor grill (not shown) installed on a wall facing the outside of the building 200. .

  Further, in the heat exchange type ventilation apparatus 1A, an exhaust duct 80EA is connected to the EA duct joint 73EA shown in FIG. 2, and the exhaust duct 80EA is connected to an outdoor grill (not shown) installed on a wall facing the outside of the building 200. The

  Further, in the heat exchanging ventilator 1A, the sub suction duct 80SE is connected to the sub suction duct joint 73SE shown in FIG. 2 and the like, and the sub suction duct 80SE is connected to the sub suction grill 202 installed on the ceiling of the toilet. .

  The suction grill 30 formed on the front panel 3 of the heat exchange type ventilation device 1A is located in the corridor R4. The building 200 is configured such that air flows between the rooms R1, R2, R3 and the corridor R4 through openings such as undercuts and louvers provided on the doors.

  As a result, the supply air SA is blown out from the supply air grill 201 in each room R1, R2, R3, and the air in each room R1, R2, R3 passes through the openings such as undercuts and louvers, and heat in the corridor R4. A flow of air sucked from the exchangeable ventilator 1A is formed. In addition, since the air in the toilet is sucked from the auxiliary suction grill 202, the odor in the toilet is prevented from leaking into the other rooms due to the air flow sucked into the suction grill 30 of the heat exchange type ventilator 1A. Yes.

<Operation example of heat exchange type ventilator>
Next, with reference to each figure, operation | movement of 1 A of heat exchange type | mold ventilation apparatuses as 1st Embodiment is demonstrated.

  1 A of heat exchange type | mold ventilation apparatuses comprise the 1st type ventilation system by which supply and exhaust are performed by mechanical ventilation, and are continuously operated for 24 hours by the ventilation air volume by which the air of the building 200 is replaced in a predetermined time. That is, in the heat exchange type ventilator 1A, the supply fan 4SA and the exhaust fan 4EA are driven at a rotational speed at which a predetermined ventilation air volume is obtained.

  When the air supply fan 4SA is driven by the fan motor 41M, the heat exchange type ventilator 1A sucks air from the fan suction port 42SA in the supply air passage 20SA, and the air sucked from the fan suction port 42SA Blows out from 43SA.

  Further, in the heat exchanging ventilator 1A, when the exhaust fan 4EA is driven by the fan motor 41M, air is sucked from the fan suction port 42EA in the exhaust air passage 20EA, and the air sucked from the fan suction port 42EA is not illustrated. It blows out from the fan outlet.

  Thereby, in the heat exchange type ventilation apparatus 1A, the outside air OA is sucked from the outdoor grill on the outer wall of the building 200 through the outside air duct 80OA and from the OA duct joint 73OA to the supply air passage 20SA, and is supplied through the heat exchange element 5. SA is blown out.

  In addition, the return air RA from each of the rooms R1 to R3 is sucked into the exhaust air passage 20EA from the suction grill 30 of the front panel 3 facing the corridor R4 through an opening (not shown) such as undercut or louver, and the heat exchange element 5 The exhaust EA that has passed through the exhaust duct 80EA passes through the outdoor grill on the outer wall of the building 200 and is discharged to the outside.

  Then, the external air OA passing through the supply air passage 20SA and the return air RA passing through the exhaust air passage 20EA are heat-exchanged by passing through the heat exchange element 5, and the supply air SA brought close to room temperature is supplied from the supply grill 201. By blowing out into the room, fresh air (outside air) whose temperature is adjusted is supplied to the room. In addition, dirty air in the room is exhausted outdoors.

  Now, the temperature of the air sucked into the main body 2A of the heat exchange type ventilation device 1A is detected by the temperature fuse 93 of the fireproof damper 9 provided in the OA duct joint 73OA. If the temperature of the air sucked into the main body 2A through the OA duct joint 73OA is below a predetermined temperature, the fire prevention damper 9 holds the shielding member 91 in the open state by the temperature fuse 93.

  On the other hand, when the temperature of the air sucked into the main body 2A through the OA duct joint 73OA becomes equal to or higher than a predetermined temperature, the thermal fuse 93 is melted and removed from the shielding member 91, and the shielding member 91 is opened by the restoring force of the spring 92. The air path is closed.

  Thereby, even if the driving of the air supply fan 4SA is continued, air is not sucked into the main body 2A through the OA duct joint 73OA, and heat above a predetermined temperature is prevented from being sucked into the main body 2A. Part 2A is protected from heat.

  In the unlikely event that a fire breaks out of the ceiling of the building 200 and spreads to the outside air duct 80OA, the heat from the fire is detected by the temperature fuse 93 of the fire damper 9 and the temperature fuse 93 is melted and OA is fired by the fire damper 9 Duct joint 73OA is closed.

  Thereby, even if the driving of the air supply fan 4SA is continued, the flow of the air sucked into the main body 2A through the OA duct joint 73OA is blocked. Since the shielding member 91 and the like are made of a metal material, the fire-proof damper 9 is not melted by the heat of the fire, and the heat from the fire is prevented from being sucked into the main body 2A and spread to the main body 2A. Can be prevented.

  Similarly, by providing the auxiliary suction duct joint 73SE with the fireproof damper 9, when the temperature of the air sucked into the main body 2A through the auxiliary suction duct joint 73SE becomes equal to or higher than a predetermined temperature, the auxiliary suction duct joint 73SE is used by the fireproof damper 9. Is blocked, heat of a predetermined temperature or higher is prevented from being sucked into the main body 2A, and the main body 2A is protected from heat.

  The fire damper 9 is attached to the OA duct joint 73OA and the sub suction duct joint 73SE in such a direction that the temperature fuse 93 is on the main body 2A side. As shown in FIG. 4, the heat exchange type ventilator 1A has an external air / exhaust duct joint mounting frame 74a etc. in which the outside air / exhaust duct joint mounting frame 74a to which the OA duct joint 73OA is attached is independent of the main body 2A. The main body 2A is installed on the ceiling 100 in a separate process.

  Thereby, when it is necessary to inspect the temperature fuse 93, if the main body 2A is removed from the ceiling 100, the outside air / exhaust duct joint mounting frame 74a to which the outside air duct 80OA or the like is connected is removed from the ceiling 100. Since the thermal fuse 93 is exposed in the OA duct joint 73OA, the inspection work can be easily performed.

  On the other hand, the fireproof damper 9 may be configured to be attached to the OA duct joint 73OA and the sub suction duct joint 73SE in the direction in which the temperature fuse 93 is opposite to the main body 2A. With such a configuration, heat can be detected on the front side of the main body 2A.

<Another configuration example of the blower according to the first embodiment>
The air blower of the present invention may be a ventilator that does not have a heat exchanging function in addition to the heat exchange ventilator described above, and can be applied to a ventilator called an intermediate duct fan, for example. is there.

  FIG. 10 is an internal configuration diagram showing an example of an intermediate duct fan as another example of the first embodiment of the blower of the present invention, and FIG. 11 is a diagram of the first embodiment of the blower of the present invention. It is an internal block diagram which shows the inspection state of the intermediate | middle duct fan as another example.

  The intermediate duct fan 1B as another example of the first embodiment is attached in a form in which the main body 2B is embedded in the ceiling 100 of the building. The intermediate duct fan 1B includes an air supply fan unit 44SA, which is a blowing unit that sucks outside air OA from outside and generates an air flow that blows out the air supply SA into the room, in the main body 2B. The air supply fan unit 44SA includes a fan motor 44M, an air supply fan 45SA that is rotationally driven by the fan motor 44M, and an air supply fan case 46SA that constitutes the air supply air passage 23SA, and is detachable from the main body 2B. Composed.

  In the supply fan case 46SA, a fan suction port 47SA is formed in the lower portion along the axial direction of the supply fan 45SA, and a fan outlet 48SA is formed in the tangential direction of the supply fan 45SA.

  The main body 2B has a rectangular parallelepiped shape with an open bottom surface and is made of a metal material. The main body 2 </ b> B is formed with an open air inlet 76 </ b> OA connected to the suction side of the supply air passage 23 </ b> SA with an opening on one side surface. The main body 2B is formed with an air supply outlet 76SA connected to the outlet side of the air supply air passage 23SA with an opening provided on the other side surface.

  The intermediate duct fan 1B has a cover 24 detachably attached to the lower surface of the main body 2B. As shown in FIG. 11, the air supply fan unit 44SA is detached from the main body 2B by removing the cover 24 from the main body 2B. It is possible.

  The intermediate duct fan 1B includes an OA filter 8C that cleans the outside air OA sucked by the air supply fan 45SA. The OA filter 8C is vertically attached to the main body 2B inside the outside air inlet 76OA, and can be attached to and detached from the main body 2B by moving in the vertical direction by opening the attach / detach port cover 24a provided on the cover 24. Done.

  The intermediate duct fan 1B includes an OA duct joint 77OA connected to the outside air inlet 76OA on one side surface of the main body 2B where the outside air inlet 76OA is formed. Further, the intermediate duct fan 1B includes an SA duct joint 77SA connected to the air supply outlet 76SA on the other side surface of the main body 2B where the air supply outlet 76SA is formed.

  The intermediate duct fan 1B has an OA duct joint 77OA connected to an outdoor air duct 81OA connected to an outdoor grill provided on the outer wall of the building (not shown), and an air supply provided on the ceiling of the room of the building (not shown) to the SA duct joint 77SA. An air supply duct 81SA connected to the grill is connected.

  The intermediate duct fan 1B includes the fire damper 9 described in FIGS. 5 and 6 and the like in the OA duct joint 77OA that forms an air passage through which air sucked into the main body 2B passes. The fire damper 9 is attached to the inside of the OA duct joint 77OA in such a direction that the temperature fuse 93 is on the main body 2B side shown in FIG.

<Operation example of intermediate duct fan>
When the supply fan 45SA is driven by the fan motor 44M, the intermediate duct fan 1B sucks air from the fan suction port 47SA in the supply air passage 23SA, and the air sucked from the fan suction port 47SA from the fan blowout port 48SA. Blown out.

  Thereby, in the intermediate duct fan 1B, the outside air OA is sucked from the outdoor grill on the outer wall of the building (not shown) through the outside air duct 81OA and from the OA duct joint 77OA to the air supply passage 23SA, and the air duct 81SA is drawn from the SA duct joint 77SA. The street supply air SA is blown out.

  Even in the intermediate duct fan 1B, the temperature of the air sucked into the main body 2B is detected by the temperature fuse 93 of the fireproof damper 9 provided in the OA duct joint 77OA. If the temperature of the air sucked into the main body 2B through the OA duct joint 77OA is lower than the predetermined temperature, the fire damper 9 holds the shielding member 91 in the open state by the temperature fuse 93.

  On the other hand, when the temperature of the air sucked into the main body 2B through the OA duct joint 77OA becomes equal to or higher than a predetermined temperature, the temperature fuse 93 is melted and removed from the shielding member 91, and the shielding member 91 is opened by the restoring force of the spring. The road is closed.

  As a result, even if the driving of the air supply fan 45SA is continued, air is not sucked into the main body 2B through the OA duct joint 77OA, and heat above a predetermined temperature is prevented from being sucked into the main body 2B. Part 2B is protected from heat.

  If a fire breaks out in the back of the building and spreads out to the outside air duct 81OA, the heat from the fire is detected by the temperature fuse 93 of the fireproof damper 9, and the temperature fuse 93 is melted and the fireproof damper 9 melts the OA duct. The joint 77OA is closed.

  Thereby, even if the driving of the air supply fan 45SA is continued, the flow of air sucked into the main body 2B through the OA duct joint 77OA is blocked. Since the shielding member 91 and the like are made of a metal material, the fire-proof damper 9 is not melted by the heat of the fire, and the heat from the fire is prevented from being sucked into the main body 2B and spread to the main body 2B. Can be prevented.

  As shown in FIG. 11, the intermediate duct fan 1B opens the inspection lid 104 covering the inspection port 103a formed in the ceiling panel 103, and removes the cover 24 from the main body 2B. It is detachable from 2B.

  As a result, when the air supply fan unit 44SA is removed from the main body 2B, such as when it is necessary to check the temperature fuse 93, the main body 2B to which the outside air duct 81OA or the like is connected is removed from the ceiling 100 without being removed. Since 93 is exposed in the OA duct joint 77OA, inspection work can be easily performed.

<Configuration Example of Blower Device of Second Embodiment>
FIG. 12 is an internal configuration diagram showing an example of a heat exchange type ventilator as a second embodiment of the blower of the present invention, and FIG. 13 shows heat as a second embodiment of the blower of the present invention. It is a functional block diagram which shows an example of an exchange type ventilation apparatus.

  The heat exchanging ventilator 1C as the second embodiment includes a temperature fuse 111 that detects the temperature of the outside air OA sucked into the main body 2C as the temperature detection means, and the suction prevention means is the temperature fuse 111. This is realized by a control function based on the temperature of the detected outside air OA. Other configurations of the heat exchange type ventilator 1C may be the same as those described in FIG.

  The heat exchange type ventilation device 1C includes a control board 112 as a control means for driving the fan motor 41M, and a remote control device 113 for operating the heat exchange type ventilation device 1C, and a power source 114 for supplying electricity to the fan motor 41M. The thermal fuse 111 is mounted on the power supply line 114a between the control board 112 and the control board 112.

  The thermal fuse 111 is mounted in the supply air passage 20SA upstream of the supply air fan 4SA inside the outside air inlet 70OA, and detects the temperature of the outside air OA sucked into the main body 2C.

  If the temperature of the air sucked into the main body 2C through the OA duct joint 73OA is below a predetermined temperature, the heat exchange type ventilation device 1C is electrically connected between the power source 114 and the control board 112 by the temperature fuse 111. Electricity is supplied from the power source 114 to the control board 112.

  On the other hand, when the temperature of the air sucked into the main body 2C reaches a predetermined temperature, which is 72 ° C. or higher in this example, the thermal fuse 111 is melted and the supply of electricity from the power source 114 to the control board 112 is interrupted. As a result, the supply fan 4SA stops, so that the flow of air sucked into the main body 2C is not generated, and heat above a predetermined temperature is prevented from being sucked into the main body 2C, and the main body 2C is heated. Protected from.

  In the unlikely event that a fire breaks out in the ceiling of the building where the heat exchanging ventilator 1C is installed and the fire spreads to the outside air duct 80OA, the heat from the fire is detected by the thermal fuse 111 and the thermal fuse 111 is melted. The supply of electricity from the power supply 114 to the control board 112 is cut off.

  As a result, the air supply fan 4SA is stopped, so that the flow of air sucked into the main body 2C is not generated, and heat from the fire is prevented from being sucked into the main body 2C, thereby preventing the spread of the fire to the main body 2C. can do.

  In the example shown in FIG. 12, the thermal fuse 111 is provided in the main body 2C inside the outside air inlet 70OA. In the configuration in which the temperature fuse 111 is provided in the main body 2C, wiring work for the temperature fuse is not required when the heat exchange type ventilation device 1C is installed.

  On the other hand, the thermal fuse 111 may be provided in the OA duct joint 73OA. In the configuration in which the thermal fuse 111 is provided in the OA duct joint 73OA, as shown in FIG. 4, when the outside air / exhaust duct joint mounting frame 74a in which the OA duct joint 73OA is provided and the main body 2C are independent, The wiring work of the temperature fuse 111 is required when the exchangeable ventilation device 1C is installed. On the other hand, the temperature of the air before being sucked into the main body 2C can be detected.

  Further, the temperature fuse 111 may be provided also in the sub suction port 70SE or the sub suction duct joint 73SE. Furthermore, the heat exchange type ventilation apparatus 1A as the first embodiment described with reference to FIG. 1 and the like is added with a structure that realizes the suction prevention means with a control function based on the temperature of the outside air OA detected by the thermal fuse 111. When the temperature of the air sucked into the main body reaches a predetermined temperature, the duct joint may be closed with a fireproof damper, and the driving of the air supply fan and the exhaust fan may be stopped. Moreover, the air blower which implement | achieves a suction prevention means with the control function based on the temperature of the external air OA detected by the temperature fuse 111 is not restricted to a heat exchange type ventilator, For example, the intermediate | middle duct fan demonstrated in FIG. But it ’s okay.

<Configuration Example of Blower Device of Third Embodiment>
FIG. 14 is an internal configuration diagram showing an example of a heat exchange type ventilator as a third embodiment of the blower of the present invention, and FIG. 15 shows heat as a third embodiment of the blower of the present invention. FIG. 16 is a functional block diagram showing an example of the exchange-type ventilation device, and FIG. 16 is a flowchart showing an example of the operation of the heat exchange-type ventilation device as the third embodiment of the blower of the present invention.

  The heat exchange type ventilator 1D as the third embodiment includes a thermistor 115 that detects the temperature of the outside air OA sucked into the main body 2D as the temperature detection means, and the suction prevention means is detected by the thermistor 115. This is realized by a control function based on the temperature of the outside air OA. Other configurations of the heat exchange type ventilation device 1D may be the same as those described in FIG.

  The heat exchange type ventilator 1D includes a control board 116 as a control means for driving the fan motor 41M and a remote control device 113 for operating the heat exchange type ventilator 1D. The control board 116 is detected by the thermistor 115. Based on the temperature of the air, the driving and stopping of the fan motor 41M are controlled.

  The thermistor 115 is mounted in the supply air passage 20SA on the upstream side of the supply air fan 4SA inside the outside air inlet 70OA, and detects the temperature of the outside air OA sucked into the main body 2D.

  In step SA1 of FIG. 16, the heat exchange type ventilation device 1D drives the fan motor 41M to rotate the air supply fan 4SA and the exhaust fan 4EA, and executes the ventilation operation. Then, the control board 116 detects the output of the thermistor 115. The temperature of the air sucked into the main body 2D, usually the outside air OA is monitored.

  If it is determined in step SA2 in FIG. 16 that the temperature of the air sucked into the main body 2D through the OA duct joint 73OA is lower than the predetermined temperature, the control board 116 continues to drive the fan motor 41M.

  On the other hand, if it is determined in step SA2 that the temperature of the air sucked into the main body 2D has reached a predetermined temperature, which is 72 ° C. or higher in this example, the control board 116 drives the fan motor 41M in step SA3 in FIG. Stop. As a result, the supply fan 4SA is stopped, so that the flow of air sucked into the main body 2D is not generated, and heat above a predetermined temperature is prevented from being sucked into the main body 2D, and the main body 2D is heated. Protected from.

  After stopping the driving of the fan motor 41M, the control board 116 monitors the temperature of air sucked into the main body 2D from the output of the thermistor 115, and passes through the OA duct joint 73OA and enters the main body 2D in step SA4 of FIG. When it is determined that the temperature of the sucked air is lower than a predetermined temperature, which is 65 ° C. in this example, the driving of the fan motor 41M is resumed.

  Should a fire occur in the back of the building where the heat exchange type ventilation device 1D is installed and spread to the outside air duct 80OA, the heat from the fire is detected by the thermistor 115, and the control board 116 detects the heat. Then, the driving of the fan motor 41M is stopped.

  As a result, the air supply fan 4SA stops, so that the flow of air sucked into the main body 2D is not generated, and heat from the fire is prevented from being sucked into the main body 2D, thereby preventing the spread of the fire to the main body 2D. can do.

  In the example shown in FIG. 14, the thermistor 115 is provided in the main body 2 </ b> D inside the outside air inlet 70 </ b> OA. In the configuration in which the thermistor 115 is provided in the main body 2D, the thermistor wiring work is not required when the heat exchange type ventilation device 1D is installed.

  On the other hand, the thermistor 115 may be provided in the OA duct joint 73OA. In the configuration in which the thermistor 115 is provided in the OA duct joint 73OA, as shown in FIG. 4, heat exchange is performed when the outside air / exhaust duct joint mounting frame 74a in which the OA duct joint 73OA is provided and the main body 2D are independent. The wiring work of the thermistor 115 is required when the mold ventilation device 1D is installed. On the other hand, the temperature of the air before being sucked into the main body 2D can be detected.

  The thermistor 115 may also be provided in the sub suction port 70SE or the sub suction duct joint 73SE. Furthermore, the heat exchange type ventilation apparatus 1A according to the first embodiment described with reference to FIG. 1 and the like is added with a configuration that realizes the suction prevention means with a control function based on the temperature of the outside air OA detected by the thermistor 115. When the temperature of the air sucked into the main body reaches a predetermined temperature, the duct joint may be closed with a fireproof damper and the driving of the air supply fan and the exhaust fan may be stopped. Further, the air blower that realizes the suction preventing means by the control function based on the temperature of the outside air OA detected by the thermistor 115 is not limited to the heat exchange type ventilator. For example, the intermediate duct fan described in FIG. good.

<Configuration example of blower according to another embodiment>
FIG. 17 is an internal configuration diagram showing an example of an air purifier as another embodiment of the blower of the present invention, and FIG. 18 is an example of an air purifier as another embodiment of the blower of the present invention. FIG.

  The air purifying apparatus 1E as another example of the first embodiment includes a circulation fan 120 that takes in indoor air and outside air, supplies the taken air into the room, and takes in the air that has taken in the indoor air. A ventilation fan 121 that exhausts outdoors and an air cleaning filter 122 that cleans the outside air and indoor air taken in by the circulation fan 120 are provided.

  The circulation fan 120 is accommodated in a circulation fan case 120a that forms an air passage, and is driven by a circulation fan motor 120M. The circulation fan case 120a is connected to the outside air / circulation suction port 120b formed by opening the upper surface along the axial direction of the circulation fan 120 and the air flow formed along the tangential direction of the circulation fan 120. An outlet 120c is provided.

  The ventilation fan 121 is accommodated in a ventilation fan case 121a that forms an air passage, and is driven by a ventilation fan motor 121M. The ventilation fan case 121a has a ventilation inlet 121b formed by opening a lower surface along the axial direction of the ventilation fan 121 and a ventilation outlet 121c communicating with an air passage formed along a tangential direction of the ventilation fan 121. Is provided.

  The circulation fan case 120a and the ventilation fan case 121a are accommodated in the main body 123 with the circulation fan case 120a on the upper and lower sides, and are supplied between the upper surface of the circulation fan case 120a and the ceiling surface of the main body 123. A circulation air passage 124 is formed.

  The air cleaning device 1E includes an ion generator 125. The ion generator 125 is mounted such that a discharge surface (not shown) that generates ions is exposed inside the circulation fan case 120a, and ions are supplied into an air passage formed by the circulation fan case 120a.

The ion generator 125 generates both positive ions and negative ions, or negative ions. The principle of generation of positive ions and negative ions is that a corona discharge is caused by boosting and applying an AC voltage taken from a household AC power source or the like between a pair of electrodes opposed so as to interpose a dielectric, Oxygen or water in the air is ionized by receiving energy by ionization, and H ⁺ (H ₂ O) _m (m is an arbitrary natural number) and O ₂ ⁻ (H ₂ O) _n (n is an arbitrary natural number). The main ions are emitted.

These H ⁺ (H ₂ O) _m and O ₂ ⁻ (H ₂ O) _n adhere to the surface of the floating bacteria and chemically react to generate H ₂ O ₂ or .OH as an active species. Since H ₂ O ₂ or .OH exhibits a very strong activity, they can surround and inactivate airborne bacteria in the air. Here, .OH is one kind of active species, and represents radical OH.

  As a result, a positive / negative ion generation mode for generating approximately the same number of positive ions and negative ions is provided, and air that contains approximately the same number of positive ions and negative ions is blown to inactivate airborne bacteria in the air. Can be suppressed.

  Also, it has a negative ion generation mode that generates only negative ions or more negative ions than positive ions, and blowing out air containing negative ions has a relaxing effect such as stabilizing the mind and improving the function of the respiratory organs. It is said that there is.

  In the air cleaning device 1E, an air cleaning filter 122 is detachably attached to the sides of the circulation fan case 120a and the ventilation fan case 121a inside the main body 123.

  The air purifying filter 122 includes, for example, a high efficiency particulate air (HEPA) filter on the panel member 122a. The panel member 122a has a HEPA filter mounted vertically, and a circulation suction grill 122b is formed on the lower surface of the mounting position of the HEPA filter.

  The main body 123 has an outside air suction port 123a connected to the outside air / circulation suction port 120b formed on one side surface, and is connected to the outside air suction port 123a on one side surface of the body portion 123 where the outside air suction port 123a is formed. An OA duct joint 126OA is provided. Moreover, the main-body part 123 is equipped with the EA duct joint 126EA connected to the ventilation blower outlet 121c on another side surface.

  In the air cleaning device 1E, an outdoor air duct connected to an outdoor grill provided on the outer wall of the building is connected to the OA duct joint 126OA, and an exhaust duct connected to the outdoor grill provided on the outer wall of the building is connected to the EA duct joint 126EA. .

  The air cleaning device 1E includes the fire damper 9 described with reference to FIGS. 5 and 6 as an intake prevention unit and a temperature detection unit in an OA duct joint 126OA that constitutes an air passage through which air sucked into the main body 123 passes. The fire damper 9 is attached to the inside of the OA duct joint 126OA in such a direction that the temperature fuse 93 is on the main body 123 side shown in FIG.

  The main body 123 has a front panel 127 attached to the lower surface. The front panel 127 is formed in the cover portion 128 that covers the lower surface of the ventilation suction port 121b, the side surface of the cover portion 128, the ventilation suction opening portion 129 that communicates with the ventilation suction port 121b, and the cover portion 128. A circulation blow grill 130 communicated with the outlet 120c is provided.

<Installation example of air purifier>
FIG. 19 is a configuration diagram of a building showing an installation example of an air cleaning device as another embodiment. In the building 250, the air purifier 1E is installed on the ceiling 252 of the living room 251. In the air purifier 1E, the front panel 127 is exposed to the ceiling 252, and the clean air supply SA is blown out from the circulation blow grill 130 shown in FIG. 17 and the like to the room 251 and from the ventilation suction opening 129 in the room 251. Inhale the return air RA. Further, the return air RA in the living room 251 is sucked from the circulation suction grill 122b.

  The building 250 has an outdoor grill 253OA and an outdoor grill 253EA attached to the outer wall. In the air cleaning device 1E, the OA duct joint 126OA shown in FIG. 17 and the like is connected to the outdoor grill 253OA via the outside air duct 254OA, and sucks the outside air OA. The EA duct joint 126EA is connected to the outdoor grill 253EA via the exhaust duct 254EA, and the sucked indoor air is exhausted as the exhaust EA.

  The building 250 includes, for example, a bathroom drying ventilator 1F having a 24-hour ventilation function in the bathroom 255 as a blower, and the entire building 250 is ventilated by the bathroom drying ventilator 1F and the living room 251 Ventilation is supplementarily performed by the air purifier 1E.

  The bathroom drying and ventilating apparatus 1 </ b> F includes an air suction port and an air outlet on the front panel 270. The bathroom drying ventilation apparatus 1F includes a sub suction port 257 attached to the ceiling of the bathroom dressing room 256 adjacent to the bathroom 255, and a sub suction duct joint 272 attached to the main body 271 having a fan, a heater, and the like. The sub-suction duct 258 is connected. In addition, the exhaust duct joint 273 attached to the main body 271 is connected to the outdoor grill 259 attached to the outer wall via the exhaust duct 260.

  The bathroom drying ventilation apparatus 1F has a function of circulating the air in the bathroom 255 to blow out air or warm air, and a ventilation function of sucking the air in the bathroom 255 and exhausting it to the outside.

  When ventilation is performed by the bathroom drying ventilation apparatus 1F, air is sucked from the bathroom 255 and the bathroom undressing room 256, and air in the living room 251 is sucked from the undercut portion 262 of the door 261 and exhausted to the outside. And the bathroom drying ventilation apparatus 1F is provided with the ventilation air volume which satisfy | fills the predetermined frequency | count of ventilation for performing ventilation for 24 hours in the whole building 250. FIG.

  Also in the air cleaning device 1E, the temperature of the air sucked into the main body 123 through the duct is detected by the temperature fuse 93 of the fireproof damper 9 provided in the OA duct joint 126OA. When the temperature of the air sucked into the main body 123 through the OA duct joint 126OA is below a predetermined temperature, the fire prevention damper 9 holds the shielding member 91 in the open state by the temperature fuse 93.

  On the other hand, when the temperature of the air sucked into the main body 123 through the OA duct joint 126OA becomes equal to or higher than a predetermined temperature, the temperature fuse 93 is melted and removed from the shielding member 91, and the shielding member 91 is opened by the restoring force of the spring. The road is closed.

  As a result, even if the circulation fan 120 continues to be driven, air is not sucked into the main body 123 through the OA duct joint 126OA, and heat above a predetermined temperature is prevented from being sucked into the main body 123. 123 is protected from heat.

  In the unlikely event that a fire breaks out of the ceiling of the building 250 and spreads to the outside air duct 254OA, the heat from the fire is detected by the temperature fuse 93 of the fireproof damper 9, and the temperature fuse 93 melts and OA is fired by the fireproof damper 9. Duct joint 126OA is closed.

  Thereby, even if the drive of the circulation fan 120 is continued, the flow of air sucked into the main body 123 through the OA duct joint 126OA is blocked. Since the shielding member 91 and the like are made of a metal material, the fire-proof damper 9 is not melted by the heat of the fire, and the heat from the fire is prevented from being sucked into the main body 123, so that the fire spreads to the main body 123. Can be prevented.

  The same effect can be obtained by providing the auxiliary suction duct joint 272 of the bathroom drying ventilation apparatus 1F with the fire damper 9 as the suction prevention means and the temperature detection means. Further, in the air cleaning device 1E and the bathroom drying ventilation device 1F, as described in the air blower of the second embodiment or the third embodiment, the suction preventing means is replaced with the temperature fuse 111 or the temperature detecting means. A control function based on the temperature of air detected by the thermistor 115 may be used.

  The present invention is applied to a blower having a configuration in which air such as outside air is sucked into a main body through a duct.

  1A, 1C, 1D ... Heat exchange type ventilation device, 1B ... Intermediate duct fan, 1E ... Air cleaning device, 1F ... Bathroom ventilation drying device, 2A-2D ... Main unit, 4SA ..Air supply fan, 4EA ... exhaust fan, 41M ... fan motor, 5 ... heat exchange element, 7 ... cabinet, 70OA ... outside air inlet, 73OA ... OA duct joint, 74a ... Outside air / exhaust duct joint mounting frame, 9 ... Fire damper, 90 ... Air passage forming member, 91 ... Shield member, 91a ... Shaft, 92 ... Spring, 93 ...・ Temperature fuse, 111... Thermal fuse, 112... Control board, 114... Power supply, 114 a .. Power line, 115.

Claims (2)

A blowing means for sucking air and blowing out the sucked air;
A main body having the air blowing means and installed on a ceiling ;
A suction port that is formed in the main body and into which air is sucked in by the blowing means;
A duct connecting member to which the main body portion is detachably attached and attached to the suction port of the main body portion, and to which a duct member through which air passes is connected;
Shielding means provided on the duct connection member for opening and closing the duct connection member;
Urging means for urging the shielding means to close the duct connecting member;
The shielding means is held in an open state against the urging force of the urging means, and when the temperature of the air sucked into the main body rises to a predetermined temperature, it melts with heat and releases the open state of the shielding means And a thermal fuse that
The thermal fuse is disposed inside the duct connection member in an orientation that is upstream of the main body with respect to the air flow sucked into the main body and on the main body with respect to the shielding means. A blower characterized by. 2. The blower according to claim 1, wherein when the main body is removed from the ceiling, the thermal fuse is exposed inside the duct connecting member connected to the duct member and remaining on the ceiling .

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