JP2008020149A - Air blower - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an air blower capable of reducing noise generated in response to rising of an exhaust pressure loss in a body case. <P>SOLUTION: The air blower 1 has intake means 6, 20 sucking in air by rotating multiblade fans 9, 25, and fan cases 11, 27 forming conduits 12, 28 for guiding the air sucked following rotation of the multiblade fans 9, 25 in fan outlet 11c, 27c directions. In the air blower 1, first stream lining means 15a, 35a for carrying out stream lining of negative pressure air are formed in fan outlet 11c, 27c neighborhoods of the conduits 12, 28, and second stream lining means 15b, 35b for separating a positive pressure portion and a negative pressure portion of the air introduced by the multiblade fans 9, 25 are formed in upstream sides of the conduits 12, 28 with respect to the first stream lining means 15a, 35a. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a suction unit that sucks air by rotating a multiblade fan, and a fan case that forms a conduction path for guiding the air sucked in accordance with the rotation of the multiblade fan toward the fan outlet. It is related with the air blower which has.

  A general bathroom is provided with a blower for ventilating the bathroom. In recent years, there are many bathroom air conditioners that have a bathroom drying function that dries clothing by heating the air in the bathroom, as well as simply ventilating the bathroom.

  In a bathroom air conditioner, a multi-blade fan such as a sirocco fan is often used as a fan for absorbing air in the bathroom. The sirocco fan has a structure in which air is discharged from the center of rotation to the circumferential direction by rotating a disk-shaped fan having a plurality of blades disposed on the peripheral edge.

Since the bathroom air conditioner using a sirocco fan can reduce the thickness (height) of the equipment due to its structure, it is easy to design the apparatus body compactly. For this reason, the air blower using a sirocco fan has a feature that it is easy to install on a bathroom ceiling or the like where installation space is limited (see, for example, Patent Document 1).
JP 2004-340407 A (page 4-6, FIG. 1)

  However, in a blower using a sirocco fan, the air introduced into the main body case may cause air separation or vortices in the main body case, and may generate noise (buzzing sound) when the fan rotates. There was a problem that there was.

  In order to reduce this noise, a method has been proposed in which a rectifying member that rectifies the flow of air to be introduced is installed in the vicinity of the outlet portion of the sirocco fan housing portion in the main body case to prevent air turbulence. However, if the exhaust duct or the intake duct extending from the main body case is long, there is a risk that exhaust pressure loss in the vicinity of the outlet portion becomes high and smooth exhaust may not be performed. There was a problem that there was a risk of doing.

  This invention is made | formed in view of the said problem, and makes it a subject to provide the air blower which can reduce the noise which generate | occur | produces according to the raise of the exhaust pressure loss in a main body case.

  In order to solve the above-described problems, a blower according to the present invention includes a suction unit that sucks air by rotating a multiblade fan, and air sucked in accordance with the rotation of the multiblade fan in a fan outlet direction. And a fan case that forms a conduction path for guiding, a first rectification means for rectifying negative pressure air is formed in the vicinity of the fan outlet of the conduction path, and the guidance to the first rectification means is performed. A second rectifying means for partitioning the positive pressure portion and the negative pressure portion of the air introduced by the multiblade fan is formed on the upstream side of the passage.

  Further, the first rectifying means and the second rectifying means may be formed on at least one of an upper surface or a lower surface of the inner wall of the fan case, and further, the second rectifying means may be provided on the fan case. It may be formed along the side wall.

  Further, the second rectifying means may be formed such that a side surface of the second rectifying means and a side wall portion of the fan case have a predetermined interval or angle.

  The second rectifying means may be formed in a straight line.

  Further, the first rectifying means is formed close to the multi-blade fan, and a front end portion of the first rectifying means is formed at a position deviating from an extending direction of a rear end portion of the second rectifying means. It may be a thing.

  Further, the height of the first rectifying means may be lower than the height of the second rectifying means.

  The blower further includes a suction unit that sucks air by rotating the multiblade fan, and a fan that forms a conduction path for guiding the air sucked in accordance with the rotation of the multiblade fan toward the fan outlet. And a rectifying means for rectifying air flowing through the conduction path is formed on the upper and lower surfaces of the inner wall of the fan case.

  In this blower, the rectifying means may be provided in the vicinity of the fan outlet.

  In the blower according to the present invention, the second rectifying means for partitioning the positive pressure portion and the negative pressure portion of the air introduced by the multiblade fan is formed on the upstream side of the conduction path to the first rectification means. Therefore, it is possible to prevent the airflow flowing through the conduction path from being changed from positive pressure to negative pressure to disturb the airflow. For this reason, it is possible to effectively perform rectification by the second rectification means, and to suppress the generation of noise caused by the turbulence of the airflow in the conduction path.

  In particular, when the length of an exhaust duct or the like connected to the blower becomes long, there is a possibility that exhaust pressure loss in the conduction path becomes high and smooth exhaust may not be performed, resulting in turbulence of the airflow. May cause noise. For this reason, by installing the second rectification means at a position where the airflow changes from positive pressure to negative pressure, it is possible to rectify the conduction path more effectively and suppress the generation of noise. it can.

  In addition, since the first rectifying means and the second rectifying means are formed on at least one of the upper surface or the lower surface of the inner wall of the fan case, not only when it is installed only on one side, but more when it is installed on both sides. Airflow can be effectively rectified, and noise can be suppressed.

  Further, since the second rectifying means has a side surface of the second rectifying means and a side wall portion of the fan case having a predetermined interval or angle, the air rectified by the second rectifying means is The airflow is rectified into an air flow substantially parallel to the side wall surface, or is rectified and discharged in a predetermined angle direction with respect to the side wall surface of the case, so that a high rectification effect can be achieved. In particular, when the second rectifying means is formed in a straight line, a higher rectifying effect can be achieved.

  Further, since the first rectifying means is formed closer to the multi-blade fan, it is possible to suppress the negative pressure from increasing near the multi-blade fan due to the rotation of the multi-blade fan, thereby disturbing the air flow. Can be done effectively.

  Furthermore, since the front end portion of the first rectifying means is formed at a position deviating from the extending direction of the rear end portion of the second rectifying means, the flow of air rectified by the second rectifying means is changed to the first rectifying means. It is possible to induce without inhibiting.

  Further, since the height of the first rectifying means is lower than the height of the second rectifying means, the second rectifying means rectifies the flow of a large air flow upstream of the conduction path, and the first rectifying means near the multiblade fan. Local air turbulence can be effectively rectified.

  Furthermore, when the rectification means for rectifying the air flowing through the conduction path is formed on the upper and lower surfaces of the inner wall of the fan case, the airflow can be rectified more effectively, especially in the conduction path. When the exhaust pressure loss increases and smooth exhaust is not performed, the conduction path is rectified more effectively, and the generation of noise can be suppressed.

  Further, when the rectifying means is provided in the vicinity of the fan outlet, the rectification can be performed more effectively.

  Hereinafter, a bathroom air conditioner provided with a blower according to the present invention will be described in detail with reference to the drawings.

  1 is an exploded perspective view showing a bathroom air conditioner, FIG. 2 shows a cross section AA of the bathroom air conditioner shown in FIG. 1, and FIG. 3 shows a BB of the bathroom air conditioner shown in FIG. A cross section is shown. In FIGS. 2 and 3, for the sake of explanation, a part is shown in a transparent state, and the corresponding part is indicated by a broken line.

  The bathroom air conditioner 1 includes a main body case 2, a ventilation unit 3, a circulation unit 4, and a front panel 5.

  The main body case 2 is a box having a predetermined height, and is made of a nonflammable member, for example, a metal such as iron in consideration of manufacturability and cost. Further, the bottom surface of the main body case 2 is opened, and a flange 2a is formed on the opened lower opening periphery. The front panel 5 can be detachably attached to the flange from below.

  The main body case 2 has a structure in which the ventilation unit 3 and the circulation unit 4 can be attached inside. When the ventilation unit 3 and the circulation unit 4 are installed inside, the ventilation unit 3 is arranged on the upper part. It is installed and the circulation unit 4 is installed thereunder.

  Further, another side exhaust suction port 2c for sucking air in the other room is formed on one side surface of the main body case 2. Further, an exhaust port 2 b for exhausting the air sucked by the ventilation unit 3 to the outside of the bathroom air conditioner 1 is formed on the other side surface of the main body case 2.

  4 shows a side view of the ventilation unit 3 housed in the main body case 2, and FIG. 5 is a bottom view showing the ventilation unit 3 shown in FIG.

  As shown in FIGS. 2 to 6, the ventilation unit 3 includes a ventilation fan unit (suction means) 6, an upper ventilation suction section 7 a, and a circuit board section 8.

  The ventilation fan unit 6 houses a ventilation sirocco fan (multi-blade fan) 9 provided with a large number of blades 9b on the peripheral edge of the main plate 9a, a ventilation fan motor 10 that rotationally drives the ventilation sirocco fan 9, and the ventilation sirocco fan 9. And a ventilation fan case (fan case) 11 to which the ventilation fan motor 10 is attached. The ventilation sirocco fan 9 is located above the ventilation fan motor 10, and the ventilation sirocco fan 9 is fixed to the rotating shaft 10 a of the ventilation fan motor 10 erected upward.

  As shown in FIG. 5, the ventilation fan case 11 includes a cylindrical exhaust guide portion 11 a extending in the direction of the exhaust port 2 b of the main body case 2, and an end portion of the cylindrical case that protrudes laterally. 11b is formed, and a side opening 11c communicating with the exhaust guide portion 11a is constituted by a ventilation fan case main body portion 11d formed in the convex portion 11b. The cylindrical case of the ventilation fan case main body 11 d has a larger diameter than the ventilation sirocco fan 9 in order to accommodate the ventilation sirocco fan 9.

  The ventilation sirocco fan 9 is installed in a state of being eccentric toward the tongue portion 11e in the circular space portion 11f of the ventilation fan case main body portion 11d. In the ventilation fan case 11 in which the ventilation sirocco fan 9 is installed, the side wall opening 11c starts from the vicinity of the tongue-like part 11e and exits (fan outlet) by the inner wall surface of the ventilation fan case body 11d facing the ventilation sirocco fan 9 An annular conduction path 12 is formed. In addition, since the ventilation sirocco fan 9 is installed in a state of being eccentric with respect to the ventilation fan case main body portion 11d, the passage width of the conduction path 12 is gradually widened from the starting point to the side opening 11c.

  Further, as shown in FIGS. 2 and 4, a ventilation fan suction port 11g is formed on the upper surface of the ventilation fan case main body 11d so that the main plate 9a of the ventilation sirocco fan 9 faces the rotation shaft 10a. When the ventilation unit 3 is installed in the main body case 2, a space having a height L is provided between the upper surface of the main body case 2 and the ventilation fan suction port 11g as shown in FIGS. Is secured.

  As shown in FIGS. 5 and 6, the ventilation fan case main body 11d has a first ventilation rectification member (first rectification means) 15a for rectifying air passing through the conduction path 12, and a convex portion 11b. Is provided at a position near the ventilation sirocco fan 9, and further, the passage width of the conduction path 12 is divided upstream of the first ventilation rectifying member 15a. The second ventilation rectification member (second rectification means) 15b is provided. The second ventilation rectification member 15b is formed so that a side surface thereof and a side wall surface of the ventilation fan case main body 11d are kept at a constant interval (predetermined interval). The side wall surface of the case main body 11d is substantially parallel.

  As shown in FIGS. 5 and 6, the horizontal cross-sectional shapes of the first ventilation rectifying member 15 a and the second ventilation rectifying member 15 b are set such that the width of the front end (the upstream end of the conduction path 12) is the rear end (side). The tail end is made thicker than the end opening 11c side and the end is rounded.

  The front end position 13a of the first ventilation rectification member 15a is located at the rear end position 13b of the second ventilation rectification member 15b so that the first ventilation rectification member 15a does not overlap the extending direction of the second ventilation rectification member 15b. The second ventilation rectification member is disposed at a position deviating from the extending direction (a position where the front end position 13a of the first ventilation rectification member 15a is shifted from the rear end position 13b of the second ventilation rectification member 15b). It is considered that the airflow rectified by 15b is not disturbed by the first ventilation rectification member 15a. Moreover, the height of the 1st ventilation rectification member 15a is adjusted so that it may become lower than the height of the 2nd ventilation rectification member 15b.

  One end of the exhaust guide portion 11a is connected to the side opening 11c of the ventilation fan case main body portion 11d, and the other end is connected to the exhaust port 2b of the main body case 2. By connecting the exhaust guide portion 11a in this way, the inside of the ventilation fan case 11 and the exhaust port 2b of the main body case 2 communicate with each other to form the exhaust air passage 17.

  The upper ventilation suction portion 7a is formed of a cylindrical member whose upper surface and lower surface are open, and the above-described height L space between the upper surface of the main body case 2 and the upper end portion of the upper ventilation suction portion 7a. Is secured to the side of the ventilation fan unit 6.

  The circuit board unit 8 is disposed on the side of the ventilation fan unit 6 and in the vicinity of the other-chamber exhaust suction port 2c. A circuit board or the like provided with a control unit 60 for controlling the bathroom air conditioner 1 is housed inside the circuit board unit 8. Further, the other-chamber exhaust suction port 2c communicates with a space having a height L formed between the upper surface of the main body case 2 and the ventilation fan suction port 11g, and this space allows ventilation from the other-chamber exhaust suction port 2c. Another room exhaust suction air passage 18 connected to the fan suction port 11g is formed.

  FIG. 7 shows a side sectional view of the circulation unit 4, and FIG. 8 is a bottom view showing the circulation unit 4 shown in FIG.

  As shown in FIGS. 7 and 8, the ventilation unit 3 includes a circulation fan unit (suction means) 20, a heater 21, a lower ventilation suction portion 7 b, and an electric chamber 22.

  The circulation fan unit 20 houses a circulation sirocco fan (multi-blade fan) 25 in which a large number of blades 25b are provided on the peripheral edge of the main plate 25a, a circulation fan motor 26 that rotationally drives the circulation sirocco fan 25, and the circulation sirocco fan 25. And a circulation fan case (fan case) 27 to which the circulation fan motor 26 is attached. In the circulation fan unit 20, the circulation fan motor 26 is positioned above the circulation sirocco fan 25, and the circulation sirocco fan 25 is fixed to a rotating shaft 26 a of the circulation fan motor 26 that is hanged downward. .

  As shown in FIG. 7, the circulation fan case 27 includes a cylindrical circulation guide portion 27 a extending in the direction of the air outlet 23 formed at the end of the circulation fan unit 20, and the end of the columnar case on the side. A convex portion 27b is formed so as to protrude in the direction, and a side opening 27c communicating with the circulation guide portion 27a is constituted by a circulation fan case main body portion 27d formed in the convex portion 27b. Note that the cylindrical case of the circulation fan case main body 27 d has a diameter larger than that of the circulation sirocco fan 25 in order to accommodate the circulation sirocco fan 25.

  Circulating sirocco fan 25 is installed in a circular space portion 27f of circulating fan case main body portion 27d in an eccentric state toward tongue portion 27e. In the circulation fan case 27 in which the circulation sirocco fan 25 is installed, the tongue portion 27e is the starting point and the side opening 27c is the outlet (fan outlet) by the inner surface of the circulation fan case main body 27d facing the circulation sirocco fan 25. An annular conduction path 28 is formed. Since the circulation sirocco fan 25 is installed in an eccentric state with respect to the circulation fan case main body 27d, the passage width of the conduction path 28 increases from the vicinity of the tongue-shaped part 27e as the starting point to the side opening 27c. It becomes gradually widened.

  Further, as shown in FIG. 7, a circulation suction port 27g is formed on the lower surface of the circulation fan case main body 27d so that the main plate 25a of the circulation sirocco fan 25 faces the rotation shaft 26a.

  As shown in FIGS. 8 and 9, the circulation fan case main body 27d has a first circulation rectification member (first rectification means) 35a for rectifying air passing through the conduction path 28, and a convex portion 27b. The second circulation rectification member is provided at a position near the circulation sirocco fan 25 on the inner wall of the first circulation circulation rectifying member 35a and further at the upstream position of the first circulation rectification member 35a so as to divide the passage width of the conduction path 28. (Second rectification means) 35b is provided. The second circulation rectification member 35b is formed such that the side surface thereof and the side wall surface of the circulation fan case main body portion 27d are kept at a constant distance. The side surface of the second circulation rectification member 35b and the circulation fan case main body portion 27d The side wall surface is substantially parallel.

  As shown in FIGS. 8 and 9, the horizontal cross-sectional shapes of the first circulation rectification member 35 a and the second circulation rectification member 35 b are set such that the width of the front end portion (the upstream end portion of the conduction path 28) is the rear end portion (side portion). The tail is shaped to be thicker than the end 27c of the opening 27c and the end is rounded.

  The first circulation rectification member 35a has a front end portion position 33a of the first circulation rectification member 35a that is not aligned with a rear end portion position 33b of the second circulation rectification member 35b so as not to overlap the extending direction of the second circulation rectification member 35b. The second circulation rectification member is disposed at a position deviating from the extending direction (a position where the front end position 33a of the first circulation rectification member 35a is shifted from the rear end position 33b of the second circulation rectification member 35b). It is considered that the airflow rectified by 35b is not disturbed by the first circulation rectification member 35a. Further, the height of the first circulation rectification member 35a is adjusted to be lower than the height of the second circulation rectification member 35b.

  The circulation guide part 27 a has a structure in which one end is connected to the side opening 27 c of the circulation fan case main body part 27 d and the other end is connected to the outlet 23. The air outlet 23 is formed with the opening directed toward the bathroom. By connecting the circulation guide portion 27a to the side opening 27c and the air outlet 23, the inside of the circulation fan case 27 and the air outlet 23 are connected. A circulation air passage 37 is formed in communication.

  The heater 21 is provided inside the circulation guide portion 27a. For example, a PTC (Positive Temperature Coefficient) heater can be used as the heater 21. The heater 21 is not limited to the PTC heater, and other heating means such as a carbon heater may be used.

  The lower ventilation suction portion 7 b is formed of a cylindrical member whose upper surface and lower surface are open, and is disposed on the side of the circulation fan unit 20. The open part of the lower surface of the lower ventilation suction part 7 b forms a ventilation suction port 36. When the circulation unit 4 is installed on the main body case 2 on which the ventilation unit 3 is installed, the upper surface of the lower ventilation suction portion 7b of the circulation unit 4 and the lower surface of the upper ventilation suction portion 7a of the ventilation unit 3 are connected. It will be in the state. The upper ventilation suction portion 7a and the lower ventilation suction portion 7b are connected and integrated to form a ventilation suction air passage 38 that leads from the ventilation suction port 36 to the ventilation fan suction port 11g.

  Further, a shutter 40 is rotatably provided in the vicinity of the ventilation inlet 36 of the lower ventilation inlet 7b. The shutter shaft 40a of the shutter 40 passes through the wall surface of the lower ventilation suction portion 7b and enters the electric chamber 22 formed in the circulation unit 4. A first drive gear 40c is fixed to an end portion of the shutter shaft 40a that has entered the electric chamber 22, and a rotation shaft 41a of a shutter opening / closing motor 41 such as a stepping motor is further attached to the first drive gear 40c. The second drive gear 40d fixed to the tip of the gear is meshed. Since the first drive gear 40c and the second drive gear 40d are engaged with each other, the shutter shaft 40a rotates according to the drive of the motor 41, and the shutter 40 is opened and closed. The drive control of the motor 41 is performed by the control unit 60 provided on the circuit board unit 8 described above.

  After the ventilation unit 3 and the circulation unit 4 thus configured are installed in the main body case 2, the ventilation fan motor 10 is driven to rotate the ventilation sirocco fan 9, and the motor 41 is further driven to perform ventilation. When the suction port 36 is opened, air outside the bathroom air conditioner 1 is sucked from the ventilation suction port 36 through the ventilation suction air passage 38 as the ventilation sirocco fan 9 rotates. Further, as the ventilation sirocco fan 9 rotates, the air outside the bathroom is sucked in through the other room exhaust suction air passage 18 from the other room exhaust suction port 2c. Air sucked into the ventilation fan unit 6 through the ventilation suction air passage 38 and the other-chamber exhaust suction air passage 18 is formed by the exhaust guide portion 11a and the conduction passage 12 formed in the ventilation fan case main body portion 11d. Then, the air is guided to the exhaust port 2 b through the exhaust air passage 17 and is discharged to the outside of the bathroom air conditioner 1.

  When the circulation fan motor 26 is driven to rotate the circulation sirocco fan 25 and the heater 21 is further operated, the air in the bathroom circulates through the circulation inlet 27g as the circulation sirocco fan 25 rotates. Inhaled into the fan unit 20. The air sucked into the circulation fan unit 20 is guided to the air outlet 23 through the conduction path 12 formed in the circulation fan case main body 27d and the circulation air path 37 formed by the circulation guide part 27a. At this time, since the air passing through the circulation guide portion 27a is warmed by the heater 21, the air that has been heated by the heater 21 is circulated in the bathroom.

  As shown in FIG. 1, the front panel 5 has a ventilation inlet 5a formed so as to correspond to the installation position of the ventilation inlet 36 of the lower ventilation inlet 7b. The circulation inlet 5b is formed so as to correspond to the installation position of the circulation inlet 27g of the unit 20. Further, the front panel 5 is formed with an outlet 5c so as to correspond to the installation position of the outlet 23 of the circulation unit 4.

  Next, the case where the bathroom air conditioner 1 which concerns on this embodiment is installed in a bathroom is demonstrated. FIG. 10 shows a state in which the bathroom air conditioner 1 is installed in the bathroom 43 adjacent to the washroom 42.

  In the ceiling panel 43a of the bathroom 43, an opening that can store the main body case 2 of the bathroom air conditioner 1 is formed. By storing the main body case 2 of the bathroom air conditioner 1 in the back of the ceiling from this opening, The bathroom air conditioner 1 is installed in the bathroom 43. The main body case 2 is installed so as to be suspended from the back of the ceiling or fixed to the ceiling panel 43 a, and the front front panel 5 is exposed to the bathroom 43 with respect to the lower surface of the fixed main body case 2. To be attached.

  A first other-room exhaust duct 46 a having one end installed in a connection unit 57 installed in the washroom 42 is connected to the other-room exhaust suction port 2 c of the bathroom air-conditioning apparatus 1 through an other-room exhaust duct connection portion 47. ing. An opening (not shown) communicating with the first exhaust duct 50 is formed on the lower surface of the connecting unit 57, and the washroom exhaust inlet 45 of the bathroom 43 and the first other-chamber exhaust duct 46a are formed through this opening. Will be in a state of communication. Further, the connection unit 57 is provided with a second other-chamber exhaust duct 46 b having one end connected to the toilet exhaust suction port 58 of the toilet 56, and the first other-chamber exhaust duct 46 a and the second exhaust duct 46 a are connected via the connection unit 57. The other-chamber exhaust duct 46b is connected.

  Furthermore, an exhaust duct 50 having one end connected to an exhaust grille 49 installed on the outer wall of the building is connected to an exhaust port 2 b of the bathroom air conditioner 1 via an exhaust duct connection portion 51. Since the living room 59 is provided between the bathroom 43 and the outer wall of the building as shown in FIG. 10, the exhaust duct 50 is installed so as to cross the ceiling of the living room 59.

  In the present embodiment, the first other-room exhaust duct 46a to which the second other-room exhaust duct 46b is connected is connected to the bathroom air conditioner 1 by the connecting unit 57, and the bathroom 42 and the toilet 56 are connected. The air is sucked in through the other-chamber exhaust suction port 2c, and the sucked air is exhausted outside the building through the exhaust duct 50 from the exhaust port 2b. However, the bathroom air conditioner 1 has two other-chamber exhaust suction ports 2c. It is good also as a structure which connects the 1st other chamber exhaust duct 46a to one other chamber exhaust suction port 2c, and connects the 2nd other chamber exhaust duct 46b to the other chamber exhaust suction port 2c.

  Further, the bathroom air conditioner 1 is provided with only one other room exhaust suction port 2c, and only one air of the washroom 42 or the toilet 56 is sucked through the other room exhaust suction port 2c, and the sucked air is exhausted. It is good also as a structure which exhausts out of a building via 2b, Furthermore, it is good also as a structure which provides the several other room exhaust inlet 2c in the bathroom air conditioner 1, and inhales the air of several other rooms. Moreover, it is good also as a structure which does not perform the suction of the air from another room, without providing the other room exhaust air inlet 2c in the bathroom air conditioner 1. FIG.

  In the bathroom 43, a land pipe 52 for suspending laundry can be installed. By applying the warm air heated by the heater 21 of the bathroom air conditioner 1 to the laundry or the like hung on the land pipe 52, the laundry can be quickly dried.

  In addition, a bathroom door 53 is provided at the entrance of the bathroom 43, and an air intake 53 a (louver) 53 a is formed in the lower part of the bathroom door 53. When the air in the bathroom 43 is sucked by the bathroom air conditioner 1, the air in the bathroom 42 is guided into the bathroom 43 through the air intake 53a as the air in the bathroom 43 is sucked. .

  Furthermore, an operation panel 55 for operating the bathroom air conditioner 1 is provided on the wall surface of the washroom 42. FIG. 11A shows an example of the operation panel 55. The operation panel 55 selects a display unit 55a, a heating mode button 55b for selecting a heating operation mode, a cool air mode button 55c for selecting a cool air operation mode, a ventilation mode button 55d for selecting a ventilation operation mode, and a drying operation mode. A drying mode button 55e is provided. Further, for example, a lamp 55f is provided corresponding to each of the buttons 55b to 55d so that the user can confirm the selected operation mode, and the lamp 55f is provided corresponding to the buttons 55b to 55d of the selected operation mode. It comes to light up. Further, a timer button 55g may be provided so that a desired operation mode can be started or ended at a set time.

  Moreover, when any operation mode is not selected by the operation buttons 55b to 55d provided on the operation panel 55, the bathroom air conditioner 1 operates in the 24-hour ventilation operation mode. In a given building, it is obliged to perform ventilation for 24 hours. In the 24-hour ventilation, it is necessary to ventilate the entire house or the volume of a predetermined area of the house by a predetermined number of ventilations (for example, 0.5 times / hour). For this reason, generally, the bathroom air conditioner 1 is provided with a 24-hour ventilation operation mode to ventilate the building.

  When the user operates the operation panel 55 and selects the operation mode of the bathroom air conditioner 1, the selected information is stored in the circuit board unit 8 as shown in FIG. Is transmitted to. The control unit 60 includes a CPU (Central Processing Unit), a memory, and the like. Under the control of the control unit 60, the heater 21, the ventilation fan motor 10, the circulation fan motor 26, and the motor 41 for the shutter 40 are provided. The drive control is performed. The control unit 41 performs control according to the heating operation mode, ventilation operation mode, cool air operation mode, and drying operation mode selected by the user in accordance with a program stored in a memory or the like (not shown). This is executed for the circulation fan motor 26 and the motor 41.

  Next, operation | movement of the bathroom air conditioner 1 performed corresponding to the operation mode mentioned above is demonstrated.

<Ventilation mode / 24-hour mode>
12 (a) and 12 (b) are diagrams showing the operating state of the bathroom air conditioner 1 in the ventilation operation mode and the air flow represented by arrows. When the user presses the ventilation mode button 55d on the operation panel 55 to select the ventilation operation mode, the control unit 60 executes a control operation in the ventilation operation mode.

  Specifically, the control unit 60 stops the circulation fan motor 26 to stop the rotation of the circulation sirocco fan 25 and stops the heater 21. Further, the control unit 60 drives the ventilation fan motor 10 to rotate the ventilation sirocco fan 9, and also drives the motor 41 for the shutter 40 to rotate the shutter 40, thereby ventilating the lower ventilation suction unit 7b. The suction port 36 is opened.

  When the ventilation sirocco fan 9 is rotated and the ventilation inlet 36 is opened, as shown in FIGS. 12 (a) and 12 (b), the ventilation inlet is provided via the ventilation inlet 5a of the front panel 5. The air in the bathroom 43 is sucked from 36. The air sucked from the ventilation suction port 36 passes through the ventilation suction air passage 38 and is sucked into the ventilation fan case 11 by the ventilation sirocco fan 9.

  At the same time, by the rotation of the ventilation sirocco fan 9, the air in the washroom 42 is led to the other-chamber exhaust suction port 2c via the other-chamber exhaust duct 46, and the air led to the other-chamber exhaust suction port 2c is Then, the air is sucked into the ventilation fan case 11 through the other-room exhaust suction air passage 18.

  The air sucked into the ventilation fan case 11 is guided through the conduction path 12 formed in the ventilation fan case 11 toward the side opening 11c serving as the outlet of the conduction path 12. The airflow passing through the conduction path 12 in the direction of the side opening 11c increases the width of the passage from around the convex portion 11b, so that the wind speed increases.

  FIG. 13 is a diagram showing a positive pressure / negative pressure distribution in the conduction path 12. As shown in the figure, the airflow on the peripheral side of the inner wall of the conduction path 12 on the upstream side of the conduction path 12 tends to be positive, while the convex portion 11b located on the downstream side of the conduction path 12 There is a tendency for the airflow to become negative pressure in the portion near the ventilation sirocco fan 9. The air sucked into the ventilation fan case 11 as the ventilation sirocco fan 9 rotates causes the airflow to change from a positive pressure to a negative pressure, so that the airflow is likely to be disturbed.

  Here, as shown in FIGS. 5 and 13, the second ventilation rectification member 15b is installed at the boundary portion of the conduction path 12 where the airflow changes from positive pressure to negative pressure, and the second ventilation rectification member 15b. Can be prevented from changing the air flowing through the conduction path 12 from the positive pressure to the negative pressure and disturbing the airflow, and the rectified airflow can be guided to the side opening 11c. It becomes.

  In particular, as shown in FIG. 10, when the lengths of the first other-chamber exhaust duct 46a, the second other-chamber exhaust duct 46b, the exhaust duct 50, etc. are increased, the exhaust pressure loss in the conduction path 12 is increased. There is a possibility that smooth exhaust may not be performed, and as a result, air currents may be disturbed and noise may be generated. For this reason, by installing the second ventilation rectification member 15b at a position where the airflow changes from positive pressure to negative pressure, the conduction path 12 can be rectified more effectively, and noise generation is suppressed. can do.

  Further, since the second ventilation rectification member 15b is installed substantially parallel to the side wall surface of the ventilation fan case main body 11d, the air rectified by the second ventilation rectification member 15b is on the side of the ventilation fan case main body 11d. The air is rectified into an airflow parallel to the wall surface and guided to the side opening 11c.

  In addition, since the side wall surface of the ventilation fan case main body 11d is linear in a plan view and the second ventilation rectification member 15b is also formed in a straight line, a high rectification effect can be achieved. . In the present embodiment, the second ventilation rectification member 15b is configured to maintain a predetermined interval with respect to the side wall surface of the ventilation fan case main body 11d. However, the second ventilation rectification member 15b is configured to maintain the ventilation fan case main body 11d. You may have a predetermined angle with respect to a side wall surface. When the second ventilation rectifying member 15b is formed with a predetermined angle, air is rectified in a predetermined angular direction with respect to the side wall surface of the ventilation fan case main body 11d and discharged. Similarly, it is possible to obtain a high rectifying effect.

  Since the second ventilation rectifying member 15b may be configured to maintain a predetermined interval with respect to the side wall surface of the ventilation fan case main body portion 11d, the side wall surface of the ventilation fan case main body portion 11d is curved and is seen in a plan view. The second ventilation rectification member 15b is also formed in a curved shape. Similarly, when formed in a curved surface, the air rectified by the second ventilation rectification member 15b is rectified into an air flow parallel to the side wall surface of the ventilation fan case main body 11d and led to the side opening 11c. Therefore, a high rectifying effect can be obtained.

  Further, since the first ventilation rectifying member 15a is provided on the lower surface of the inner wall of the convex portion 11b and near the ventilation sirocco fan 9, the first ventilation rectifying member 15a was blown into the convex portion 11b by the rotation of the ventilation sirocco fan 9. The first ventilation rectification member 15a can suppress the air from increasing the negative pressure in the vicinity of the convex portion 11b and causing the turbulence of the airflow, and the rectification in the convex portion 11b can be effectively performed. Can do.

  In particular, when the ventilation sirocco fan 9 rotates, the air sucked from the ventilation fan suction port 11g of the ventilation fan case body 11d is blown toward the lower surface of the conduction path 12, so that the vicinity of the lower surface of the convex portion 11b. Tends to be negative pressure. Since the first ventilation rectification member 15a is provided on the lower surface of the inner wall of the convex portion 11b that is likely to be negative pressure, the first ventilation rectifying member 15a is in the vicinity of the lower surface of the convex portion 11b that is liable to be disturbed. Can be positively rectified, and the generation of noise in the convex portion 11b can be effectively reduced.

  Further, since the first ventilation rectification member 15a is disposed so as not to overlap the extending direction of the second ventilation rectification member 15b, the flow of air rectified by the second ventilation rectification member 15b is changed to the first ventilation rectification member 15b. It becomes possible to guide to the side opening 11c without being obstructed by the ventilation rectification member 15a.

  Furthermore, since the height of the first ventilation rectification member 15a is adjusted to be lower than the height of the second ventilation rectification member 15b, the flow of a large air flow upstream of the conduction path 12 by the second ventilation rectification member 15b. The first ventilation rectification member 15a can effectively rectify the local turbulence blown out toward the lower surface of the conduction path 12 in the vicinity of the ventilation sirocco fan 9 of the convex portion 11b. it can.

  Moreover, since the cross-sectional shape of the 1st ventilation rectification member 15a and the 2nd ventilation rectification member 15b is comprised by the tail shape, it reduces the air resistance of the airflow with respect to the 1st ventilation rectification member 15a and the 2nd ventilation rectification member 15b. Thus, noise such as wind noise can be reduced.

  In this way, the air flowing through the conduction path 12 is guided to the exhaust guide 11a through the side opening 11c while being rectified by the first ventilation rectification member 15a and the second ventilation rectification member 15b. Thereafter, the air flows from the exhaust air passage 17 formed by the exhaust guide portion 11a through the exhaust port 2b to the exhaust duct 37 and is exhausted to the outside through the exhaust grille 38.

  Since the air in the bathroom 43 is exhausted to the outside by the suction of the air in the bathroom 43 by the ventilation fan unit 6, the air in the washroom 42 is sucked from the air intake port 53 a provided in the bathroom door 53. . In this way, by operating the bathroom air conditioner 1 in the ventilation operation mode, steam and moisture in the bathroom 43 can be actively exhausted to the outside, so that condensation in the bathroom 43 can be suppressed, It becomes possible to suppress the occurrence of mold.

  Also, when the bathroom air conditioner 1 is operated in the 24-hour operation mode, the control unit 60 stops the circulation fan motor 26 and assists with the tilting plate member 30a as in the above-described operation in the ventilation operation mode. The opening 30 is closed, and the ventilation fan motor is driven and the shutter 40 is rotated to open the ventilation inlet 36.

  Thus, when the control part 60 starts the operation | movement of 24 hours ventilation operation mode, air will flow like the ventilation operation mode mentioned above, and it becomes possible to ventilate a building. Even when ventilation is performed for 24 hours in this way, the air flow in the exhaust fan case main body 11 can be rectified by the first ventilation rectification member 15a and the second ventilation rectification member 15b. Noise generation can be suppressed.

  In the 24-hour ventilation operation mode, normally, the ventilation fan motor 10 of the ventilation fan unit 6 is continuously operated so that the ventilation is always performed. As long as ventilation can be realized, the ventilation fan unit 6 may be operated intermittently to the extent that this requirement is satisfied.

  In addition, since the 24-hour ventilation is not necessarily intended to ventilate only the bathroom 43, for example, when the bathroom air conditioner 1 is operated in the 24-hour ventilation mode, the rotation angle of the shutter 40 is reduced for ventilation. The opening amount of the suction port 36 may be reduced. In this way, by reducing the opening amount of the ventilation inlet 36, the air is sucked from the other room through the first other room exhaust duct 46a and the second other room exhaust duct 46b than the air volume sucked from the bathroom 43. Since the amount of air flow increases, the ventilation efficiency of the entire building can be improved.

  Further, when the operation is performed in the 24-hour ventilation mode, the rotation time of the ventilation sirocco fan 9 of the ventilation fan unit 6 tends to become longer regardless of day and night, so that noise is reduced by reducing the rotation speed of the ventilation sirocco fan 9. It is also possible to suppress the occurrence of.

  Furthermore, when the bathroom air-conditioning apparatus 1 is provided with a plurality of other-chamber exhaust suction ports 2c, an electric shutter or the like is provided in the other-chamber exhaust duct connection portion 47 or the like so as to change the opening degree of the shutter. It may be. Thus, by changing the opening degree of the shutter, the amount of air sucked from other rooms can be adjusted, and the amount of air ventilated in the entire house can be kept at a predetermined amount.

<About heating mode>
14 (a) and 14 (b) are diagrams showing the operating state of the bathroom air conditioner 1 in the heating operation mode and the air flow represented by arrows. When the heating mode button 55b is pressed by the user on the operation panel 55 and the heating operation mode is selected, the control unit 60 executes a control operation in the heating operation mode.

  Specifically, the control unit 60 stops the ventilation fan motor 10 to stop the rotation of the ventilation sirocco fan 9. Further, the control unit 60 drives the motor 41 for the shutter 40 to rotate the shutter 40 and closes the ventilation suction port 36 of the lower ventilation suction unit 7b. Further, the control unit 60 drives the circulation fan motor 26 to rotate the circulation sirocco fan 25 and energizes the heater 21.

  When the circulation sirocco fan 25 rotates, the air in the bathroom 43 is sucked from the circulation suction port 27g through the circulation suction port 5b of the front panel 5, as shown in FIGS. Air sucked from the circulation suction port 27 g is sucked into the circulation fan case 27 by the circulation sirocco fan 25.

  The air sucked into the circulation fan case 27 is guided through the conduction path 28 formed in the circulation fan case 27 toward the side opening 27 c serving as the outlet of the conduction path 28. Since the airflow passing through the conduction path 28 in the direction of the side opening 27c increases the width of the passage from around the convex portion 27b, the exhaust pressure loss decreases and the wind speed increases.

  Here, like the second ventilation rectification member 15b, the second circulation rectification member 35b is installed at the boundary portion of the conduction path 28 where the airflow changes from positive pressure to negative pressure, and the second circulation rectification member 35b. Can be prevented from changing the air flowing through the conduction path 28 from the positive pressure to the negative pressure and disturbing the airflow, and the rectified airflow can be guided to the side opening 27c. It becomes.

  Further, since the second circulation rectification member 35b is installed substantially parallel to the side wall surface of the circulation fan case main body 27d, the air rectified by the second circulation rectification member 35b is on the side of the circulation fan case main body 27d. The air is rectified into an airflow parallel to the wall surface and guided to the side opening 27c.

  Note that the side wall surface of the circulation fan case main body 27d is linear in a plan view, and the second circulation rectification member 35b is similarly formed in a straight line, so that a high rectification effect can be achieved. . Further, in the present embodiment, the second circulation rectification member 35b is configured to maintain a predetermined interval with respect to the side wall surface of the circulation fan case main body portion 27d. However, the second circulation rectification member 35b is configured to maintain the circulation fan case main body portion 27d. You may have a predetermined angle with respect to a side wall surface. When the second circulation rectification member 35b is formed with a predetermined angle, air is rectified in a predetermined angle direction with respect to the side wall surface of the circulation fan case main body portion 27d and discharged. Similarly, it is possible to obtain a high rectifying effect.

  Note that the second circulation rectifying member 35b may be configured to maintain a predetermined interval with respect to the side wall surface of the circulation fan case main body portion 27d. Therefore, the side wall surface of the circulation fan case main body portion 27d has a curved surface and is seen in a plan view. The second circulation rectifying member 35b is also formed in a curved shape. Similarly, when formed in a curved surface, the air rectified by the second circulation rectifying member 35b is rectified into an air flow parallel to the side wall surface of the circulation fan case main body 27d and guided to the side opening 27c. Therefore, a high rectifying effect can be obtained.

  Further, since the first circulation rectifying member 35a is provided on the inner wall upper surface of the convex portion 27b and near the circulation sirocco fan 27, the air blown into the convex portion 27b by the rotation of the circulation sirocco fan 27 However, increasing the negative pressure in the vicinity of the convex portion 27b and causing turbulence of the airflow can be suppressed by the first circulation rectifying member 35a, and the rectification in the convex portion 27b can be effectively performed. Can do.

  In particular, when the circulation sirocco fan 27 rotates, air sucked from the circulation suction port 27g of the circulation fan case main body 27d is blown toward the upper surface of the conduction path 28, so that the vicinity of the upper surface of the convex portion 27b. Tends to be negative pressure. Since the first circulation rectifying member 35a is provided on the upper surface of the inner wall of the convex portion 11b that is likely to be negative pressure, the first air circulation member 35a is in the vicinity of the upper surface of the convex portion 27b that is liable to be disturbed. Can be positively rectified, and the generation of noise in the convex portion 27b can be effectively reduced.

  Further, since the first circulation rectification member 35a is disposed so as not to overlap the extending direction of the second circulation rectification member 35b, the flow of air rectified by the second circulation rectification member 35b is changed to the first circulation rectification member 35b. It becomes possible to guide to the side opening 27c without being obstructed by the circulation rectifying member 35a.

  Further, since the height of the first circulation rectification member 35a is adjusted to be lower than the height of the second circulation rectification member 35b, the flow of a large air flow upstream of the conduction path 28 by the second circulation rectification member 35b. The first circulation rectification member 35a can effectively rectify local turbulence blown out toward the upper surface of the conduction path 28 in the vicinity of the circulation sirocco fan 27 of the convex portion 27b. it can.

  Moreover, since the cross-sectional shape of the 1st circulation rectification member 35a and the 2nd circulation rectification member 35b is comprised by the tail shape, the air resistance of the airflow with respect to the 1st circulation rectification member 35a and the 2nd circulation rectification member 35b is reduced. Thus, noise such as wind noise can be reduced.

  In this way, the air flowing through the conduction path 28 is guided to the circulation guide portion 27a through the side opening 27c while being rectified by the first circulation rectification member 35a and the second circulation rectification member 35b. Thereafter, the air guided to the circulation guide portion 27a is heated by the heater 21 provided in the circulation guide portion 27a, and then blown into the bathroom 43 through the outlet 23 and the outlet 5c of the front panel 5. The

  Thus, by operating the bathroom air conditioner 1 in the heating operation mode, it is possible to heat the bathroom 43 while circulating the air in the bathroom 43 and to raise the temperature in the bathroom. By operating the bathroom air conditioner 1 in the heating operation mode, the inside of the bathroom 43 can be warmed in advance (so-called preheating), so that the user can comfortably bathe without feeling cold at the start of bathing. It becomes possible. Also, by warming the bathroom 43 by reducing the amount of warm air blown into the bathroom 43 during bathing (so-called bath heating), the user can feel comfortable even when washing the body in the washroom 43b. You can take a bath.

  In the above-described embodiment, the ventilation fan motor 10 is stopped and the ventilation sirocco fan 9 is not rotated. However, in order to exhaust air sucked from other rooms such as the washroom 42, the shutter 40 is used for ventilation suction. The ventilation sirocco fan 9 may be rotated while the mouth 36 is closed. By rotating the ventilation sirocco fan 9 with the ventilation inlet 36 closed, the warmed air in the bathroom 43 becomes difficult to be sucked in by the ventilation fan unit 6, so that the warm air escapes outside the bathroom 43. Can be prevented.

<Dry mode and cool breeze mode>
FIGS. 15A and 15B are diagrams showing the operating state of the bathroom air conditioner 1 in the dry operation mode and the flow of air represented by arrows. When the user presses the drying mode button 42d on the operation panel 55 to select the drying operation mode, the control unit 60 executes the control operation in the drying operation mode.

  Specifically, the control unit 60 drives the ventilation fan motor 10 to rotate the ventilation sirocco fan 9. Further, the control unit 60 drives the shutter motor 41 to rotate the shutter 40 to open the ventilation suction port 36 of the lower ventilation suction unit 7b. Further, the control unit 60 drives the circulation fan motor 26 to rotate the circulation sirocco fan 25 and energizes the heater 21.

  When the ventilation sirocco fan 9 rotates and the ventilation inlet 36 is opened, as shown in FIGS. 15 (a) and 15 (b), the ventilation inlet is provided via the ventilation inlet 5a of the front panel 5. The air in the bathroom 43 is sucked from 36. The air sucked from the ventilation suction port 36 passes through the ventilation suction air passage 38 and is sucked into the ventilation fan case 11 by the ventilation sirocco fan 9.

  At the same time, by the rotation of the ventilation sirocco fan 9, the air in the washroom 42 is led to the other-chamber exhaust suction port 2c via the other-chamber exhaust duct 46, and the air led to the other-chamber exhaust suction port 2c is The air is sucked into the ventilation fan case 11 through the other room exhaust suction air passage 18.

  The air sucked into the ventilation fan case 11 is guided through the conduction path 12 formed in the ventilation fan case 11 toward the side opening 11c serving as the outlet of the conduction path 12. Since the flow width of the airflow flowing in the direction of the side opening 11c through the conduction path 12 increases from the vicinity of the convex portion 11b, the exhaust pressure loss decreases and the wind speed increases.

  Here, as shown in FIGS. 5 and 13, the second ventilation rectification member 15b is installed at the boundary portion of the conduction path 12 where the airflow changes from positive pressure to negative pressure, and the second ventilation rectification member 15b. Can be prevented from changing the air flowing through the conduction path 12 from the positive pressure to the negative pressure and disturbing the airflow, and the rectified airflow can be guided to the side opening 11c. It becomes.

  In particular, as shown in FIG. 10, when the lengths of the first other-chamber exhaust duct 46a, the second other-chamber exhaust duct 46b, the exhaust duct 50, etc. are increased, the exhaust pressure loss in the conduction path 12 is increased. There is a possibility that smooth exhaust may not be performed, and as a result, air currents may be disturbed and noise may be generated. For this reason, by installing the second ventilation rectification member 15b at a position where the airflow changes from positive pressure to negative pressure, the conduction path 12 can be rectified more effectively, and noise generation is suppressed. can do.

  Further, since the second ventilation rectification member 15b is installed substantially parallel to the side wall surface of the ventilation fan case main body 11d, the air rectified by the second ventilation rectification member 15b is on the side of the ventilation fan case main body 11d. The air is rectified into an airflow parallel to the wall surface and guided to the side opening 11c.

  Further, since the first ventilation rectifying member 15a is provided on the lower surface of the inner wall of the convex portion 11b and near the ventilation sirocco fan 9, the first ventilation rectifying member 15a was blown into the convex portion 11b by the rotation of the ventilation sirocco fan 9. The first ventilation rectification member 15a can suppress the air from increasing the negative pressure in the vicinity of the convex portion 11b and causing the turbulence of the airflow, and the rectification in the convex portion 11b can be effectively performed. Can do.

  In particular, when the ventilation sirocco fan 9 rotates, the air sucked from the ventilation fan suction port 11g of the ventilation fan case body 11d is blown toward the lower surface of the conduction path 12, so that the vicinity of the lower surface of the convex portion 11b. Tends to be negative pressure. Since the first ventilation rectification member 15a is provided on the lower surface of the inner wall of the convex portion 11b that is likely to be negative pressure, the first ventilation rectifying member 15a is in the vicinity of the lower surface of the convex portion 11b that is liable to be disturbed. Can be positively rectified, and the generation of noise in the convex portion 11b can be effectively reduced.

  Further, since the first ventilation rectification member 15a is disposed so as not to overlap the extending direction of the second ventilation rectification member 15b, the flow of air rectified by the second ventilation rectification member 15b is changed to the first ventilation rectification member 15b. It becomes possible to guide to the side opening 11c without being obstructed by the ventilation rectification member 15a.

  Furthermore, since the height of the first ventilation rectification member 15a is adjusted to be lower than the height of the second ventilation rectification member 15b, the flow of a large air flow upstream of the conduction path 12 by the second ventilation rectification member 15b. The first ventilation rectification member 15a can effectively rectify the local turbulence blown out toward the lower surface of the conduction path 12 in the vicinity of the ventilation sirocco fan 9 of the convex portion 11b. it can.

  Moreover, since the cross-sectional shape of the 1st ventilation rectification member 15a and the 2nd rectification | straightening board 5b is comprised by the tail shape, it can reduce the air resistance of the airflow with respect to the 1st ventilation rectification member 15a and the 2nd ventilation rectification member 15b. It is possible to reduce noise such as wind noise.

  In this way, the air flowing through the conduction path 12 is guided to the exhaust guide 11a through the side opening 11c while being rectified by the first ventilation rectification member 15a and the second ventilation rectification member 15b. Thereafter, the air flows from the exhaust air passage 17 formed by the exhaust guide portion 11 a through the exhaust port 2 b to the exhaust duct 50 and is exhausted to the outside through the exhaust grille 49.

  On the other hand, when the circulation sirocco fan 25 rotates, the air in the bathroom 43 is sucked from the circulation inlet 27g through the circulation inlet 5b of the front panel 5 as shown in FIGS. 15 (a) and 15 (b). Be turned. Air sucked from the circulation suction port 27 g is sucked into the circulation fan case 27 by the circulation sirocco fan 25.

  The air sucked into the circulation fan case 27 is guided through the conduction path 28 formed in the circulation fan case 27 toward the side opening 27 c serving as the outlet of the conduction path 28. The airflow passing through the conduction path 28 in the direction of the side opening 27c increases the width of the passage from the vicinity of the convex portion 27b, so that the exhaust pressure loss is reduced and the wind speed is increased.

  Here, like the second ventilation rectification member 15b, the second circulation rectification member 35b is installed at the boundary portion of the conduction path 28 where the airflow changes from positive pressure to negative pressure, and the second circulation rectification member 35b. Can be prevented from changing the air flowing through the conduction path 28 from the positive pressure to the negative pressure and disturbing the airflow, and the rectified airflow can be guided to the side opening 27c. It becomes.

  Further, since the second circulation rectification member 35b is installed substantially parallel to the side wall surface of the circulation fan case main body 27d, the air rectified by the second circulation rectification member 35b is on the side of the circulation fan case main body 27d. The air is rectified into an airflow parallel to the wall surface and guided to the side opening 27c.

  Further, since the first circulation rectifying member 35a is provided on the inner wall upper surface of the convex portion 27b and near the circulation sirocco fan 27, the air blown into the convex portion 27b by the rotation of the circulation sirocco fan 27 However, the first circulation rectification member 35a can prevent the turbulence of the air flow by increasing the negative pressure in the vicinity of the convex portion 27b, and the rectification in the convex portion 27b can be effectively performed. it can.

  In particular, when the circulation sirocco fan 27 rotates, air sucked from the circulation suction port 27g of the circulation fan case main body 27d is blown toward the upper surface of the conduction path 28, so that the vicinity of the upper surface of the convex portion 27b. Tends to be negative pressure. Since the first circulation rectifying member 35a is provided on the upper surface of the inner wall of the convex portion 27b that is likely to be negative pressure, the first air circulation member 35a is in the vicinity of the upper surface of the convex portion 27b that is liable to be disturbed. Can be positively rectified, and the generation of noise in the convex portion 27b can be effectively reduced.

  Further, since the first circulation rectification member 35a is disposed so as not to overlap the extending direction of the second circulation rectification member 35b, the flow of air rectified by the second circulation rectification member 35b is changed to the first circulation rectification member 35b. It becomes possible to guide to the side opening 27c without being obstructed by the circulation rectifying member 35a.

  Further, since the height of the first circulation rectification member 35a is adjusted to be lower than the height of the second circulation rectification member 35b, the flow of a large air flow upstream of the conduction path 28 by the second circulation rectification member 35b. The first circulation rectification member 35a can effectively rectify local turbulence blown out toward the upper surface of the conduction path 28 in the vicinity of the circulation sirocco fan 27 of the convex portion 27b. it can.

  Moreover, since the cross-sectional shape of the 1st circulation rectification member 35a and the 2nd circulation rectification member 35b is comprised by the tail shape, the air resistance of the airflow with respect to the 1st circulation rectification member 35a and the 2nd circulation rectification member 35b is reduced. Thus, noise such as wind noise can be reduced.

  In this way, the air flowing through the conduction path 28 is guided to the circulation guide portion 27a through the side opening 27c while being rectified by the first circulation rectification member 35a and the second circulation rectification member 35b. Thereafter, the air guided to the circulation guide portion 27a is heated by the heater 21 provided in the circulation guide portion 27a, and then blown into the bathroom 43 through the outlet 23 and the outlet 5c of the front panel 5. The

  In this way, by operating the bathroom air conditioner 1 in the dry mode, the inside of the bathroom 43 can be warmed by the circulation unit 4 while the air in the bathroom 43 is discharged to the outdoors by the ventilation unit 3. The clothes hung on the land re-pipe 52 can be dried. Further, a part of the air in the bathroom 43 is exhausted to the outside, and ventilation in the bathroom 43 is performed by taking in the air in the washroom 42 and the like from the air intake port 53a. Drying of can be promoted.

  When the cool wind mode button 55c of the operation panel 55 is pressed by the user and the cool wind operation mode is selected, the control unit 60 performs the same control operation as the above-described dry operation mode except that the heater 21 is stopped. Execute. For this reason, even when the bathroom air conditioner 1 is operated in the cool air operation mode, the first ventilation rectification member 15a, the second ventilation rectification member 15b, and the first circulation are the same as the operation in the dry operation mode described above. Since the airflow can be rectified by the rectifying member 35a and the second circulation rectifying member 35b, the generation of noise in the ventilation fan unit 6 and the circulation fan unit 20 can be suppressed.

  Moreover, by operating the bathroom air conditioner 1 in the cool air operation mode, the air in the bathroom 32 is exhausted, and the cool air is blown out according to the temperature in the bathroom 32 while circulating the air in the bathroom 32. Therefore, the bathroom air conditioner 1 can be used as a fan in the summer.

  As described above, in the bathroom air conditioner 1 provided with the air blower according to the present invention, the second ventilation rectification member 15b and the second circulation rectification member 35b have the conduction path 12 in which the airflow changes from positive pressure to negative pressure. , 28 can prevent the airflow flowing through the conduction paths 12 and 28 from changing from positive pressure to negative pressure and disturbing the airflow. For this reason, it is possible to effectively perform rectification by the second ventilation rectification member 15b and the second circulation rectification member 35b, and it is possible to suppress the generation of noise caused by the turbulence of the air flow in the conduction paths 12 and 28.

  Further, the second ventilation rectification member 15b is formed such that the side surface thereof and the side wall surface of the ventilation fan case main body portion 11d are kept at a predetermined (predetermined) distance, and the side surface of the second ventilation rectification member 15b and the ventilation fan are formed. The side wall surface of the case main body portion 11d is installed substantially in parallel, and the second circulation rectifying member 35b is formed such that the side surface thereof and the side wall surface of the circulation fan case main body portion 27d maintain a constant (predetermined) distance. Since the side surface of the second circulation rectification member 35b and the side wall surface of the circulation fan case main body 27d are installed substantially in parallel, the air rectified by the second ventilation rectification member 15b and the second circulation rectification member 35b is Then, the air is rectified into an airflow substantially parallel to the side wall surface of the fan case main body and guided to the side openings 11c and 27c.

  In particular, as shown in FIG. 10, when the lengths of the first other-chamber exhaust duct 46a, the second other-chamber exhaust duct 46b, the exhaust duct 50, etc. are increased, the exhaust pressure loss in the conduction path 12 is increased. There is a possibility that smooth exhaust may not be performed, and as a result, air currents may be disturbed and noise may be generated. For this reason, by installing the second ventilation rectification member 15b at a position where the airflow changes from positive pressure to negative pressure, the conduction path 12 can be rectified more effectively, and noise generation is suppressed. can do.

  Further, the first ventilation rectification member 15a is provided on the lower surface of the inner wall of the convex portion 11b and closer to the ventilation sirocco fan 9, and the first circulation rectification member 35a is the upper surface of the inner wall of the convex portion 27b and has a circulation sirocco. Since it is provided at a position close to the fan 27, the first ventilation rectifying member that the negative pressure increases near the convex portions 11b and 27b and the air flow is disturbed by the rotation of the ventilation sirocco fan 9 and the circulation sirocco fan. 15a and the first circulation rectification member 35a can suppress the rectification in the convex portions 11b and 27b effectively.

  In particular, when the ventilation sirocco fan 9 rotates, the air sucked from the ventilation fan suction port 11g of the ventilation fan case body 11d is blown toward the lower surface of the conduction path 12, so that the vicinity of the lower surface of the convex portion 11b. Tends to be negative pressure. Since the first ventilation rectification member 15a is provided on the lower surface of the inner wall of the convex portion 11b that is likely to be negative pressure, the first ventilation rectifying member 15a is in the vicinity of the lower surface of the convex portion 11b that is liable to be disturbed. Can be positively rectified, and the generation of noise in the convex portion 11b can be effectively reduced.

  Similarly, when the circulation sirocco fan 27 rotates, air sucked from the circulation suction port 27g of the circulation fan case main body 27d is blown toward the upper surface of the conduction path 28, so that the convex portion 27b The vicinity of the top surface is particularly likely to be negative pressure. Since the first circulation rectifying member 35a is provided on the upper surface of the inner wall of the convex portion 11b that is likely to be negative pressure, the first air circulation member 35a is in the vicinity of the upper surface of the convex portion 27b that is liable to be disturbed. Can be positively rectified, and the generation of noise in the convex portion 27b can be effectively reduced.

  Further, the first ventilation rectification member 15a and the first circulation rectification member 35a are disposed so as not to overlap the extending direction of the second ventilation rectification member 15b and the second circulation rectification member 35b, so that the second ventilation The flow of air rectified by the rectifying member 15b and the second circulation rectifying member 35b can be guided to the side openings 11c and 27c without being blocked by the first ventilation rectifying member 15a and the first circulation rectifying member 35a. It becomes.

  Moreover, since the height of the 1st ventilation rectification member 15a and the 1st circulation rectification member 35a is adjusted so that it may become lower than the height of the 2nd ventilation rectification member 15b and the 2nd circulation rectification member 35b, it is 2nd ventilation. The flow of a large air flow upstream of the conduction paths 12 and 28 is rectified by the rectifying member 15b and the second circulation rectifying member 35b, and the sirocco of the convex portions 11b and 27b is rectified by the first ventilation rectifying member 15a and the first circulation rectifying member 35a. It is possible to effectively rectify local air turbulence that is blown out toward the lower surface of the conduction path 12 and toward the upper surface of the conduction path 28 in the vicinity of the fan.

  Furthermore, since the cross-sectional shapes of the first ventilation rectification member 15a, the second ventilation rectification member 15b, the first circulation rectification member 35a, and the second circulation rectification member 35b are formed in a tail shape, the first ventilation rectification member 15a, 2 The air resistance of the airflow to the ventilation rectification member 15b, the first circulation rectification member 35a, and the second circulation rectification member 35b can be reduced, and noise such as wind noise can be reduced.

  As mentioned above, although embodiment of the bathroom air conditioner 1 was divided and classified for every operation mode, the air blower which concerns on this invention is not limited to embodiment mentioned above. It will be apparent to those skilled in the art that various changes and modifications can be made within the scope of the claims, and these are naturally within the technical scope of the present invention. Understood.

  For example, in this embodiment, the 1st ventilation rectification member 15a and the 2nd ventilation rectification member 15b are installed one by one, and the 1st circulation rectification member 35a and the 2nd circulation rectification member 35b are similarly installed one by one. Although the description has been made by showing an example in which a single unit is installed, the first ventilation rectification member 15a, the second ventilation rectification member 15b, the first circulation rectification member 35a, and the second circulation rectification member 35b are not necessarily single. There is no need, and a plurality may be set.

  In the above-described embodiment, the first ventilation rectification member 15a and the second ventilation rectification member 15b are formed only on the bottom surface of the inner wall of the ventilation fan case main body 11d, and the first circulation rectification member 35a and the second circulation rectification member 35b are formed. Although it is configured to be formed only on the upper surface of the inner wall of the circulation fan case main body 27d, the rectifying member is not necessarily limited only to the inner wall bottom of the ventilation fan case main body 11d and the upper surface of the inner wall of the circulation fan case main body 27d. As shown in FIG. 16, it is good also as a structure each installed in the ventilation fan case main-body part 11d and the circulation fan case main-body part 27d upper and lower surfaces.

  When the length of the duct connected like the 1st other room exhaust duct 46a, the 2nd other room exhaust duct 46b, and the exhaust duct 50 becomes long, exhaust pressure loss in conduction passage 12 becomes high, and smooth exhaust There is a tendency not to be done. In such a case, the rotation of the sirocco fan may disturb the airflow not only on the upper or lower surface of the fan case main body but also on the upper and lower surfaces of the fan case main body. There is a possibility that a sufficient rectifying effect cannot be achieved only by installing the rectifying member only on the upper surface or the lower surface. For this reason, as described above, by installing the rectifying members on the upper and lower surfaces of the ventilation fan case main body portion 11d and the circulation fan case main body portion 27d, the turbulence of the airflow can be positively suppressed, which is effective. Generation of noise can be suppressed by rectification of the conduction path.

  Further, when the rectifying member is installed on the upper and lower surfaces of the fan case main body, the installation position of the rectifying member is limited to the convex portion of the fan case main body and the upstream position thereof as in the bathroom air conditioner 1 described above. However, as shown in FIG. 17, it is also possible to adopt a configuration in which a plurality of rectifying members 15b are arranged in the width direction of the conduction path. By arranging the rectifying member in this way, even if there is a possibility that exhaust pressure loss in the conduction path becomes high and smooth exhaustion may not be performed, the turbulence of the airflow is smoothly suppressed and the noise is suppressed. Occurrence can be reduced.

  Further, the first ventilation rectification member 15a is formed so as to gradually warp or incline toward the ventilation sirocco fan 9 as it advances upward from the lower surface of the ventilation fan case body 11d, and the first circulation rectification The member 35a may be formed to gradually warp or incline toward the circulation sirocco fan 25 as it proceeds downward from the upper surface of the circulation fan case main body 27d.

  The first ventilation rectification member 15a is formed so as to gradually warp or incline toward the ventilation sirocco fan 9 as it advances upward from the lower surface of the ventilation fan case main body 11d. With the rotation of the ventilation sirocco fan 9 and the circulation sirocco fan 27, it is formed so as to gradually warp or incline toward the circulation sirocco fan 27 as it proceeds downward from the upper surface of the circulation fan case main body 27d. The air introduced into the conduction paths 12 and 28 from the side surfaces of the first ventilation rectification member 15a and the first circulation rectification member 35a causes air turbulence at the ends of the first ventilation rectification member 15a and the first circulation rectification member 35a. Without being generated, the first ventilation rectification member 15a and the first circulation rectification member 35a are easily guided in the extending direction, and the conduction path 1 , Together smoothly side opening 11c and the air flowing from the 28, it is possible to lead to 27c.

  Furthermore, in the above embodiment, the explanation has been made using the unitized circulation fan unit 20 and the ventilation fan unit 6, but the fan is not necessarily limited to the unitized one. It may be configured separately. Furthermore, in the above embodiment, the case where a sirocco fan is used as a fan for blowing air has been described. However, the fan is not necessarily limited to a sirocco fan, and a multiblade fan such as a radial fan is used. May be.

  Moreover, in the said embodiment, although the example of a structure which has arrange | positioned the ventilation unit 3 to the upper side of the circulation unit 4 was shown and demonstrated, the air blower which concerns on this invention has the circulation unit 4 arrange | positioned on the upper side of the ventilation unit 3. It is good also as a structure to be.

  Furthermore, in the said embodiment, although the bathroom air conditioner 1 which performs ventilation and circulation of air by a separate fan unit using the circulation unit 4 and the ventilation unit 3 was demonstrated, the ventilation fan unit 6, the circulation fan unit 20, It is good also as a structure which controls ventilation and circulation of air using a damper etc. by uniting with one fan unit. Even in such a structure, it is possible to increase the intake air volume of the fan unit by providing the auxiliary openings 13 and 30 and sucking the outside air.

  Moreover, although the bathroom air conditioner 1 shown in the said embodiment was set as the structure which arrange | positions the rotating shaft 10a of the ventilation sirocco fan 9 and the rotating shaft 26a of the circulation sirocco fan 25 in the perpendicular direction, the rotating shaft of the ventilation sirocco fan 9 is set. 10a and the rotating shaft 26a of the circulation sirocco fan 25 may be arranged horizontally.

  Furthermore, although the bathroom air conditioner 1 shown in the said embodiment was set as the structure which arrange | positions the ventilation fan unit 6 and the circulation fan unit 20 up and down, the structure which arrange | positions the ventilation fan unit 6 and the circulation fan unit 20 on right and left It may be.

  Moreover, although the air conditioner for bathroom was demonstrated in embodiment mentioned above, the air blower which concerns on this invention is not limited to the air conditioner for bathrooms, Even if it is an air conditioner used other than a bathroom Good.

It is a perspective view which shows the bathroom air conditioner which concerns on embodiment. It is a sectional side view which shows the AA cross section of the bathroom air conditioner shown in FIG. It is side sectional drawing which shows the BB cross section of the bathroom air conditioner shown in FIG. It is a side sectional view showing the state where the ventilation unit concerning an embodiment was stored in the main part case. It is the bottom view which showed the ventilation unit 3 shown in FIG. 4 from the arrow C direction. It is a perspective view which shows the state which expand | deployed the upper surface part of the ventilation fan unit which concerns on embodiment. It is side sectional drawing which shows the circulation unit which concerns on embodiment. It is the bottom view which showed the circulation unit shown in FIG. 8 from the arrow D direction. It is a perspective view which shows the upper surface part of the circulation fan unit which concerns on embodiment. It is a schematic block diagram which shows the state which installed the bathroom air conditioner which concerns on embodiment in the bathroom. (A) is the figure which showed the operation panel in embodiment, (b) is the block diagram which showed the control function of the bathroom air conditioner. It is sectional drawing of the bathroom air conditioner which showed the operation state of the bathroom air conditioner at the time of ventilation operation mode, and the flow of air. It is the figure which showed the pressure state of the conduction path in the state where the ventilation sirocco fan was rotated in the ventilation fan unit. It is sectional drawing of the bathroom air conditioner which showed the operation state of the bathroom air conditioner at the time of heating operation mode, and the flow of air. It is sectional drawing of the bathroom air conditioner which showed the operation state of the bathroom air conditioner in the dry operation mode, and the flow of air. It is a perspective view which shows a mode that the 1st ventilation rectification member and the 2nd ventilation rectification member were provided in the upper surface part and mask surface part of the ventilation fan unit which concerns on embodiment. In the perspective view shown in FIG. 16, it is a perspective view which shows the state which has arrange | positioned two or more 2nd ventilation rectification members in the width direction of a conduction path.

Explanation of symbols

1 ... Bathroom air conditioner (blower)
2 ... Body case 2a ... Flange 2b ... Exhaust port 2c ... Other room exhaust suction port 3 ... Ventilation unit 4 ... Circulation unit 5 ... Front panel 5a ... (Front panel) ventilation suction port 5b ... (Front panel) for circulation Suction port 5c ... (front panel) outlet 6 ... Ventilation fan unit (suction means)
7a: Upper ventilation suction section 7b: Lower ventilation suction section 8: Circuit board section 9: Ventilation sirocco fan (multi-blade fan)
9a ... main plate 9b (of ventilation sirocco fan) ... wing 10 (of ventilation sirocco fan) ... ventilation fan motor 10a ... rotating shaft 11 (of ventilation fan motor) ... ventilation fan case (fan case)
11a ... Exhaust guide part 11b ... Convex part 11c (of ventilation fan case) ... Side part opening (of fan ventilation) (fan outlet)
11d ... Ventilation fan case main body 11e ... Tongue part 11f (of ventilation fan case) ... Circular space part 11g (of ventilation fan case) ... Ventilation fan inlet 13a ... Front end position 13b (of the first ventilation rectifying member) ... rear end position 12 (of second ventilation rectification member) ... conduction path 15a (of ventilation fan case) ... first ventilation rectification member (first ventilation means) (of ventilation fan case)
15 ... 2nd ventilation rectification member (2nd rectification means) (of ventilation fan case)
17 ... Exhaust air passage 18 ... Exhaust air suction passage 20 in other chambers ... Circulating fan unit (suction means)
21 ... Heater 22 ... Electric chamber 23 ... Air outlet 25 (circulation unit) ... Circulation sirocco fan (multi-blade fan)
25a ... main plate 25b (of circulation sirocco fan) ... blade 26 (of circulation sirocco fan) ... circulation fan motor 26a ... rotating shaft 27 (of circulation fan motor) ... circulation fan case (fan case)
27a ... Circulation guide part 27b ... Convex part 27c (of the circulation fan case) ... Side opening (fan outlet) (of the circulation fan case)
27d ... circulation fan case body 27e ... tongue-like part 27f (of circulation fan case) ... circular space 27g (of circulation fan case) ... suction port 28 for circulation ... conduction path 33a (of circulation fan case) ... Front end position 33b (of one circulation rectification member) ... Rear end position 35a (of the second circulation rectification member) ... First circulation rectification member (first circulation means) (of the circulation fan case)
35b (second circulation rectification member (second rectification means) (circulation fan case)
36 ... Ventilation suction port 37 ... Circulation air passage 38 ... Ventilation suction air passage 40 ... Shutter 40a ... Shutter shaft 40c ... First drive gear 40d ... Second drive gear 41 ... (Shutter) motor 41a ... (Shutter motor) ) Rotating shaft 42 ... Washroom 43 ... Bathroom 43a ... Ceiling panel 43b ... Washroom 45 ... Washroom exhaust inlet 46a ... First other room exhaust duct 46b ... Second other room exhaust duct 47 ... Other room exhaust duct connection 49 ... Exhaust grill 50 ... Exhaust duct 51 ... Exhaust duct connection 52 ... Land re-pipe 53 ... Bathroom door 53a ... Air intake 55 ... Operation panel 55a ... Display 55b ... Heating mode button 55c ... Cool air mode button 55d ... Ventilation mode button 55e ... Dry mode button 55f ... Lamp 55g ... Timer button 56 ... Toilet 57 ... Connecting unit 58 ... Toy Le exhaust inlet 59 ... Living room 60 ... Control unit

Claims (8)

Suction means for sucking air by rotating a multiblade fan;
A fan case that forms a conduction path for guiding air sucked in accordance with the rotation of the multiblade fan toward the fan outlet;
Forming first rectifying means for rectifying negative pressure air in the vicinity of the fan outlet of the conduction path;
An air blower characterized in that a second rectifying means for partitioning a positive pressure portion and a negative pressure portion of air introduced by the multi-blade fan is formed on the upstream side of the conduction path with respect to the first rectification means. .   2. The blower according to claim 1, wherein the first rectifying unit and the second rectifying unit are formed on at least one of an upper surface and a lower surface of an inner wall of the fan case.   3. The air blower according to claim 1, wherein the second rectification unit is formed such that a side surface of the second rectification unit and a side wall portion of the fan case have a predetermined interval or angle. apparatus.   The blower according to any one of claims 1 to 3, wherein the second rectifying means is formed in a straight line.   The first rectifying means is formed closer to the multi-blade fan, and the front end of the first rectifying means is formed at a position deviating from the extending direction of the rear end of the second rectifying means. The air blower according to claim 1, wherein the air blower is characterized in that   6. The air blower according to claim 1, wherein a height of the first rectifying means is lower than a height of the second rectifying means. Suction means for sucking air by rotating a multiblade fan;
A fan case that forms a conduction path for guiding air sucked in accordance with the rotation of the multiblade fan toward the fan outlet;
An air blower characterized in that rectifying means for rectifying air flowing through the conduction path is formed on an upper surface and a lower surface of an inner wall of the fan case.   The blower according to claim 7, wherein the rectifying unit is provided in the vicinity of the fan outlet.

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