JP4526372B2 - Air cleaner - Google Patents

Description

  The present invention relates to an air cleaner.

  Conventionally, an air purifier has been widely used as an apparatus for purifying air by capturing dust or the like floating in the air. An air cleaner usually includes a motor, a fan, and a filter. The fan is rotated by the motor to suck air into the inside, and the sucked air is passed through the filter to capture dust and the like with the filter. To purify. Such an air cleaner is described in Patent Document 1.

This air purifier includes a dust collection filter and a deodorization filter, and dust and odor contained in the air are removed by passing the air through these filters.
JP 2002-79018 A

However, in the air cleaner described in Patent Document 1, since the dust collection filter and the deodorizing filter are arranged so as to overlap in the thickness direction of the air cleaner, the depth of the air cleaner is increased, and the installation area is increased. There is a problem that it becomes large (a large arrangement place is required).
Further, in order to improve the performance of the air cleaner, it is conceivable to further increase the fan and the filter. However, in this case as well, there is a problem that the installation area of the air cleaner is increased.

The present invention has been made based on such a background, and an object thereof is to provide an air purifier having good performance while keeping the installation area small.
Another object of the present invention is to provide an air purifier capable of efficiently purifying air.

In order to achieve the above object, according to the first aspect of the present invention, the fan (18, 23) is rotated by the motor (17, 22) to suck in the air, and the sucked air is filtered (14, 15, 19, 20). ), The air purifier (1) that exhausts air through the exhaust ports (6, 7) is provided with two component units (25, 26) including the motor, fan, and filter, In the single case (2), it is arranged in two steps up and down ,
In the case (2), an exhaust port (6) for the upper constituent unit and an exhaust port (7) for the lower constituent unit are respectively distributed in the left and right directions,
On the left and right sides of the case (2), dirt detection sensors (10, 11) for detecting the degree of air pollution are disposed, and in response to the detection signal of the dirt detection sensor, upper and lower component units (25, 26) is an air cleaner characterized by being selectively driven .

The alphanumeric characters in parentheses indicate corresponding components in the embodiments described later. The same applies hereinafter.
According to this configuration, since the structural units are arranged in two upper and lower stages, it is possible to prevent the depth of the air purifier from increasing, and to keep the installation area small. Therefore, it becomes a portable type air cleaner with a high degree of freedom in the place of placement. Moreover, since two structural units are provided, more air can be sucked and purified, and the performance of the air cleaner can be improved. Moreover, since the two component units are accommodated in a single case, the number of parts can be reduced and the cost can be reduced.

Further, in the case (2), the exhaust port (6) for the upper constituent unit (25) and the exhaust port (7) for the lower constituent unit (26) are respectively distributed in the left and right directions. In addition, on the left and right sides of the case, dirt detection sensors (10, 11) for detecting the degree of air dirt are arranged, and in response to the detection signal of the dirt detection sensor, upper and lower constituent units Since (25, 26) is selectively driven , air can be purified efficiently.

For example, as in the second aspect of the invention, the purified air is exhausted from the exhaust port (6, 7) on the side where the dirt detection sensor (10, 11) for outputting the dirt detection signal is disposed. In this way, if the upper and lower constituent units (25, 26) are selectively driven, the purified air is exhausted to the dirty side, so the air is efficiently purified. be able to.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.
FIG. 1 is a front view showing a configuration of an air purifier 1 according to an embodiment of the present invention. Moreover, FIG. 2 is a figure which shows the state which cut | disconnected the air cleaner 1 shown in FIG. 1 by the cutting line AA.
For example, the air cleaner 1 is installed in a room, takes in air outside the machine, performs a process of cleaning the air, and discharges the air outside the machine, thereby performing indoor air cleaning. The outer shape of the air purifier 1 is partitioned by a thin housing 2 having a length in the front-rear direction shorter than that in the left-right direction. A substantially rectangular upper front plate 3 that covers substantially the upper half of the front surface of the housing 2 and a substantially rectangular lower front plate 4 that covers substantially the lower half of the front surface of the housing 2 are attached to the front surface of the housing 2. An operation panel 5 as an operation display unit is attached between the upper front plate 3 and the lower front plate 4 on the front surface of the housing 2. An upper exhaust port 6 is formed on the right side surface of the upper portion of the housing 2 when viewed from the front side, and a lower exhaust port 7 is formed on the left side surface of the lower portion of the housing 2 when viewed from the front side. Yes.

The upper front plate 3 is formed with a plurality of elongated upper intake ports 8 extending from the upper part to the lower part of the upper front plate 3. A first dirt detection sensor 10 is provided inside the upper front plate 3.
The first dirt detection sensor 10 is a sensor for detecting dirt components in the air, and is provided on the right side inside the upper part of the upper front plate 3 when viewed from the front side.

The lower front plate 4 is formed with a plurality of elongated lower intake ports 9 extending from the upper part to the lower part of the lower front plate 4. A second dirt detection sensor 11 is provided inside the lower front plate 4.
The second dirt detection sensor 11 is a sensor for detecting dirt components in the air, and is provided on the left side inside the lower part of the lower front plate 4 when viewed from the front side.

As will be described later, the upper exhaust port 6 is for purifying the air sucked from the upper intake port 8 and then exhausting the air. The air sucked from the upper intake port 8 is shown in FIG. It moves in the spiral upper fan casing 40 indicated by the broken line and is exhausted from the upper exhaust port 6.
As will be described later, the lower exhaust port 7 is for purifying the air sucked from the lower intake port 9 and then exhausting the air. The air sucked from the lower intake port 9 is shown in FIG. It moves in a spiral lower fan casing 50 indicated by a broken line and is exhausted from the lower exhaust port 7.

The housing 2 is formed with an upper compartment 12 partitioned so as to occupy substantially the upper half of the housing 2 and a lower compartment 13 partitioned so as to occupy the substantially lower half of the housing 2.
The front side of the upper compartment 12 is partitioned by the upper front plate 3. The upper compartment 12 is provided with a fine dust filter 14 and a deodorizing filter 15 behind a predetermined dimension of the upper front plate 3.

The fine dust filter 14 has a size capable of covering the upper intake port 8 formed in the upper front plate 3 and is composed of a high-performance filter capable of capturing fine dust.
The deodorizing filter 15 is approximately the same size as the fine dust filter 14 and is composed of activated carbon capable of adsorbing odors and a filter capable of capturing gas components. The deodorizing filter 15 is disposed so as to overlap the fine dust filter 14 and the thickness direction of the housing 2.

The upper compartment 12 is provided with a locking body 16 that constitutes a part of the upper fan casing 40, and an upper motor 17 is attached to the locking body 16. A fan 18 is attached to the rotating shaft 17 a of the upper motor 17.
The fan 18 is a so-called sirocco fan, and when the fan 18 is rotated, air is sucked from the front center side, and the air is discharged in the radial direction of the fan 18. Therefore, when the fan 18 is rotated, as indicated by an arrow B in FIG. 2, outside air is sucked from the upper intake port 8 and passes through the fine dust filter 14 and the deodorizing filter 15, and the radial direction of the fan 18. Flowing into. Further, the upper fan casing 40 continues to the upper exhaust port 6, and the air flowing in the radial direction of the fan 18 is exhausted from the upper exhaust port 6 to the outside as indicated by an arrow C in FIG. 1.

Thus, the upper component unit 25 including the upper motor 17, the fan 18, the fine dust filter 14, and the deodorizing filter 15 is provided in the upper stage of the housing 2.
The front side of the lower compartment 13 is partitioned by the lower front plate 4. The lower compartment 13 is provided with a coarse dust filter 19 and a pollen filter 20 behind the lower front plate 4 by a predetermined dimension.

  The coarse dust filter 19 is a size that can cover the lower intake port 9 formed in the lower front plate 4 and is configured by a filter that can capture large dust. That is, the coarse dust filter 19 is a filter having a larger gap than the fine dust filter 14, the fine dust filter 14 is a high performance filter, and the coarse dust filter 19 is a low performance filter.

The pollen filter 20 is approximately the same size as the coarse dust filter 19 and is configured by a filter that can capture pollen. The pollen filter 20 is disposed so as to overlap the coarse dust filter 19 and the thickness direction of the housing 2.
The lower compartment 13 is provided with a locking body 21 that constitutes a part of the lower fan casing 50, and a lower motor 22 is attached to the locking body 21. A fan 23 is attached to the rotating shaft 22 a of the lower motor 22.

  The fan 23 is a so-called sirocco fan, and when the fan 23 is rotated, air is sucked from the front center side, and the air is discharged in the radial direction of the fan 23. Therefore, when the fan 23 is rotated, as indicated by an arrow D in FIG. 2, outside air is sucked from the lower intake port 9, passes through the coarse dust filter 19 and the pollen filter 20, and the diameter of the fan 23 is increased. Flow in the direction. Further, the lower fan casing 50 continues to the lower exhaust port 7, and the air flowing in the radial direction of the fan 23 is exhausted from the lower exhaust port 7 to the outside as indicated by an arrow E in FIG.

Thus, the lower component unit 26 including the lower motor 22, the fan 23, the coarse dust filter 19, and the pollen filter 20 is provided at the lower stage in the housing 2.
FIG. 3 is a block diagram showing an electrical configuration of a main part of the air purifier 1.
The air cleaner 1 is provided with a control unit 24 that controls each part of the air cleaner 1. The control unit 24 includes a microcomputer, a ROM, a RAM, and the like. The control unit 24 receives signals from the operation panel 5, the first dirt detection sensor 10, and the second dirt detection sensor 11, and the display mode of the operation panel 5 according to these signals. The driving of the upper motor 17 and the lower motor 22 is controlled.

When the operation panel 5 is operated by the user and the power of the air purifier 1 is turned on, the first dirt detection sensor 10 and the second dirt detection sensor 11 start detecting dirt components in the air.
When the first dirt detection sensor 10 detects a dirt component in the air, the upper motor 17 is driven and the fan 18 is rotated. Then, outside air is sucked into the upper compartment 12 through the upper intake port 8. At this time, the air passes through the fine dust filter 14 and the deodorizing filter 15 and is purified. The purified air is exhausted from the upper exhaust port 6.

Further, when the second dirt detection sensor 11 detects a dirt component in the air, the lower motor 22 is driven and the fan 23 is rotated. Then, outside air is sucked into the lower compartment 13 through the lower air inlet 9. At this time, the air passes through the coarse dust filter 19 and the pollen filter 20 and is purified. The purified air is exhausted from the lower exhaust port 7.
Thus, since the upper component unit 25 and the lower component unit 26 are arranged in two upper and lower stages, the depth of the air cleaner 1 can be prevented from increasing, and the installation area can be kept small. Therefore, the portable device has a high degree of freedom in place. Moreover, since two structural units are provided, more air can be sucked and purified, and the performance of the air cleaner 1 can be improved.

Further, since the upper component unit 25 and the lower component unit 26 are accommodated in the housing 2 which is a single case, the number of parts can be reduced and the cost can be reduced.
Further, since the upper intake port 8 and the upper exhaust port 6 are disposed above, and the lower intake port 9 and the lower exhaust port 7 are disposed below, the air can be sucked up and down. And the air after purification | cleaning can be disperse | distributed up and down and can be exhausted.

Further, since the upper exhaust port 6 and the lower exhaust port 7 are distributed to the left and right, the purified air can be distributed to the left and right and exhausted.
Further, when the first dirt detection sensor 10 on the right side as viewed from the front side detects a dirt component, the purified air is exhausted from the upper exhaust port 6 on the right side surface of the upper portion of the housing 2 and seen from the front side. When the second dirt detection sensor 11 on the left side detects a dirt component, the purified air is exhausted from the lower exhaust port 7 on the left side surface of the lower part of the housing 2, so that the cleaned side is moved to the dirty side. Since air is exhausted, the air can be purified efficiently.

  Further, since the fine dust filter 14 that is a relatively high-performance filter is used for the upper component unit 25 and the coarse dust filter 19 that is a relatively low-performance filter is used for the lower component unit 26, the efficiency is improved. The air can be purified. That is, small dust or the like floats in the air, and large dust or the like often rises from the floor, so that small dust or the like can be captured by the fine dust filter 14 and large dust or the like can be captured by the coarse dust filter 19. it can. Therefore, it is possible to efficiently use different filters. Moreover, compared with the case where the fine dust filter 14 is used for both the upper component unit 25 and the lower component unit 26, the fine dust filter 14 can be reduced and the cost can be reduced.

  Further, since the operation panel 5 is disposed between the upper component unit 25 and the lower component unit 26, the air purifier is operated when the operation panel 5 is operated as compared with the case where the operation panel 5 is disposed upward. 1 can be kept stable. Furthermore, compared with the case where the operation panel 5 is disposed below, the display can be made easier to see and the operation can be made easier. Furthermore, since the distance from the operation panel 5 to the upper component unit 25 and the lower component unit 26 is shortened, the wiring used in the air cleaner 1 can be shortened, and the cost can be reduced.

  In this embodiment, the upper exhaust port 6 is configured such that the purified air is exhausted on the right side when viewed from the front side, and the lower exhaust port 7 is configured such that the purified air is exhausted on the left side when viewed from the front side. However, the reverse is also possible, and the upper exhaust port 6 is formed so as to open above the upper front plate 3, and the lower exhaust port 7 is formed so as to open below the lower front plate 4, and after purification. The air may be exhausted upward from the upper exhaust port 6 and exhausted downward from the lower exhaust port 7.

Further, the upper motor 17 and the lower motor 22 have their rotation speed controlled according to the detection conditions of the first dirt detection sensor 10 and the second dirt detection sensor 11, that is, the higher the dirt degree, the higher the rotation speed. You may do.
For example, when the dirt detection level by the first dirt detection sensor 10 is higher than the dirt detection level by the second dirt detection sensor 11, the rotational speed of the upper motor 17 is made larger than the rotational speed of the lower motor 22. The air purification by the upper component unit 25 may be stronger than the air purification by the lower component unit 26.

Further, the rotation rate of the upper motor 17 and the lower motor 22 may be controlled in accordance with detection by the first dirt detection sensor 10 or the second dirt detection sensor 11.
For example, when the first dirt detection sensor 10 detects dirt, the upper motor 17 and the lower motor 22 are driven, and at this time, the number of rotations of the lower motor 22 is less than that of the upper motor 17. You may do. Further, the upper motor 17 and the lower motor 22 are driven in response to the detection of the dirt by the second dirt detection sensor 11, and at this time, the rotation speed of the upper motor 17 is reduced as compared with the rotation speed of the lower motor 22. You may do.

Further, the first dirt detection sensor 10 and the second dirt detection sensor 11 may be distributed on the left and right sides of the housing 2 and may not necessarily be distributed vertically.
FIG. 4 is a front view showing another form of the air purifier 27 having upper and lower constituent units 25, 26 . In addition, about the thing similar to the above-mentioned structure, description is abbreviate | omitted by attaching | subjecting the same referential mark.

In this embodiment, instead of the first dirt detection sensor 10 and the second dirt detection sensor 11, a gas sensor 28 is provided inside the upper left side of the upper front plate 3, and a dust sensor is placed inside the lower right side of the lower front plate 4. 29 is provided.
The gas sensor 28 is a sensor for detecting a gas component in the air.
The dust sensor 29 is a sensor for detecting dust floating in the air.

When the gas sensor 28 detects a gas component in the air, the upper motor 17 is driven, the fan 18 is rotated, and air outside the apparatus is sucked into the upper compartment 12 through the upper intake port 8. At this time, the air passes through the fine dust filter 14 and the deodorizing filter 15 and is purified. The purified air is exhausted from the upper exhaust port 6.
When the dust sensor 29 detects dust in the air, the lower motor 22 is driven to rotate the fan 23 and air outside the apparatus is sucked into the lower compartment 13 through the lower intake port 9. At this time, the air passes through the coarse dust filter 19 and the pollen filter 20 and is purified. The purified air is exhausted from the lower exhaust port 7.

  In this way, air is exhausted from the lower exhaust port 7 in response to the dust sensor 29 detecting dust, and air is exhausted from the upper exhaust port 6 in response to the gas sensor 28 detecting gas components. Therefore, the air is efficiently purified. That is, the dust that has accumulated on the floor often soars, and the gas component often floats in the air. Therefore, depending on the detection signal of the dust sensor 29, the lower air where there is a lot of dust is used. If the air that has been sucked in from the lower intake port 9 and purified is exhausted from the lower side, the air is exhausted to a region where more dust exists. Further, if the upper air containing a large amount of gas components is sucked in from the upper intake port 8 according to the detection signal of the gas sensor 28 and the purified air is exhausted from the upper side, the air is supplied to a region where more gas components exist. Will exhaust. That is, since the purified air is exhausted to the area to be purified, the air is efficiently purified.

Note that the magnitudes of the rotational speeds of the upper motor 17 and the lower motor 22 may be controlled according to the degree of detection of each of the gas sensor 28 and the dust sensor 29.
Further, both the upper motor 17 and the lower motor 22 may be driven in accordance with detection by the gas sensor 28 or the dust sensor 29, and the ratio of the number of rotations may be controlled by the upper and lower motors.

  For example, when the gas sensor 28 detects the gas component, the upper motor 17 and the lower motor 22 are driven, and at this time, the rotational speed of the lower motor 22 is reduced as compared with the rotational speed of the upper motor 17. There may be. In addition, when the dust sensor 29 detects dust, the upper motor 17 and the lower motor 22 are driven, and at this time, the rotational speed of the upper motor 17 is reduced as compared with the rotational speed of the lower motor 22. There may be.

Further, the upper motor 17 is mainly driven in response to the gas sensor 28 detecting the gas component, and the lower motor 22 is mainly driven in response to the dust sensor 29 detecting the dust. The gas sensor 28 and the dust sensor The place where 29 is arranged is not limited to the above.
FIG. 5 is a front view showing still another embodiment of the air purifier 30 having upper and lower constituent units 25 and 26 . In addition, about the thing similar to the above-mentioned structure, description is abbreviate | omitted by attaching | subjecting the same referential mark.

In this embodiment, instead of the first dirt detection sensor 10 and the second dirt detection sensor 11, the amount of large particle dust and the amount of small particle dust are separately detected on the upper left side of the upper front plate 3. A dust sensor 31 is provided.
When dust of small particles is detected by the dust sensor 31, the upper motor 17 is driven to rotate the fan 18 and air outside the apparatus is sucked into the upper compartment 12 through the upper intake port 8. At this time, the air passes through the fine dust filter 14 and the deodorizing filter 15 and is purified. The purified air is exhausted from the upper exhaust port 6.

When dust of a large particle is detected by the dust sensor 31, the lower motor 22 is driven to rotate the fan 23 and air outside the apparatus is sucked into the lower compartment 13 through the lower intake port 9. At this time, the air passes through the coarse dust filter 19 and the pollen filter 20 and is purified. The purified air is exhausted from the lower exhaust port 7.
Thus, when the particle size detected by the dust sensor 31 is large, air is exhausted from the lower exhaust port 7, and when the detected particle size is small, air is exhausted from the upper exhaust port 6. Therefore, the air is efficiently purified. In other words, dust that has a large particle size often floats up on the floor, and dust that has a small particle size often floats in the air, so when the detected particle size is large, If the lower air containing a lot of dust is sucked from the lower intake port 9 and the purified air is exhausted from the lower side, the air is exhausted to a region where more dust exists. In addition, when the detected particle size is small, if the upper air in which a large amount of small particle dust exists is sucked in by the upper intake port 8 and the purified air is exhausted from the upper side, the region in which more dust exists is present. The air will be exhausted. That is, since the purified air is exhausted to the area to be purified, the air is efficiently purified.

Note that the magnitudes of the rotational speeds of the upper motor 17 and the lower motor 22 may be controlled according to the amount of large particle dust detected by the dust sensor 31 and the amount of small dust.
Further, both the upper motor 17 and the lower motor 22 are driven according to whether the dust sensor 31 detects dust of large particles or dust of small particles, and the upper and lower motors adjust the number of rotations. The ratio may be controlled.

  For example, when the dust sensor 31 detects small dust, the upper motor 17 and the lower motor 22 are driven, and at this time, the rotational speed of the lower motor 22 is reduced compared with the rotational speed of the upper motor 17. It may be. Further, when the dust sensor 31 detects a large amount of dust, the upper motor 17 and the lower motor 22 are driven, and at this time, the rotational speed of the upper motor 17 is reduced as compared with the rotational speed of the lower motor 22. It may be.

FIG. 6 is a front view showing still another embodiment of the air purifier 32 having upper and lower constituent units 25 and 26 . In addition, about the thing similar to the above-mentioned structure, description is abbreviate | omitted by attaching | subjecting the same referential mark.
In this embodiment, instead of the first dirt detection sensor 10 and the second dirt detection sensor 11, a moving object detection sensor 33 that detects the movement of a human body or the like is provided on the upper left side of the upper front plate 3.

The moving object detection sensor 33 is a sensor for detecting the movement frequency of an object moving in the room.
When the moving object detection sensor 33 detects that the object movement frequency is low, the upper motor 17 is driven and the fan 18 is rotated, and air outside the apparatus enters the upper compartment 12 via the upper intake port 8. Inhaled. At this time, the air passes through the fine dust filter 14 and the deodorizing filter 15 and is purified. The purified air is exhausted from the upper exhaust port 6.

When the moving object detection sensor 33 detects that the moving frequency of the object is high, the lower motor 22 is driven to rotate the fan 23 and air outside the apparatus enters the lower compartment 13 through the lower intake port 9. Inhaled. At this time, the air passes through the coarse dust filter 19 and the pollen filter 20 and is purified. The purified air is exhausted from the lower exhaust port 7.
Further, when the moving object detection sensor 33 detects that the moving frequency of the object is the highest, the upper motor 17 and the lower motor 22 are driven, and air is sucked from the upper intake port 8 and the lower intake port 9, and after purification. Are exhausted from the upper exhaust port 6 and the lower exhaust port 7.

  In this way, the moving object detection sensor 33 drives the upper motor 17 and the lower motor 22 when it detects that the movement is the most, and drives only the lower motor 22 when it detects that the movement is large. If only the upper motor 17 is driven by detecting that the movement is small, the air is efficiently purified. That is, when there is the most movement of an object, large dust that has accumulated on the floor rises and small dust floats in the air. Therefore, by driving the upper motor 17 and the lower motor 22, the air in the area to be purified can be sucked and the purified air can be exhausted into the area. In addition, when there is a lot of movement of objects, large dust that has accumulated on the floor rises, so if the lower motor 22 is driven, air in the area to be purified is sucked and the purified air is exhausted to that area. Can do. In addition, when there is little movement of the object, there is little large dust soaring from the floor, so by driving the upper motor 17, the air in the area where the small dust is floating is sucked, and the purified air is put into that area. Can be exhausted.

In the above description, the upper motor 17 and the lower motor 22 are driven in three modes according to the movement frequency of the object. However, in each driving mode, each motor is further driven according to the movement frequency. The number of rotations may be controlled.
FIG. 7 is a front view showing still another embodiment of the air purifier 34 having upper and lower constituent units 25 and 26 . In addition, about the thing similar to the above-mentioned structure, description is abbreviate | omitted by attaching | subjecting the same referential mark.

In this embodiment, instead of the first dirt detection sensor 10 and the second dirt detection sensor 11, a temperature / humidity sensor 35 is provided on the upper left side of the upper front plate 3.
The temperature / humidity sensor 35 is a sensor for detecting the temperature and relative humidity in the air.
When the temperature / humidity sensor 35 detects that the relative humidity in the air is low, the upper motor 17 is driven, the fan 18 is rotated, and the air outside the apparatus is passed through the upper intake port 8 to the upper compartment 12. Sucked into. At this time, the air passes through the fine dust filter 14 and the deodorizing filter 15 and is purified. The purified air is exhausted from the upper exhaust port 6.

Further, when the temperature / humidity sensor 35 detects that the relative humidity in the air is high, the lower motor 22 is driven to rotate the fan 23, and the outside air passes through the lower intake port 9 and the lower compartment 13 Sucked into. At this time, the air passes through the coarse dust filter 19 and the pollen filter 20 and is purified. The purified air is exhausted from the lower exhaust port 7.
Thus, since the upper motor 17 and the lower motor 22 are selectively driven according to the relative humidity, the air can be purified efficiently. That is, when the relative humidity is low, the air is dry, so there is a lot of dust floating. Therefore, by driving the upper motor 17, it is possible to suck in air in a region where a lot of dust exists and exhaust the purified air to that region. Also, when the relative humidity is high, there are few floating dusts and there are many dusts that soar from the floor. By driving the lower motor 22, the air in a region where there is a lot of dust is sucked, and after purification, Air can be exhausted.

The upper motor 17 and the lower motor 22 are controlled according to the degree of relative humidity detected by the temperature / humidity sensor 35, or the upper motor 17 and the lower motor 22 are both rotating. The rotation rate of the motor 17 and the lower motor 22 may be controlled.
The present invention is not limited to the embodiment described above, and various modifications can be made within the scope of the claims.

For example, in the above description, the front plate is divided into the upper front plate 3 and the lower front plate 4, but the front plate may be composed of a single plate.
Further, the upper intake port 8 and the lower intake port 9 may be continuous.
Moreover, the filter used in the air cleaner 1 is not limited to the one that is configured separately at the top and bottom, and may have a common configuration at the top and bottom.

It is a front view which shows the structure of the air cleaner concerning 1st Embodiment of this invention. It is a figure which shows the state which cut | disconnected the air cleaner shown in FIG. 1 by the cutting line AA. It is a block diagram which shows the electric constitution of the principal part of an air cleaner. It is a front view which shows the structure of the other form of the air cleaner which has an upper and lower structural unit . It is a front view which shows the structure of the further another form of the air cleaner which has an upper and lower structural unit . It is a front view which shows the structure of the further another form of the air cleaner which has an upper and lower structural unit . It is a front view which shows the structure of the further another form of the air cleaner which has an upper and lower structural unit .

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Air cleaner 2 Housing 6 Upper exhaust port 7 Lower exhaust port 8 Upper intake port 9 Lower intake port 10 First dirt detection sensor 11 Second dirt detection sensor 14 Fine dust filter 15 Deodorizing filter 17 Upper motor 18 Fan 19 Coarse dust filter 20 Pollen exclusive filter 22 Lower motor 23 Fan 25 Upper component unit 26 Lower component unit 27 Air cleaner 28 Gas sensor 29 Dust sensor 30 Air cleaner 31 Dust sensor 32 Air cleaner 33 Moving object detection sensor 34 Air cleaner 35 Temperature / humidity Sensor

Claims (2)

In an air cleaner that rotates a fan with a motor to suck in air, purifies the sucked air through a filter, and exhausts it from the exhaust port.
Two component units including the motor, fan and filter are provided, and they are arranged in two stages in a single case ,
In the case, the exhaust port for the upper component unit and the exhaust port for the lower component unit are respectively arranged in a distributed manner on the left and right sides.
A dirt detection sensor for detecting the degree of air contamination is arranged on each of the left and right sides of the case, and the upper and lower component units are selectively driven in response to the detection signal of the dirt detection sensor. An air purifier characterized by. 2. The upper and lower constituent units are selectively driven so that purified air is exhausted from an exhaust port on a side where a dirt detection sensor for outputting a dirt detection signal is disposed. Air cleaner as described in

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