JP3707225B2 - air purifier - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an air cleaner provided with both a fan and a fan that induces ionic wind to blow.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, in an air purifier that sucks indoor air and cleans it by dust collecting means, air blowing means for sucking and blowing air is required. There are two types of conventional air purifiers: one that blows air with a fan and cleans it with dust collection means, and one that induces ion wind to blow and cleans with dust collection means.
[0003]
However, an air cleaner equipped with a fan can take a large amount of air flow, but it is noisy and the electricity bill is high, so it is suitable for those that quietly clean the air for a long time like a bedroom or a study. It wasn't. On the other hand, the type of air cleaner that induces ionic wind has a problem that the amount of blown air is small, and it is not as good as the fan type to quickly purify air in a short time.
[0004]
In addition, in order to detect the dirty state of room air, a dust sensor device is attached to the outer surface of the main body case of the air purifier. As a result, the detection speed becomes slow. For this reason, a dust sensor device for detecting a dirty state of indoor air is provided in the flow path in order to detect the dirty state of the indoor air in a case where the air is blown by a fan and cleaned by the dust collecting means. Although this is done, it is possible to detect the dirty state by rotating the fan and forcing the indoor air to flow to the duct sensor device, but every time it tries to detect the dirty state of the indoor air There is a problem that the fan must be operated, and there is a problem that the power consumption increases and the cost is high.
[0005]
[Problems to be solved by the invention]
The present invention was invented in view of the problems of the above-described conventional example, and it is necessary to perform an air cleaning mode depending on the purpose, for example, when it is desired to quietly clean the air or when it is desired to quickly clean the air in a short time. It is possible to respond effectively by selecting, and it is possible to detect it quickly with a simple configuration when detecting dirt in the room air, to reduce power consumption in the dirt detection, and more than a certain amount of dirt in the room air In this case, it is an object to provide an air purifier that can automatically clean a room air dirt by automatically operating a fan.
[0006]
[Means for Solving the Problems]
In order to solve the above problems, the air purifier of the present invention is an air purifier 2 having both air blown by a fan 1 and air blown by inducing an ionic wind, one end of which is an inlet for room air. A dust sensor device 31 having a detection passage 32 whose other end is an outlet to the ion wind passage 3 is provided, and the detection passage 32 is made to pass through the indoor air by the flow of the ion wind flowing through the ion wind passage 3. The dust sensor device 31 is provided with a dust sensor 31a for detecting dirt in the indoor air flowing through the detection passage 32 by the flow of ion wind, and the detected value of the dirt in the room air by the dust sensor 31a. Is over a certain level In addition to the operation of inducing the ion wind and blowing air A control unit 40 that controls the fan 1 to operate is provided. In the present invention, with such a configuration, when it is desired to quietly clean the air, the air is purified by blowing air induced by ion wind, and when the air is quickly cleaned in a short time or the degree of air contamination Is large, the air is purified by blowing air from the fan 1. When it is desired to detect the dirty state of the room air, the ion wind is induced to flow through the flow path 3 and the room air is sucked from the detection passage 32 along the flow of the ion wind. The dirt can be quickly detected by the dust sensor 31a. And in detecting the contamination of the indoor air, the indoor air is quickly sucked in using the flow induced by the ionic wind, so that the detection of the contamination by operating the fan as in the past is performed. Power consumption can be reduced. Further, when the dirty state of the indoor air detected as described above becomes a certain level or more, the fan 1 can be operated to increase the amount of blown air and quickly clean the indoor air.
[0007]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, the present invention will be described based on embodiments shown in the accompanying drawings.
The main body case 4 of the air cleaner 2 has a large opening on the front side, and a front cover 5 is detachably attached so as to cover the front opening of the main body case 4. Most of the front cover 5 is an air suction portion 10, and the air suction portion 10 is formed by forming a mesh or a large number of small holes, or by forming a suction port between louver pieces. is there.
[0008]
As shown in FIGS. 1 and 2, the front opening of the main body case 4 is recessed rearward, and the back of the recessed portion is a filter attachment portion 6, and the filter 7 is attached to and detached from the filter attachment portion 6. Can be installed freely. This filter 7 can be attached or removed by removing the front cover 5. The filter 7 may have a single type of single-layer filter configuration, or may have a multilayer filter configuration in which a plurality of types of filters are stacked in multiple layers. In the embodiment shown in FIG. 3, a multilayer structure of a pre-filter 7a for removing coarse dust, a filter body 7b for removing dust and deodorizing, and a filter 7c for removing formalin for removing formalin generated from building materials at the time of new construction, An example is shown.
[0009]
A fan housing 8 is provided on the back of the filter mounting portion 6 of the main body case 4, and the fan 1 (sirocco fan in the embodiment shown in the accompanying drawings) is disposed in the fan housing 8. A hole 9 communicating with the fan 1 is opened in the back wall of the filter mounting portion 6. A fan discharge port 11 is provided on the upper surface of the rear part of the main body case 4, and when the fan 1 is operated, the air suction part 10 of the front cover 5 is directed to the filter 7 as indicated by the white arrow in FIG. 5. Then, the air is sucked in horizontally, purified by the filter 7, and discharged upward from the fan outlet 11 through the hole 9 and the fan 1.
[0010]
As described above, the front cover 5 is attached to the front opening of the main body case 4, and the filter 7 is attached to the back of the recessed portion behind the front opening so that the front cover 5 and the filter are attached. A space is formed between the two. This space is a flow path 3 for ion wind. The main body case 4 is provided with a suction port 12 that opens in the vertical direction in the lower bottom portion of the space. The suction port 12 communicates with a lower end opening 13 provided on the front surface of the lowermost end portion of the main body case 4 via an introduction detection passage 14. A pre-filter 18 for collecting relatively large dust is attached to the suction port 12.
[0011]
At the front part of the upper surface of the main body case 4, there is provided a blowout port 15 that communicates with the ion-air flow path 3 constituted by a space formed between the front cover 5 and the filter 7.
Further, a first discharge electrode block 16 and a second discharge electrode block 17 are respectively provided at the lower part and the upper part of the ion-air flow path 3 constituted by a space formed between the front cover 5 and the filter 7. Provided.
[0012]
Here, the first discharge electrode block 16 constitutes dust charge means and ion wind induction means for inducing ion wind by charging dust in the air, and opens up and down as shown in FIG. The electrode frame 19 includes a rectangular electrode frame 19, a discharge line 20 disposed in the lower part of the electrode frame 19, and a counter electrode plate 21 made of a conductive thin steel sheet disposed in the upper part of the electrode frame 19. The discharge wire 20 is attached to the electrode frame 19 with its end being tensioned by a coil spring 22. In addition, one end or both ends of the discharge wire 19 is covered with a rubber or synthetic resin tube 23 having elasticity and insulation to absorb vibration. The discharge wire 20 is formed of, for example, a thin tungsten wire or piano wire having a small diameter.
[0013]
The counter electrode plate 21 disposed above the discharge line 20 is fixed to the electrode frame 19 at portions where insulation coating is applied at both ends.
The first discharge electrode block 16 formed in this way can be attached and detached by removing the front cover 5. The first discharge electrode block 16 is attached to the first discharge electrode block 16 in a state where the first discharge electrode block 16 is disposed and attached to the lower portion of the space of the main body case 4 (supported by a support member not shown). For example, a voltage of +6.5 kV is applied to the discharge line 20, and a voltage of −6.5 kV, for example, is applied to the counter electrode plate 21.
[0014]
The filter 7 is formed of a conductive material, and the filter 7 is grounded or applied with a voltage of, for example, −6.5 kV when the power is turned on.
Similar to the first discharge electrode block 16, the second discharge electrode block 17 provided in the upper part of the space constituting the ion flow path 3 has a function of inducing an ion wind. That is, the second discharge electrode block 17 is composed of an ionization needle 24 facing upward and an ionization needle counter electrode plate 25 disposed above the ionization needle 24, and the ionization needle 24 has, for example, −6.5 kV. A voltage is applied, and the ionization needle counter electrode plate 25 is connected to the ground side of the circuit.
[0015]
Next, an operation in the case where air is purified by inducing an ion wind will be described. When a voltage is applied to each of the first discharge electrode block 16 and the second discharge block 17 as described above, first, air in the vicinity of the discharge line 20 is ionized to generate positive ions, and these positive ions have a negative potential. It moves toward the counter electrode plate 21. During this movement, positive ions collide with molecules in the air, and the kinetic energy of the positive ions is given to the molecules in the air, so that the air moves. The flow of air generated in this way is a wind called an ionic wind, and an ionic wind traveling upward is generated by the movement of molecules.
[0016]
As a result of the ionic wind generated in this manner, room air is sucked from the lower end opening 13 at the lowermost end of the main body case 4 as shown by the black arrow in FIG. Thus, a flow of wind that flows out from the blowout port 15 at the front upper portion of the main body case 4 is generated. In this case, a large amount of dust is collected by the pre-filter 18, and then, in the first discharge electrode block 16, the dust in the air collides with the positive ions and is charged positively, and the positively charged dust is Then, it moves upward by the ion wind, is attracted to the filter 7 that is grounded or has a negative potential, and is collected by the filter 7. Thereafter, in the second discharge electrode block 17, the ion wind is accelerated by the same principle as that of the first discharge electrode block 16, and further, negative ions are added by the ionization needle 24 provided in the vicinity of the outlet 15. . Air is ionized in the vicinity of the tip of the ionization needle 24 to generate negative ions, and an ion wind flows to the outlet 15 along the electric lines of force generated between the ionization needle 24 and the ionization needle counter electrode plate 25 that is grounded. Purified air to which negative ions, which are guided and good for the human body, are added is released into the room.
[0017]
A dust sensor device 31 is attached to the upper part (in the embodiment, the upper part of the side surface) of the outer surface of the main body case 4. This dust sensor device 31 is provided with a detection passage 32 that opens into the room and the upper part of the flow path 3 of the ion wind. That is, one end of the detection passage 32 opens into the room to be an indoor air inlet 31k, and the other end opens into the ion wind channel 3 to the ion wind channel 3. So that the indoor air flows into the upper portion of the ion flow passage 3 through the detection passage 32 by being drawn by the flow of the ion wind when the ion wind flows through the flow passage 3. It has become. As described above, when the room air flows through the detection passage 32 of the dust sensor device 31, the degree of air contamination is detected by the dust sensor 31 a provided in the dust sensor device 31. In this way, it is possible to quickly detect dirt in the room air.
[0018]
The dust sensor device 31 is formed with a detection passage 32 having both ends opened in a box-shaped main body 31b as shown in FIG. 8 (in other words, the inlet 31k of the detection passage 32 is opened indoors). The outlet 31m of the detection passage 32 communicates with the ion-flow passage 3), and a partition wall 31c is provided in the detection passage 32 so as to be opposed to each other with a gap 31i in the vertical direction so that the box-shaped main body 31b is provided. The room is divided into two rooms 31d and 31e, a light emitting part 31f is provided in one room 31d and a light receiving part 31g is provided in the other room 31e, and the dust sensor 31a is constituted by the light emitting part 31f and the light receiving part 31g. It is. In the figure, reference numeral 31 j denotes an electronic circuit unit provided in the dust sensor device 31. FIG. 9 is an explanatory diagram showing the relationship between the light emitting area emitted from the light emitting unit 31f and the light receiving area received by the light receiving unit 31g. As is apparent from FIG. 9, light is emitted from the light emitting unit 31f. The light is configured not to reach the light receiving unit 31g directly. Here, the light emitting unit 31f emits the LED at regular intervals, and the light receiving unit 31g also detects the amount of received light according to the cycle of the light emitting unit 31f. When indoor air flows through the detection passage 32 from the inlet 31k toward the outlet 31m, the light emitted from the light emitting portion 31g is scattered by dust (particles) contained in the indoor air, and the light receiving portion 31f. Since the light reaches the side, the change in the amount of light is detected, and the amount of received light is converted into the amount of dust, so that the dirty state of the indoor air can be detected.
[0019]
Next, the operation mode of the present invention will be described.
An operation switch 30 and various operation display units are provided on the outer surface (an outer surface such as a front surface or an upper surface) of the main body case 4. In the present embodiment, by operating the operation switch 30, “OFF”, “AUTO MODE”, “ION MODE”, and “FAN MODE” can be selected.
[0020]
A specific example will be described. By operating the operation switch 30, switching can be performed in the order of “off” → “automatic mode” → “ion mode” → “fan mode” → “off”. FIG. 10 shows a control block diagram. In the present invention, when the degree of contamination of the indoor air is detected by the dust sensor 31a in the “ion mode” in each of the above modes, the detected data is obtained as shown in FIG. The fan 1 is operated by the output from the control unit 40 when the degree of contamination of the room air is a certain value or more.
[0021]
Thus, the “OFF” state is a state in which the operation is stopped. When the operation switch 30 is operated in this “OFF” state, the “automatic mode” is first set. This “automatic mode” is a mode for automatically detecting dirt in the room air. That is, when the operation switch 30 is operated to enter the “automatic mode”, an operation is performed in which an ionic wind is induced to blow air, and the flow of the ionic wind causes indoor air to flow into the flow path 3 through the detection passage 32 of the dust sensor device 31. Since the air is drawn in, the dirty state of the room air is quickly detected by the dust sensor 31a when the room air passes through the detection passage 32 of the dust sensor device 31.
[0022]
The detection result obtained by detecting the dirt state of the indoor air flowing in by the flow of the ion wind by the dust sensor 31a is output to the control unit 40, and when the degree of dirt is less than a certain value, the ion wind is directly induced to perform air purification. In the case where the degree of contamination is equal to or greater than a certain value, the fan 1 is set to “weak” or “standard” or “ The operation of the fan 1 is controlled by a control signal from the control unit so as to operate quickly and to clean up the dirt in the room air quickly by purification by the operation of the fan 1 having a large air volume. When the detection result of the dirty state of the indoor air by the dust sensor 31a falls below a certain value, the operation by the fan 1 is stopped, and only the operation for inducing ionic wind and purifying the air is controlled. It is.
[0023]
Next, when the operation switch 30 is operated to switch from the “automatic mode” to the “ion mode”, in the “ion mode”, only the operation of inducing the ionic wind and purifying the air flow is continuously performed. In the “ion mode” operation, the fan 1 is not operated even when the indoor air is in a dirty state over a certain value. As described above, in the “ion mode” operation, only the operation of inducing the ionic wind to purify the air flow is performed, and the air purification by the operation of the fan 1 is not performed. Therefore, the sound is quiet and particularly suitable for sleeping. It is.
[0024]
Next, when the operation switch 30 is operated to switch from the “ion mode” to the “fan mode”, in the “fan mode”, the air flow is purified by the operation of the fan 1. It is possible to purify indoor air with a large degree of contamination, and to purify indoor air in a short time. In the “fan mode”, “weak fan mode”, “standard fan mode”, and “rapid fan mode” having different air volumes can be selected. In the “fan mode”, an operation is also performed in which an ionic wind is induced to purify the air.
[0025]
In the above embodiment, the dust sensor device 31 is attached to the upper part of the outer surface of the main body case 4, one end of the detection passage 32 of the dust sensor device 31 is opened in the room, and the other end is the flow of ion wind. Although an example in which the upper portion of the path 3 is communicated is shown, the attachment position of the dust sensor device 31 is not limited to the upper portion of the outer surface portion of the main body case 4, and one end portion of the detection passage 32 opens into the room. As long as the other end of the detection passage 32 communicates with the ion flow passage 3, the dust sensor device 31 may be attached to the other part of the body case 4, and the suction port 12 and the lower end opening In this case, one end of the detection passage 32 opens to the suction port 12 side and serves as an inlet for room air. End opens to the lower opening 13 side As a result, a part of the indoor air flowing in from the lower opening 13 due to the flow of the ion wind flows in the detection passage 32 of the dust sensor device 31, so that the dust sensor device 31 The dust sensor 31a provided can detect the dirty state of the room air.
[0026]
As described above, the dust sensor device 31 can be provided at various positions in various forms. FIG. 11 shows a specific example of attachment of the dust sensor device 31. That is, in the present embodiment, an example is shown in which the dust sensor device 31 is attached to the outer surface portion of the main body case 4 so as to communicate with the outer surface portion of the main body case 4 and the flow path 3 of ionic wind in the main body case 4. The dust sensor device 31 is fitted into the hole 35 so that the hole 35 can be inserted into and removed from the outside of the hole 35. A box-shaped main body 31b constituting the outer shell of the dust sensor device 31 is configured by detachably attaching a cover plate 31q to an opening of a box-shaped main body portion 31p having one side opened. In a state where the dust sensor device 31 is fitted in the hole portion 35, a dust sensor cover 36 is attached to the opening portion outside the hole portion 35 so as to be freely opened and closed. The dust sensor cover 36 closes the opening outside the hole 35 so as to prevent the dust sensor device 31 from being exposed to the outside. In this case, an opening 36a provided in the dust sensor cover 36 is provided in the main body 31b. The detection passage 32 communicates with the inlet 31k.
[0027]
Therefore, in this embodiment, when cleaning the dust inside the dust sensor device 31, the power of the air cleaner is turned off, and the dust sensor cover 36 is removed from the state of FIG. 11 (a). Next, the dust sensor device 31 is pulled out from the hole 35 as shown in FIG. 11 (c), and then the cover plate 31q is removed as shown in FIG. 11 (d). The inside of the cover plate 31q and the inner surface of the cover plate 31q are cleaned with a cotton swab or a soft cloth. When the cleaning is completed, the cover plate 31q is attached to the box-shaped main body 31p again, and the dust sensor device 31 is fitted into the hole 35, as shown in FIG. The dust sensor cover 36 is attached to the opening portion outside the hole portion 35 as in FIG. With this configuration, the dust sensor device 31 can be taken out of the main body case 4 and easily cleaned. When the dust sensor device 31 is pulled out and taken out from the hole 35, if one end portion of the drawing tape 45 is attached to the dust sensor device 31, the leading end portion of the drawing tape 45 is shown in FIG. It can be easily pulled out by picking and pulling with a finger.
[0028]
FIG. 12 to FIG. 15 show an embodiment in which the filter 7 is attached to the filter attachment portion 6. That is, the front opening of the main body case 4 is recessed rearward, and the back of the recessed portion is the filter mounting portion 6. The lower end portion and both side end portions of the filter mounting portion 6 are respectively L-shaped. A locking member 37 having a shape is provided, and an upper support member 38 having an inclined guide portion 38 a is provided at the upper end portion of the filter mounting portion 6. The guide portion 38a is provided on the front surface portion of the upper support 38, and the guide portion 38a is configured by making the front surface of the guide portion 38a an inclined surface located on the rear side of the lower end portion. When attaching the filter 7, first, as shown in FIG. 14, both ends of the filter 7 are inserted and locked into L-shaped locking tools 37 provided at both ends of the filter mounting portion 6. 13, the lower end portion of the filter 7 is inserted and locked into an L-shaped locking member 37 provided at the lower end portion of the filter mounting portion 6, and then the upper end portion of the filter 7 is moved to the upper support 38. While being guided along the inclined guide part 38a, it is pushed into the rear part of the upper support 38 and locked as shown in FIGS. By doing in this way, the filter 7 can be easily and accurately attached to the filter attachment portion 6 at four places, top, bottom, left and right. That is, in the case where the filter 7 is attached to the filter attachment portion 6 at the lower, right and left three locations, the upper end portion of the filter 7 is not supported, so the filter 7 may fall forward. If the filter 7 is mounted at four locations on the top, bottom, left and right, the filter 7 is prevented from falling forward, and the upper support member 38 having the inclined guide portion 38 is provided. The filter 7 is easy to attach despite the fact that the filter 7 is attached.
[0029]
FIG. 16 shows an embodiment of the filter 7 used in the present invention. That is, the filter 7 is formed of a conductive material as described above. As such a filter 7, for example, as shown in a schematic diagram shown in FIG. 17, a filter medium 41 for dust removal and conductive fibers are kneaded. The conductive fiber material 42 is overlapped and simultaneously pleated (mountain fold), deodorized material 43 is placed inside, and a cover material 44 'is further laminated. This is a filter medium for dust removal. 41 and the conductive fibers are kneaded and overlapped with the conductive fiber material 42, the pressure loss of the filter 7 occurs. Therefore, in the embodiment shown in FIG. 16, the filter material 41 for dust removal is pleated (mountain folded), The filter 7 is configured by putting a deodorizing material 43 inside and further laminating a cover material 44 containing conductive fibers. Since the filter 7 having the structure shown in FIG. 16 does not require the conductive fiber material 42 in which a separate conductive fiber is kneaded, the pressure loss of the filter 7 can be reduced, and the noise can be reduced even with the same air volume. (Or the air volume can be increased with the same noise level).
[0030]
【The invention's effect】
In the present invention, as described above, since the air purifier includes both of the air blown by the fan and the air blown by inducing the ionic wind, the air purifier can be quietly cleaned by one air purifier. If you want to do it, or if you want to clean the air quickly in a short time, you can select the air cleaning mode according to the purpose and respond effectively, and one end part is A dust sensor device having a detection passage having an inlet to the indoor air and the other end serving as an outlet to the flow path of the ionic wind is provided, and the flow of the ionic wind flowing through the flow path of the ionic wind causes the indoor air to pass through the detection passage. The dust sensor device is provided with a dust sensor for detecting dirt in the indoor air flowing through the detection passage by the flow of ion wind, and the detected value of the dirt in the room air by the dust sensor is less than a certain value. When it comes to In addition to the operation of inducing the ion wind and blowing air Since a control unit for controlling the fan to operate is provided, when it is desired to detect the dirty state of the indoor air, the ion wind flows through the ion wind channel by inducing the ion wind, and the ion wind The indoor air is sucked in from the detection passage along the flow of the air, and the dust sensor can quickly detect the dirt. In this way, in detecting the dirt of the indoor air, Because the room air is quickly sucked into the detection passage of the dust sensor device using the flow generated by the air flow, the power consumption can be reduced compared to the conventional method that detects dirt by operating the fan. It can be down and there is no noise, and if the dirty state of the indoor air detected by the dust sensor is above a certain level, In addition to the operation of inducing the ion wind and blowing air The fan can be operated to increase the amount of air flow and quickly clean the indoor air.
[Brief description of the drawings]
FIG. 1 is a cross-sectional view of the present invention.
FIG. 2 is a perspective view of the same.
FIG. 3 is an exploded perspective view of the above.
FIG. 4A is a front sectional view of a first discharge electrode block, and FIG. 4B is a bottom view.
FIG. 5 is a cross-sectional view for explaining air blowing directions during the fan operation and ion operation of the above.
FIG. 6 is a perspective view showing the air flow during fan operation.
FIG. 7 is a perspective view showing the air flow during the ion operation of the above.
FIG. 8 is a schematic configuration diagram of the inside of the dust sensor device of the above.
FIG. 9 is an explanatory diagram showing a relationship between a light emitting area that emits light from a light emitting unit and a light receiving area that receives light at a light receiving unit in the dust sensor device of the above.
FIG. 10 is a control block diagram of air blowing controlled based on the detection result by the dust sensor of the present invention.
FIGS. 11A, 11B, 11C, and 11D are explanatory views showing the order in which the dust sensor device is taken out for cleaning.
FIG. 12 is an overall cross-sectional view showing an example of attaching the filter of the present invention.
FIG. 13 is a perspective view of a portion in which the side end portion of the filter is locked and supported by a locking tool.
FIG. 14 is a perspective view of a portion in which the lower end portion of the filter is locked and supported by a locking tool.
FIG. 15 is a perspective view seen from below in a state where the upper end portion of the filter is supported by the upper support.
FIG. 16 shows an embodiment of the filter used in the above, (a) is a schematic sectional view, and (b) is a schematic perspective view.
FIG. 17 is a schematic sectional view showing a filter of a comparative example.
[Explanation of symbols]
1 fan
2 Air purifier
3 Flow path of ion wind
31 Dust sensor device
31a Dust sensor
32 Detection passage
40 Control unit

Claims (1)

An air purifier equipped with both fan blowing and ionic wind to be blown, with one end serving as an inlet for room air and the other serving as an outlet to an ion wind channel A dust sensor device having a flow path is provided and the detection air flow is set so that the indoor air flows by the flow of the ionic wind flowing through the flow path of the ion wind. A dust sensor for detection is provided in the dust sensor device, and when the detected value of the contamination of the indoor air by the dust sensor exceeds a certain value , the fan is operated in addition to the operation of inducing the ion wind and blowing the air. An air purifier comprising a control unit.

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