JP6181466B2 - Blower - Google Patents

Description

  The present invention relates to a blower, and more particularly to a blower using a centrifugal fan.

  For example, as disclosed in Japanese Patent Application Laid-Open No. 2007-170711 (hereinafter referred to as Patent Document 1), there is a blower using a centrifugal fan such as a sirocco fan or a turbo fan.

JP 2007-170711 A

  The wind speed distribution in the casing containing the centrifugal fan has a characteristic that the outer peripheral side is faster and the inner peripheral is slower. Therefore, the blowing speed from the blower outlet of the blower becomes uneven, and the air volume sent from the blower outlet may be uneven. In particular, when the air outlet is provided so that the longitudinal direction of the air outlet is the radial direction of the centrifugal fan, unevenness in the amount of air sent from the air outlet tends to occur.

  This invention is made | formed in view of such a problem, Comprising: It aims at providing the air blower which can suppress air volume nonuniformity and can blow.

  In order to achieve the above object, according to one aspect of the present invention, the blower device has a centrifugal fan in the housing, and the housing is provided with a blowout port for discharging air discharged from the centrifugal fan. As for the shape of the air outlet, the cross-sectional area perpendicular to the airflow distribution direction is larger at the position on the inner peripheral side closer to the center of the centrifugal fan than on the position on the outer peripheral side far from the center of the centrifugal fan.

  Preferably, the air blower is provided with a heater and an ion generator between the centrifugal fan and the air outlet in the housing, and a flow path of air discharged from the centrifugal fan is directed to the air outlet through the heater. A separation wall is provided to separate the first flow path and the second flow path toward the outlet through the ion generator. The separation wall is provided at a position where the channel cross-sectional area of the first channel is larger than the channel cross-sectional area of the second channel.

  More preferably, the blower device includes a sensor for detecting the temperature of the heater, and the sensor is located closer to the outlet than the position where the heater is provided, and is discharged from the first flow path. It is provided at a position closer to the centrifugal fan than the position where the air and the air discharged from the second flow path merge.

  Preferably, the air outlet is provided with a louver whose angle with respect to the air outlet is variable, and the blower device includes a control device for controlling the angle of the louver, ON / OFF of the heater, and driving of the centrifugal fan. The control device can switch between a first operation in which the heater is turned on to drive the centrifugal fan and a second operation in which the heater is turned off to drive the centrifugal fan, and is specified in advance when the first operation is stopped. During the cooling period, the heater is turned off to drive the centrifugal fan, and the cooling operation is performed so that the louver angle is parallel to the edge of the outlet. When the second operation is stopped after switching from the first operation to the second operation, the control device, when the operation period of the second operation is shorter than the cooling period, The cooling operation is executed during the difference period.

  Preferably, the air blower is provided with a heater and an ion generator between the centrifugal fan and the air outlet in the housing, and a flow path of air discharged from the centrifugal fan is directed to the air outlet through the heater. A separation wall is provided to separate the first flow path and the second flow path toward the outlet through the ion generator. The separation wall separates the first flow path and the second flow path at least up to a position where the heater is provided.

  According to the present invention, it is possible to blow air from the air blower while suppressing unevenness in the air volume.

It is the schematic which looked at the air blower concerning embodiment from the front. It is the schematic which looked at the air blower from upper direction. It is the schematic which looked at the air blower from the back. It is a block diagram which shows the specific example of a structure of the control apparatus of an air blower. It is the schematic which looked at the air blower from one side. It is a figure for demonstrating the wind speed distribution of the air discharged from a centrifugal fan. It is a figure for demonstrating the wind speed distribution of the air discharged | emitted from the blower outlet of an air blower. It is the schematic which looked up the cross section in the AA position of FIG. 3 from the downward direction. It is the schematic which looked up the cross section in the BB position of FIG. 3 from the downward direction. It is a figure for demonstrating the angle of a louver. It is a figure for demonstrating the timing of the post purge at the time of operation stop in each driving | operation of an air blower. FIG. 12 is a flowchart showing a flow of control in a control device for performing the operation of FIG. 11. FIG. It is a figure for demonstrating control of the air blower in a warm air automatic driving | operation. It is a figure for demonstrating the edge part by the side of the blowing outlet of a separation wall. It is a figure for demonstrating the case where a sensor is arrange | positioned in the position away from the heater. It is the schematic which expanded the sensor vicinity.

  Embodiments of the present invention will be described below with reference to the drawings. In the following description, the same parts and components are denoted by the same reference numerals. Their names and functions are also the same. Therefore, these descriptions will not be repeated.

  FIG. 1 is a diagram for explaining the external appearance of the blower 100 according to the present embodiment, and is a schematic view of the blower 100 viewed from the front. Referring to FIG. 1, a blower device 100 includes a housing 1, and a blowout port (blower port) 2 is provided on the front side of the housing 1. Suction ports 3 are provided on both sides of the housing 1. For example, the operation unit 4 is provided on the upper surface of the housing 1.

  As an example, the housing 1 has a vertically long shape with the vertical direction as the longitudinal direction, and a rectangular outlet 2 with the vertical direction as the longitudinal direction is provided on the front surface thereof. The air outlet 2 is provided with a louver 5 whose angle with respect to the air outlet 2 is variable.

  FIG. 2 is a diagram for explaining the operation unit 4 and is a schematic view of the air blower 100 as viewed from above. Referring to FIG. 2, operation unit 4 does not heat room temperature air, and warm air button 41 that is a button for instructing the start of warm air operation, which is an operation mode for heating and blowing room temperature air. A cool air button 42 that is a button for instructing the start of cool air operation, which is an operation mode for blowing air, and a stop button 43 that is a button for instructing stop of air blowing. In addition, the operation unit 4 may include a button for instructing timer operation, a button for instructing lock of button operation, and the like.

  FIG. 3 is a view for explaining the internal structure of the blower 100, and the blower 100 is viewed from the rear side by removing the rear face of the casing 1 and the casing 7 of the centrifugal fan 6 (FIG. 5). FIG. Referring to FIG. 3, a blower 100 includes a motor 61 having output shafts 62a and 62b on both sides in the output shaft direction, and centrifugal fans 6a and 6b mounted on the output shafts 62a and 62b of the motor 61, respectively. And a casing 7 for housing the centrifugal fans 6a and 6b. The centrifugal fans 6a and 6b are also referred to as a centrifugal fan 6 as a representative.

  The centrifugal fan 6 is, for example, a sirocco fan or a turbo fan, and a sirocco fan is used in the embodiment. Since the motor 61 is installed so that the output shafts 62 a and 62 b are horizontal with the direction of the suction port 3, the centrifugal fan 6 is installed such that the rotation surface is directed to the suction port 3 and the rotation shaft is horizontal. Therefore, when the centrifugal fan 6 is driven (rotated), air outside the housing 1 is sucked from the suction port 3 and introduced into the casing 7, and is discharged upward from the centrifugal fan 6. The air discharged from the centrifugal fan 6 is guided by the casing 7 to flow to the outlet 2 and is discharged from the outlet 2 to the outside of the blower 100. Therefore, in the following description, “upstream side” refers to the side where the centrifugal fan 6 is installed in the flow path from the centrifugal fan 6 to the outlet 2, and “downstream side” refers to the outlet 2 side.

  Two ducts 71a and 71b are formed above the portion of the casing 7 that accommodates the centrifugal fan 6 as cylinders that allow the air discharged from the centrifugal fans 6a and 6b to flow upward. Therefore, a separation wall 72 for separating the ducts 71a and 71b is provided in the casing 7. Preferably, the separation wall 72 extends upward from the lowermost portion of the casing 7 and is also provided between the centrifugal fan 6a and the centrifugal fan 6b. The ducts 71a and 71b are representatively referred to as a duct 71.

  A heater 8 is disposed in one duct 71a. The heater 8 is preferably a PTC (Positive Temperature Coefficient) heater, which is a kind of semiconductor heater that dissipates heat according to the ambient temperature and the air volume. The heater 8 has a fin-type heat radiating plate formed of aluminum or the like, and heats the air by radiating heat to the air passing between the heat radiating plates. Therefore, the heater 8 is arranged such that the fins are arranged in a comb shape in a direction (hereinafter also referred to as a width direction) orthogonal to the blowing direction (the direction from the bottom to the top) in the duct 71a. Of course, the heater 8 is not limited to a PTC heater, and may be another heater. Even in that case, preferably, the heating elements are arranged in a direction orthogonal to the blowing direction in the duct 71a.

  A sensor 81 for detecting the temperature of the heater 8 is disposed outside the duct 71 a and in the vicinity of the heater 8. The sensor 81 may be a sensor that detects the temperature electrically, such as a thermistor or a thermocouple, or may be a sensor that physically detects the temperature using a bimetal, a shape memory alloy, or the like. Further, there may be a plurality of sensors 81 (as illustrated in FIG. 8) (sensor group), and in this case, various sensors as described above may be employed. The sensor (or sensor group) 81 is electrically connected to the control device 10 described later, and outputs a sensor signal to the control device 10. The sensor 81 is covered with a cover 82 outside the duct 71a.

  An ion generator 9 is disposed in the other duct 71b. The ion generator 9 is provided with a discharge electrode (not shown) for generating negative ions and positive ions by supplying a voltage. Therefore, the ion generator 9 is arranged so that the discharge electrodes are arranged in the blowing direction (the direction from the bottom to the top) in the duct 71b. Preferably, the ion generator 9 is disposed such that the surface opposite to the surface on which the discharge electrode is provided (also referred to as the back surface) is in contact with the inner wall of the duct 71b and the tip of the discharge electrode is directed toward the inside of the duct 71b. It can be said that the position where the ion generator 9 is installed is a position where the flow velocity of the air in the duct 71b is slightly slow. By disposing the ion generator 9 at such a position, it is possible to reduce the resistance to blowing while slimming the duct 71.

  Further, referring to FIG. 3, a control device 10 for controlling the blower 100 is disposed in the housing 1. The control device 10 is electrically connected to the operation unit 4 and controls the blower device 100 according to a user operation on the operation unit 4. The control device 10 is electrically connected to a drive mechanism of the louver 5 (not shown), the heater 8, the ion generator 9, and the motor 61, so that the angle of the louver 5, the ON / OFF of the heater 8, the amount of heat, and the ion generation. The device 9 is controlled to be turned ON / OFF, and the centrifugal fan 6 is driven (ON / OFF and rotation amount).

  FIG. 4 is a block diagram illustrating a specific example of the configuration of the control device 10. Referring to FIG. 4, control device 10 includes a CPU (Central Processing Unit) 10a, a ROM 11 that is a memory for storing a program executed by CPU 10a, a set value, and the like, and when CPU 10a executes the program. In order to connect the RAM 12, which is a memory serving as a work area, an operation unit I / F (interface) 13 for connection to the operation unit 4, a heater I / F 14 for connection to the heater 8, and the ion generator 9. An ion generator I / F 15, a motor I / F 16 for connecting to the motor 61, and a sensor I / F 17 for connecting to the sensor 81.

  FIG. 5 is a diagram for explaining the internal structure of the blower 100, and is a schematic view of the blower 100 viewed from the side surface on the centrifugal fan 6a side. With reference to FIG. 5, a duct 73 a of the casing 7 is provided with a rib 73 for guiding the air discharged from the centrifugal fan 6 a to the outlet 2. The rib 73 extends upward from the portion accommodating the centrifugal fan 6a to the outlet 2.

  The heater 8 is disposed in the duct 71 a and in the middle of the rib 73, and the sensor 81 covered with the cover 82 is disposed outside the duct 71 a and in the vicinity of the heater 8.

[First Embodiment]
The shape of the air outlet 2 of the blower 100 is such that the lower position of the air outlet 2 nearer the distance from the center of the centrifugal fan 6 is closer to the air flow direction than the upper position of the air outlet 2 farther from the center of the centrifugal fan 6. It has a shape with a large cross-sectional area in the vertical direction. As a first embodiment of the blower device 100, the shape of the air outlet 2 will be described. As an example, the shape of the outlet 2 of the blower 100 according to the first embodiment is a trapezoidal shape with a long lower side and a short upper side, as shown in FIG.

  FIG. 6 is a view for explaining the wind speed distribution of the air discharged from the centrifugal fan 6a. Referring to FIG. 6, it is known from the characteristics of the centrifugal fan 6a that the wind speed increases as the distance from the center of the centrifugal fan 6a increases. The wind speed on the outer circumference along the wall surface of the casing 7 increases, and the wind speed decreases toward the inner side. Become. The arrow of FIG. 6 represents the wind speed, and the length represents the wind speed.

  FIG. 7 is a schematic view of the air blower 100 as viewed from the side surface on the centrifugal fan 6a side, and is a view for explaining the wind speed distribution of the air discharged from the outlet 2. As shown in FIG. 1 and the like, the air outlet 2 is a rectangle whose longitudinal direction is the vertical direction, which is a direction orthogonal to the rotation axis of the centrifugal fan 6. Since the wind speed increases toward the outer peripheral side of the casing 7 far from the center of the centrifugal fan 6 as described above, if the shape of the outlet 2 is the same shape in the vertical direction, as shown in FIG. The wind speed increases toward the upper side of the blowout port 2 where the air on the outer periphery of the casing 7 is guided along the wall surface. When this is warm air, since the wind speed of the air discharged from the air outlet 2 is uneven, the air temperature is also uneven, and an appropriate heating effect cannot be obtained.

  As shown in FIG. 1, the air outlet 2 of the blower device 100 according to the present embodiment has a trapezoidal shape with a long lower side and a short upper side, so that the distance from the center of the centrifugal fan 6 is short. The cross-sectional area in the direction perpendicular to the airflow delivery direction is larger in the side position than in the outer peripheral side position where the distance from the center of the centrifugal fan 6 is far. It is an example that the outlet 2 has a trapezoidal shape, and the air flow direction is closer to the inner peripheral side position closer to the center of the centrifugal fan 6 than to the outer peripheral side position farther from the center of the centrifugal fan 6. Any other shape such as a triangle may be used as long as the cross-sectional area in the direction perpendicular to is large.

  By setting it as such a shape, the resistance with respect to the air which passes the blower outlet 2 can be made large so that it may become large upwards and it may become small downwards. Therefore, the opposite resistance is given to the air whose wind speed is faster as it is guided by the duct 71 and the air is slower as it is lower. it can. Furthermore, a difference in distribution resistance can be made due to a synergistic effect with the length of the duct 7 serving as a blowing path, and the blowing speed at the blowing port 2 is made uniform.

  In this example, the shape of the blowout port 2 is a vertically long shape with the lower side being close to the centrifugal fan 6 and the upper side being far from the centrifugal fan 6, but the shape of the blower port 2 is not limited to a vertically long shape and is a horizontally long shape. It may be circular or circular. In this case as well, the cross-sectional area in the direction perpendicular to the airflow delivery direction is larger at the inner peripheral position where the distance from the center of the centrifugal fan 6 is closer than at the outer peripheral position where the distance from the center of the centrifugal fan 6 is far. It becomes the shape which becomes.

  Preferably, as shown in FIG. 5, a rib 73 is provided in the duct 71. Accordingly, since air with a high wind speed can be guided above the blowout port 2 having a high resistance and air with a low wind speed can be guided under the blowout port 2 having a low resistance, unevenness in the wind speed of the effectively discharged air can be achieved. Can be suppressed.

  More preferably, as shown in FIG. 5, the interval between the ribs 73 is not uniform, and the distance from the centrifugal fan 6 to the outlet 2 is longer as the wind speed is higher, and the passage width is reduced in the air discharge direction. To be larger. Thus, a large resistance is given to air with a high wind speed, and a small resistance is given to air with a low wind speed, so that unevenness in the wind speed of the effectively discharged air can be suppressed.

[Second Embodiment]
In the duct 71, the separation wall 72 has a flow passage cross-sectional area of the duct 71a through which the heater 8 is installed and hot air flows, and a duct 71b through which the ion generator 9 is installed and ionized air flows. It is provided at a position larger than the cross-sectional area of the channel. As the second embodiment of the blower 100, the position of the separation wall 72 will be described.

  As described above, since the heater 8 is arranged so that the fins are arranged in the width direction of the duct 71a, the width of the duct 71a needs to be at least the width of the heater 8. Moreover, since the air discharged from the centrifugal fan 6a passes between the fins of the heater 8 in the duct 71a, the flow velocity is reduced, so the amount of hot air discharged from the outlet 2 per unit time is reduced. For this reason, the wider the duct 71a, the larger the amount of warm air discharged from the outlet 2 per unit time. Therefore, the width of the duct 71a is preferably equal to or greater than the width of the heater 8. On the other hand, the design aiming at slimming of the blower 100 requires that the width of the entire ducts 71a and 71b is not too large, so that the width of the duct 71a is also not required to be too large.

  Next, on the duct 71b side, if the distance from the tip of the discharge electrode of the ion generator 9 to the inner wall of the duct 71b (the inner wall of the casing 7) which is the surface opposite to the tip is close, ions are adsorbed on the wall surface. Charge and hinder discharge from the discharge electrode. Further, since the air discharged from the centrifugal fan 6b flows through the duct 71b and is discharged from the outlet 2, the diffusion of ions is hindered. On the other hand, if the distance from the tip of the discharge electrode to the inner wall of the duct 71b (inner wall of the casing 7) is long, the air discharged from the centrifugal fan 6b also passes through a region exceeding the range where ions generated from the discharge electrode exist. Therefore, ions are not efficiently diffused. Accordingly, the width of the duct 71b is such that the distance from the tip of the discharge electrode of the ion generator 9 to the inner wall of the opposite duct 71b is such that ions are not adsorbed on the inner wall, and the ions generated from the discharge electrode are present. The width is preferably close to a certain extent. For example, the distance from the tip of the discharge electrode of the ion generator 9 to the inner wall of the opposing duct 71b is about 10 mm to 20 mm.

  8 and 9 are diagrams for explaining a specific example of the position of the separation wall 72 that separates the duct 71a and the duct 71b, and is a schematic view of the cross section of the blower 100 viewed from below.

  Specifically, FIG. 8 is a cross-sectional view taken along the line AA in FIG. 3, and is a schematic view of the cross section of the portion of the casing 7 that accommodates the centrifugal fan 6 upstream from the duct 71 as viewed from below. Referring to FIG. 8, in this portion, a separation wall 72 is provided at the central position to accommodate the centrifugal fans 6a and 6b on the left and right.

  FIG. 9 is a cross-sectional view taken along the line BB in FIG. 3, and is a schematic view of the cross-section at a portion where the duct 71 of the casing 7 starts looking up from below. Referring to FIG. 9, in this portion, separation wall 72 is provided at a position where the flow passage cross-sectional area of duct 71a is larger than the flow passage cross-sectional area of duct 71b. Therefore, the width of the duct 71a is larger than the width of the duct 71b. Preferably, considering the size (width) of the heater 8 and the size of the ion generator 9 (thickness from the front end to the back surface of the discharge electrode), as an example, the width of the duct 71a and the width of the duct 71b may The area is 7: 3. That is, preferably, the separation wall 72 is provided at a position where the ratio of the channel cross-sectional area of the duct 71a and the channel cross-sectional area of the duct 71b is 7: 3.

  For the blower 100, which is an ion generator that also has a heating function, it is required that the design amount of ions be reliably diffused into the outside environment such as a room and the outside environment is heated to a set temperature. On the other hand, in view of the situation where it is installed in a living room or the like, design is emphasized, and there is a demand for slimming.

  With respect to this problem, by installing the separation wall 72 as described above, in the air blower 100 according to the present embodiment, of the air discharged from the centrifugal fan 6, the side of the duct 71 a where the heater 8 is installed. Since the amount of air introduced into the air can be larger than the amount introduced into the other duct 71b, the amount of warm air discharged from the blower 100 can be ensured. Thereby, the heating effect can be improved while ensuring the ion diffusion effect.

  The separation wall 72 is movable, and the ratio of the channel cross-sectional area between the duct 71a and the duct 71b may be variable. For example, a configuration using a damper may be considered.

  In addition, a configuration in which the separation wall 72 such as a damper is movable is electrically connected to the control device 10, and the ratio of the flow path cross-sectional areas of the duct 71 a and the duct 71 b becomes variable according to the control signal from the control device 10. May be. In this case, for example, in the case of the cool air operation in which the warm air is not discharged from the blower 100, the control device 10 may move the separation wall 72 to a position where the flow path cross-sectional areas of the duct 71a and the duct 71b are equal. Good. By doing so, ions can be efficiently diffused.

[Third Embodiment]
In the air blower 100, a hot air operation in which the heater 8 is turned on to drive the centrifugal fan 6 and a cool air operation in which the heater 8 is turned off to drive the centrifugal fan 6 can be switched. When the hot air operation is switched to the cool air operation and when the hot air operation is completed, the blower 100 performs a cooling operation (post-purge). At that time, the louver 5 has an angle different from that during the hot air operation. At the end of the operation, after the post purge, the louver 5 is at an angle that covers the outlet 2. As a third embodiment of the blower device 100, control of the angle of the louver 5 will be described.

  FIG. 10 is a diagram for explaining the angle of the louver 5. Referring to FIG. 10, an upward movable angle α <b> 1 is provided on the structure of louver 5. Further, it is movable downward to a horizontal angle α2 (fully closed position) that completely covers the outlet 2. Note that an example in which the angle α2 is 90 ° is shown in FIG. The angle α1 corresponds to an angle such as 65 °, for example. Therefore, the movable range α on the configuration of the louver 5 is α = α1 + α2.

  As described above, the control device 10 is electrically connected to the drive mechanism of the louver 5 (not shown) and controls the drive (ON / OFF and angle). The controller 10 reciprocates (swings) the louver 5 within a range β within the movable range α during hot air operation. The range β corresponds to, for example, a range of 60 ° from the horizontal to the top and 20 ° from the horizontal to the bottom. Thereby, warm air can be spread | diffused and heating efficiency can be raised.

  When the hot air operation is switched to the cool air operation and when the hot air operation is finished, the control device 10 turns off the heater 8 and keeps the centrifugal fan 6 driven. This is because the heater 8 and the inside of the device are cooled at the end of the hot air operation. At this time, the control device 10 sets the louver 5 to an angle γ from the horizontal to the lower side than the lower limit of the swing (for example, 20 ° from the horizontal to the lower side). The position of the angle γ from the horizontal down is an angle that is parallel to the edge of the lower end of the outlet 2 as shown in FIG. Therefore, when the hot air operation is switched to the cool air operation and when the hot air operation is finished, the louver 5 swinging in the range β moves to an angle parallel to the lower edge of the outlet 2. Stop. The control device 10 maintains the angle of the louver 5 from the horizontal to the angle γ for a predetermined cooling period after switching from the hot air operation to the cool air operation or after the hot air operation is completed. Keep driving. In the case of the end of the hot air operation, the control device 10 further sets the louver 5 to the fully closed position (angle α2).

  Conventionally, for example, in a blower that discharges warm air such as heating equipment, when it is necessary to cool the equipment during operation or when the heating operation is finished, the louver is positioned where the air from the blower is blown out efficiently. (Angle) was made. However, although the cooling efficiency can be improved by setting the louver to an angle at which the air outlet is greatly opened, there is a case in which the user is misunderstood that the operation of the device is not stopped. On the other hand, if the angle is such that there are not many outlets, there is a problem that the cooling efficiency is lowered and a long cooling time is required.

  With respect to this problem, by controlling the angle of the louver 5 as described above, in the blower device 100 according to the present embodiment, the louver 5 is parallel to the inclination angle of the lowermost edge of the outlet 2. Internal air is exhausted while keeping it. Therefore, the inside of the apparatus can be efficiently cooled without giving a misunderstanding that the operation is not stopped for the user and without using wasted power. At the end of the hot air operation, the air outlet 2 is fully closed after the cooling operation for a predetermined period. Therefore, it is possible to reduce the entry of foreign matter and dust from the air outlet 2 during operation stop and prevent the child from inserting foreign matter and the like.

[Fourth Embodiment]
As described above, the air blower 100 can be switched between the hot air operation and the cool air operation. When the operation is stopped after switching from the warm air operation to the cool air operation, the blower 100 performs post-purge for a predetermined period in consideration of the period of the cool air operation. As a fourth embodiment of the blower 100, post purge control will be described. The post purge is an operation for cooling the inside of the blower 100 by turning off the heater 8 and driving the centrifugal fan 6.

  FIGS. 11A and 11B are diagrams for explaining the timing of post-purge at the time of operation stop in each operation of the blower 100, where (A) is when the hot air operation is stopped, and (B) is when the cool air operation is stopped. (C) shows the post-purge timing at the time of stop after switching from the cool air operation to the hot air operation, and (D) shows the post purge timing at the stop after switching from the hot air operation to the cool air operation. Referring to (A) of FIG. 11, when the operation stop operation is performed during the hot air operation, the blower 100 performs a post-purge for a predetermined cooling period t (for example, 30 seconds), Thereafter, the operation is stopped. Referring to (B) of FIG. 11, if the operation stop operation is performed during the cool wind operation, the air blower 100 does not require cooling, so the operation is stopped without performing the post purge. Referring to (C) of FIG. 11, even when the operation is stopped after the cool air operation and the operation is stopped during the operation of the hot air operation, the blower device 100 defines in advance as in (A). The post-purge of the cooling period t is performed, and then the operation is stopped. On the other hand, referring to (D) of FIG. 11, when the operation is stopped during the cool air operation after the hot air operation is switched to the cool air operation, the air blower 100 also posts the period of the cool air operation. The post-purge is performed for the period excluding the period of the cool air operation from the period t so that the cooling operation is performed in the purge period and the period t defined in advance as a whole, and then the operation is stopped.

  FIG. 12 is a flowchart showing the flow of control in control device 10 for performing the above-described operation. The operation shown in the flowchart of FIG. 12 is executed by the CPU 10 a reading a program stored in the ROM 11 onto the RAM 12. Referring to FIG. 12, CPU 10a continues to determine whether or not an operation for stopping the operation has been performed when blower 100 is in operation (YES in step S101). While the operation stop operation is not performed (NO in step S103), the CPU 10a continues the instructed operation (warm air operation, cool air operation) (step S105).

  When the operation stop operation is accepted (YES in step S103), the CPU 10a switches the subsequent control depending on whether the operation before the stop, that is, the current operation is the hot air operation or the cool air operation. That is, when the hot air operation is being performed (YES in step S107), the CPU 10a performs a post purge for a predetermined cooling period t (step S109).

  If it is during the cool air operation (NO in step S107), the CPU 10a is switched from the hot air operation, and further whether or not the elapsed time from the switching exceeds the post purge period t, Judging. As a result, when the cool air operation is switched from the hot air operation and the elapsed time from the switching time does not exceed the cooling period t (NO in step S111), the CPU 10a executes the post purge ( Step S109). In this case, the CPU 10a executes the post purge for a period excluding the elapsed time from the switching time from the post purge period t.

  When the cool air operation is not switched from the hot air operation, or when the elapsed time from the switching exceeds the cooling period t even if the cool air operation is switched from the hot air operation (in step S111) (YES), CPU10a stops driving | running | working, without performing a post purge (step S111).

  By performing the above operation, the air blower 100 according to the present embodiment can efficiently cool the inside of the device after the hot air operation and can save energy.

[Fifth Embodiment]
As described above, the blower 100 performs the post purge for a predetermined period when the operation is stopped during the hot air operation. As a fifth embodiment of the blower 100, post-purge different from that during hot air operation is performed during automatic hot air operation, and control thereof will be described.

  FIGS. 13A and 13B are diagrams for explaining the control of the blower 100 in the hot air automatic operation. FIG. 13A shows the control contents in each operation notch, and FIG. 13B shows the switching temperature of the operation notch. Referring to FIG. 13A, warm air normal operation and hot air automatic operation can be selected as warm air operation, and notches from 0 to 6 are set. The heater is different from the ON-OFF state. In normal warm air operation, six steps from notches 1 to 6 can be selected with the air volume button. In the hot air automatic operation, seven stages from notches 0 to 6 are automatically selected. Referring to FIG. 13B, the notch is switched according to the detected temperature during the hot air automatic operation. If it demonstrates according to a figure, when the operation | movement is performed by the notch 6, if room temperature reaches 22 degreeC, an operation | movement will be changed to the notch 4. FIG. Thereby, when the room temperature decreases to 21 ° C., the operation notch is returned to 6. Similarly, when the room temperature reaches 24 ° C., the notch 4 is changed to the notch 2, and when the room temperature reaches 26 ° C., the notch 2 is changed to the notch 0.

  In the hot air normal operation or the hot air automatic operation, when the operation is stopped by the stop button or the turn-off timer, the post purge is performed for 30 seconds to cool the heater, and then the operation is stopped. In the notch 0 of the hot air automatic operation, the fan rotation speed is set to 0. However, when the blower is completely stopped when the heater is turned off, the heat of the heater remains inside the machine body, and the fan and the heater are turned on at the room temperature. In spite of being lowered to 24 ° C. at which the notch 2 is switched, there is a problem that the hot air operation cannot be resumed. In addition, in the case of post-purging for 30 seconds as in the case of operation stop by the stop button or the turn-off timer, the heater does not cool completely even after the fan is turned off, so that the heater remains in the heat and the temperature sensor detected temperature is detected from the room temperature. Becomes higher, causing a problem that hot air operation cannot be resumed.

  In order to eliminate such inconvenience, in the blower device 100 of the present embodiment, when the operation notch is changed from 0 to 0 during the hot air automatic operation, the post-purge is performed at the minimum number of rotations at which the blower rotates. It was. The minimum number of rotations is the number of rotations at which the fan motor barely rotates. The number of rotations is about several tens of rpm, but varies depending on the characteristics of the motor. Notch 0 for automatic hot air operation is different from normal operation stop to avoid hitting the user with cold air even during hot air operation, and that the amount of air that can be sent is extremely small. In consideration of this, the special post-purge was extended to 10 minutes for a normal post-purge of 30 seconds.

  When the user gives an instruction to stop the operation with the stop button or the off timer during the special post purge, the operation returns to the normal post purge and stops all the operations after the cooling operation for 30 seconds. If the room temperature drops to 21 ° C. during the special post-purge, the operation automatically returns to the hot air operation and operates with the notch 6. In addition, when the room temperature is gradually lowered, automatic operation is started at the notch 2 when the room temperature is lowered to 24 ° C.

  Further, when the room temperature does not decrease and the special post purge is performed for 10 minutes, the rotation of the fan is stopped and the operation is waited until the room temperature decreases. By configuring as described above, in general use, it is assumed that the hot air automatic operation is started again without completing the special post purge, but it is possible to quickly detect a change in room temperature. An effect is born.

[Sixth Embodiment]
In the duct 71, the separation wall 72 extends from the portion of the casing 7 that accommodates the centrifugal fan 6 to the duct 71 as shown in FIG. 3, and the heater 8 is installed in the duct 71 and hot air flows therethrough. It is separated into a duct 71a and a duct 71b in which the ion generator 9 is installed and through which air with ions flows. The separation wall 72 is provided at least up to a position where the heater 8 is installed, and the duct 71a and the duct 71b are integrated into a single duct 71 at the end portion of the separation wall 72, so that warm air and ions are included. Air joins. As a sixth embodiment of the blower 100, the positional relationship between the separation wall 72, the heater 8, and the ion generator 9 will be described.

  FIG. 14 is a view for explaining the end of the separation wall 72 on the outlet 2 side, and is a schematic view of the blower 100 as seen from the back. Referring to FIG. 14, separation wall 72 extending from the upstream side, which is the portion of casing 7 that houses centrifugal fan 6, is provided up to the position where heater 8 is installed.

  When the merging position of the air flowing through the duct 71a and the air flowing through the duct 71b is upstream of the position where the heater 8 is installed, ions in the air flowing through the duct 71b are absorbed by the heater 8. There is a problem that the amount of ions released to the outside of the blower 100 is reduced.

  With respect to this problem, in the blower device 100 according to the present embodiment, the separation wall 72 is provided to the position where the heater 8 is installed as described above, preferably to the downstream side of the position where the heater 8 is installed. The air flowing through the duct 71 a and the air flowing through the duct 71 b merge on the downstream side of the heater 8. Therefore, the air containing ions does not pass through the heater 8 by flowing through the duct 71b in which the ion generator 9 is installed, and the ions are not absorbed by the heater 8. As a result, the amount of ions released to the outside of the blower 100 can be secured.

[Seventh Embodiment]
As described above, the sensor 81 for detecting the temperature of the heater 8 is provided in the vicinity of the heater 8. The sensor 81 is a position closer to the outlet 2 than the position where the heater 8 is provided, and the centrifugal fan 6 is located more than the position where the air discharged from the duct 71a and the air discharged from the duct 71b merge. It is provided in the upstream position close to. As the seventh embodiment of the blower 100, the position of the sensor 81 will be described with reference to FIG.

  In FIG. 14, arrows indicate the air flow in the duct 71. As described above, since the separation wall 72 is provided at least up to the position where the heater 8 is installed, the air discharged from the duct 71a and the air discharged from the duct 71b as shown in FIG. They merge on the downstream side of the heater 8. Referring to FIG. 14, sensor 81 is installed on the downstream side (outlet 2 side) with respect to heater 8 and on the upstream side (centrifugal fan 6 side) with respect to the merging position.

  Both the heated air flowing through the duct 71a on the side where the heater 8 is installed and the air flowing (not heated) through the duct 71b on the side where the ion generator 9 is installed are discharged simultaneously. In the air blower 100 which is a structure, the change of the warm air temperature in the position away from the heater 8 becomes dull. Therefore, for example, as shown in FIG. 15, when the sensor 81 is arranged at a position away from the heater 8, there is a problem that the ability to detect an abnormality in the heater 8 temperature is weakened.

  With respect to this problem, the air blower 100 according to the present embodiment detects the temperature of the heater 8 with high accuracy by disposing the sensor 81 upstream of the merging position of both air as shown in FIG. And the ability to detect temperature changes of the heater can be enhanced.

[Eighth Embodiment]
As shown in FIG. 5, the air blower 100 may further include a sensor 83 for detecting the temperature in the duct 71 a on the downstream side of the heater 8. The sensor 83 may be capable of detecting not only temperature but also humidity.

  When the air blower 100 is stopped or operating in a mode in which air is blown without turning on the heater, the sensor 83 is outside the air blower 100, for example, the temperature inside the room where the air blower 100 is installed. (And humidity) is detected.

  When the air outlet 2 is sealed by placing an object in front of the air outlet 2, the air heated by the heater 8 flows backward from the air outlet 2 toward the inside of the apparatus. In that case, the sensor 83 detects the temperature of the air heated by the heater 8 that flows backward from the outlet 2 side.

  Thereby, in the air blower 100 concerning this Embodiment, even when air is no longer discharged from the blower outlet 2, it can detect abnormal temperature.

[Ninth Embodiment]
As described above, the air blower 100 has the sensor 81 covered with the cover 82 outside the duct 71 a and in the vicinity of the heater 8.

  FIG. 16 is an enlarged schematic view of the vicinity of the sensor 81. Referring to FIG. 16, as an example, the heater 8 has an integrally formed heater terminal 8a, and the heater terminal 8a is set so as to protrude outside the duct 71a. Since the heater 8 main body and the heater terminal 8a are integrally formed, the temperature of the heater terminal 8a is substantially equal to the temperature of the heater 8.

  The cover 82 covers the heater terminal 8a protruding from the inside of the duct 71a to the outer wall (outer wall of the casing 7) and the sensor 81 without a gap between the outer wall of the casing 7 and the edge of the cover 82. Thereby, the cover 82 forms a small space including the heater terminal 8 a and the sensor 81 together with the outer wall of the casing 7. That is, in the blower 100, the sensor 81 and the heater terminal 8a are arranged in the same sealed space.

  The material of the cover 82 is not limited to a specific material, but is preferably formed of a thin metal plate (sheet metal).

  In general, the sensor 81 is generally disposed without the cover 82 in the vicinity of the heater 8. However, with such an arrangement, the sensor 81 detects the temperature of the heater 8 through a route in which the casing 7 is heated by the air heated by the heater 8 and the heat of the casing 7 is conducted. . In particular, the casing 7 is often formed of a molded product made of synthetic resin, so that the thermal conductivity is low and heat transfer is not sufficiently performed, so that accurate temperature detection may be difficult quickly.

  In order to solve this problem, as shown in FIG. 16, when the cover 82 is provided, the sensor 81 and the heater terminal 8a are arranged in the same sealed space. In the air blower 100, in addition to the above heat conduction, heat conduction in a route that suppresses heat radiation from the casing 7 and heats the sensor 81 by air in a small space heated by the heater terminal 8a is added. become. Therefore, when the heater 8 is overheated, the temperature can be detected by the sensor 81 more quickly and accurately than in the conventional arrangement.

[Tenth embodiment]
As mentioned above, although each characteristic of the air blower 100 was demonstrated by 1st Embodiment-9th Embodiment, the air blower 100 was equipped with only any one of these characteristics, Alternatively, it may be provided with two or more.

[Summary]
The aspect of the present invention can be expressed as follows.

  (1) A blower (blower 100) having a centrifugal fan (centrifugal fan 6) in a housing (housing 1), and a blowout port for discharging air discharged from the centrifugal fan to the housing (Blow-out port 2) is provided, and the shape of the blow-out port is such that air flow is closer to the position on the inner peripheral side closer to the center of the centrifugal fan than to the position on the outer peripheral side farther from the center of the centrifugal fan. A blower with a large cross-sectional area perpendicular to the direction.

Thereby, the nonuniformity of the wind speed of the air discharged | emitted from an air blower can be suppressed.
(2) A heater (heater 8) and an ion generator (ion generator 9) are provided between the centrifugal fan and the outlet in the housing, and the flow path of air discharged from the centrifugal fan passes through the heater. Then, a separation wall (separation wall 72) for separating the first flow path (duct 71a) toward the blowout port and the second flow path (duct 71b) toward the blowout port via the ion generator And the separation wall is provided at a position where the cross-sectional area of the first flow path is larger than the cross-sectional area of the second flow path.

Thereby, the heating effect can be improved while ensuring the ion diffusion effect.
(3) A sensor (sensor 81) for detecting the temperature of the heater is provided, and the sensor is located closer to the outlet than the position where the heater is provided, and is discharged from the first flow path. The air blower according to (2), provided at a position closer to the centrifugal fan than a position where the air and the air discharged from the second flow path merge.

  Thereby, the temperature of the heater can be detected with high accuracy, and the detection capability of the temperature change of the heater can be enhanced.

  (4) The louver (louver 5) having a variable angle from the outlet is provided at the outlet, and a control device (control for controlling the louver angle, heater ON / OFF, and centrifugal fan drive) The control device includes a first operation (warm air operation) in which the heater is turned on to drive the centrifugal fan, and a second operation (cool air operation) in which the heater is turned off to drive the centrifugal fan. The control device is capable of switching the heater to turn off the heater and drive the centrifugal fan for a predetermined cooling period when the first operation is stopped, and to make the louver angle parallel to the edge of the outlet When the second operation is stopped after switching from the first operation to the second operation, the control device performs the cooling period when the operation period of the second operation is shorter than the cooling period. And luck Period of the difference between the periods, executes the cooling operation, the air blowing apparatus according to any one of (1) to (3).

  Thereby, in the air blower, the inside of the apparatus can be efficiently cooled after the hot air operation, and energy saving can be achieved.

  (5) A heater (heater 8) and an ion generator (ion generator 9) are provided between the centrifugal fan and the outlet in the housing, and the flow path of air discharged from the centrifugal fan passes through the heater. Then, a separation wall (separation wall 72) for separating the first flow path (duct 71a) toward the blowout port and the second flow path (duct 71b) toward the blowout port via the ion generator And the separation wall separates the first flow path and the second flow path at least up to a position where the heater is provided.

Thereby, the discharge | release amount of the ion outside a ventilation apparatus can be ensured.
The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

  DESCRIPTION OF SYMBOLS 1 Housing, 2 Outlet, 3 Suction port, 4 Operation part, 5 Louver, 6, 6a, 6b Centrifugal fan, 7 Casing, 8 Heater, 8a Heater terminal, 9 Ion generator, 10 Control apparatus, 10a CPU, 11 ROM, 12 RAM, 13 Operation unit I / F, 14 Heater I / F, 15 Ion generator I / F, 16 Motor I / F, 17 Sensor I / F, 41 Hot air button, 42 Cool air button, 43 Stop button , 61 Motor, 62a, 62b Output shaft, 71, 71a, 71b Duct, 72 Separating wall, 73 Rib, 81, 83 Sensor, 82 Cover, 100 Blower.

Claims (5)

A blower having a centrifugal fan in the housing,
And outlet for discharging the air discharged from the centrifugal fan in the enclosure,
A heater disposed between the centrifugal fan and the outlet in the housing;
A sensor for detecting the temperature of the heater;
A cover that covers the sensor,
The heater is
Including a heater terminal protruding on the outer wall of the housing;
Operates according to the temperature detected by the sensor,
The cover is disposed so as to form a closed space including the sensor and the heater terminal,
The shape of the outlet is a cross-sectional area perpendicular to the air flow direction in the position on the inner peripheral side closer to the center of the centrifugal fan than on the outer peripheral position far from the center of the centrifugal fan. Big blower. The Tadashi body, ion-generator is provided between the said centrifugal fan to said outlet,
A flow path of air discharged from the centrifugal fan, a first flow path toward the blowout opening via the heater, and a second flow path toward the blowout opening via the ion generator; A separation wall is provided for separation,
The blower according to claim 1, wherein the separation wall is provided at a position where a cross-sectional area of the first flow path is larger than a cross-sectional area of the second flow path. Before Symbol sensor is a side position closer to the outlet than the position provided with the said heater, and the air discharged from the second flow path and the air discharged from the first flow path The air blower according to claim 2, wherein the air blower is provided at a position closer to the centrifugal fan than a position at which the two are joined. The Tadashi body, ion-generator is provided between the said centrifugal fan to said outlet,
A flow path of air discharged from the centrifugal fan, a first flow path toward the blowout opening via the heater, and a second flow path toward the blowout opening via the ion generator; A separation wall is provided for separation,
The blower according to claim 1, wherein the separation wall separates the first flow path and the second flow path to at least a position where the heater is provided. A blower having a centrifugal fan in the housing,
The housing has a blowout port for discharging air discharged from the centrifugal fan,
A heater disposed between the centrifugal fan and the outlet in the housing is provided;
The shape of the outlet is a cross-sectional area perpendicular to the air flow direction in the position on the inner peripheral side closer to the center of the centrifugal fan than on the outer peripheral position far from the center of the centrifugal fan. Is big ,
The air outlet is provided with a louver whose angle with respect to the air outlet is variable,
A control device for controlling the angle of the louver, ON / OFF of the heater, and driving of the centrifugal fan;
The control device can switch between a first operation for turning on the heater and driving the centrifugal fan, and a second operation for turning off the heater and driving the centrifugal fan,
The control device performs a cooling operation to turn off the heater to drive the centrifugal fan and to make the angle of the louver parallel to the edge of the air outlet during a cooling period specified in advance when the first operation is stopped. Run,
When the second operation is stopped after switching from the first operation to the second operation, the control device, when the operation period of the second operation is shorter than the cooling period, the duration of the difference of the cooling period and the operation period, to perform the cooling operation, feeding the wind device.

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