JP4232530B2 - Roll filter and air conditioner - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a roll filter and an air conditioner.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, air conditioners that improve comfort by blowing conditioned air in buildings, houses, and the like are known. For example, an air cleaner takes in indoor air, and separates and removes particles such as dust, smoke, pollen, and other foreign matters from the indoor air (for example, Patent Document 1). And an air cleaner blows the clean air from which these particulates were removed indoors. In this way, the air purifier keeps indoor air clean and improves indoor comfort.
[0003]
Such an air purifier includes a casing, a filter, an electric dust collection unit, a photocatalyst unit, and a sirocco fan. The casing has a suction port for sucking indoor air into the casing and a discharge port for blowing the cleaned air into the room. In the casing, the above devices are arranged in the order of a filter, an electric dust collection unit, a photocatalyst unit, and a sirocco fan from the air suction port toward the air discharge port. The sirocco fan sucks indoor air into the casing from the suction port, and generates an air flow for supplying the cleaned air into the room through the discharge port.
[0004]
The filter adsorbs relatively large dust and dirt. This filter has a roll shape in which a length corresponding to a plurality of times is wound, and is configured to be pulled out and cut a dirty portion when the surface in use is dirty. Further, the filter has a waveform in a sectional view by being sandwiched by filter guides from both the upstream and downstream sides of the air flow generated by the sirocco fan. The electric dust collection unit charges and adsorbs fine particles such as cigarette smoke. The photocatalyst unit inactivates microorganisms such as bacteria and viruses by decomposing fine particles such as malodorous components and harmful substances not adsorbed on the filter.
[0005]
[Patent Document 1]
JP-A-2002-186814 [0006]
[Problems to be solved by the invention]
By the way, in the above air cleaners, in order to improve the adsorption efficiency of the fine particles, the photocatalytic filter is formed into a cross-sectional view wave shape using a filter guide. Therefore, when replacing a filter with a dirty surface in use, for example, a user of an air cleaner needs to pull out a roll-shaped filter and sandwich the pulled-out filter using a filter guide. However, since the filter is often generated from a material having low elasticity, the filter may be broken when the user sandwiches the filter with the filter guide. Therefore, when replacing the filter, the user of the air cleaner needs to perform fine work such as sagging the filter.
[0007]
Thus, in the conventional air conditioning apparatus, it takes time to replace the filter and put it into use.
[0008]
Accordingly, an object of the present invention is to provide a filter and an air conditioner that can be easily installed and can improve dust collection efficiency.
[0009]
[Means for Solving the Problems]
The roll filter according to claim 1 includes an elastic body and a dust collecting portion. Here, the “elastic body” is, for example, a rubber string. A part of the elastic body is fixed to the dust collection portion at a predetermined interval along the expansion and contraction direction. And this dust collecting part becomes a planar shape when the elastic body is extended, and becomes a bent shape when the elastic body is contracted from the state of the elastic body in the planar shape. And this dust collection part is wound by the cylindrical shape in the state by which the elastic body was extended | stretched so that a planar shape might be maintained.
[0010]
For this reason , for example, it is not necessary for the user or the like to perform some work to place the filter in a bent state. For this reason , installation of a filter becomes easy. Further, at the time of dust collection, the dust collection portion is in a bent state. Therefore, since the area of the surface part which contacts air increases, dust collection efficiency is improved.
[0011]
For this reason, in this filter, it can install easily and dust collection efficiency can be improved.
[0012]
Here, the dust collecting portion is wound in a cylindrical shape when stored. Therefore, the storage space is reduced during storage. For this reason, in this roll filter, the storage space is further reduced.
[0013]
Roll filter according to claim 2 is the roll filter according to claim 1, the dust collecting part has a crease. The fold forms a waveform.
[0014]
Here, the dust collection part has the fold which forms a waveform. Therefore, for example, when a worker or the like alternately folds the dust collecting portion, the fold can be easily manufactured. For this reason, in this roll filter, the ease of manufacture improves.
[0015]
Roll filter according to claim 3, a roll filter according to claim 2, the pitch of the waveform is constant.
[0016]
Here, the pitch of the waveform of the dust collector is constant. Therefore, the dust collection unit can uniformly collect particles in the air. For this reason, in this roll filter, the entire surface of the dust collecting portion is effectively used for collecting particles in the air.
[0017]
The air conditioning apparatus according to claim 4 includes a casing, a blower, and a roll filter. The blower sucks outside air into the casing. Further, the blower blows out the air sucked into the casing into a predetermined space. Roll filter is a roll filter according to any one of claims 1 to be incorporated in the casing 3 of the.
[0018]
For this reason , for example, it is not necessary for the user or the like to perform some work to place the filter in a bent state. For this reason, in this air conditioner, it is easy to install the filter. Further, at the time of dust collection, the dust collection portion is in a bent state. Therefore, since the area of the surface part which contacts air increases, dust collection efficiency is improved.
[0019]
Further, here, the dust collecting unit, during storage, is wound into a cylindrical shape. Therefore, the storage space is reduced during storage. For this reason, in this roll filter, the storage space is further reduced.
[0020]
DETAILED DESCRIPTION OF THE INVENTION
<Overall configuration of the air purifier>
In FIG. 1, the external view of the air cleaner 1 by which one embodiment of this invention is employ | adopted is shown.
[0021]
The air purifier 1 keeps the room in a comfortable environment by purifying indoor air in buildings and houses and blowing the cleaned air into the room. The air cleaner 1 includes a casing 10, a blower mechanism 20 (see FIG. 2), a control unit 50 (see FIG. 3), and a filter unit 30 (see FIG. 2).
[0022]
The casing 10 constitutes the outer surface of the air purifier 1 and includes the blower mechanism 20, the control unit 50, and the filter unit 30. The casing 10 has a main body 11 and a front panel 12.
[0023]
The main body 11 has an upper surface suction port 13, a side surface suction port 14, and a blowout port 15. The upper surface suction port 13 and the side surface suction port 14 are substantially rectangular openings for sucking room air into the air purifier 1 in order to clean the room air in the air purifier 1. The upper surface suction port 13 is provided at the front side end of the upper surface of the main body 11 that is the same as the surface on which the blowout port 15 is provided. The side suction ports 14 are a pair of openings provided on the left and right sides of the main body 11. The blowout port 15 is provided at the rear side end of the upper surface of the main body 11. The blowout port 15 is an opening for blowing the cleaned air from the air cleaner 1 into the room.
[0024]
The front panel 12 is provided in front of the main body 11 and covers the filter unit 30 installed inside the main body 11. The front panel 12 has a front suction port 16 and a display panel opening 17. The front suction port 16 is a substantially rectangular opening for sucking indoor air provided in a substantially central portion of the front panel 12 into the air cleaner 1. The display panel opening 17 is provided so that a display panel 56 to be described later can be seen from the outside of the casing 10.
[0025]
The blower mechanism 20 sucks room air from each suction port (upper surface suction port 13, side suction port 14, and front suction port 16), and blows out clean air from the blowout port 15. The blower mechanism 20 is provided on the inner side of the casing 10 and is configured such that the indoor air sucked from each suction port passes through the filter unit 30. As shown in FIG. 2, the blower mechanism 20 includes a fan motor 21 and a blower fan 22 that is rotationally driven by the fan motor 21. As the fan motor 21, an inverter motor whose frequency is controlled by an inverter circuit is employed. A centrifugal fan is employed as the blower fan 22.
[0026]
The control unit 50 is configured by a microprocessor. As shown in FIG. 3, the control unit 50 is connected to a ROM 51 for storing control programs and various parameters, a RAM 52 for temporarily storing variables being processed, and the like.
[0027]
In addition, various sensors such as a humidity sensor 53, a temperature sensor 54, and a dust sensor 55 are connected to the control unit 50, and detection signals from the sensors are input. The dust sensor 55 irradiates light into the introduced air, detects the amount of light that reaches the light receiving element by being scattered by the smoke, dust, pollen, and other particles contained in the air, and detects the concentration of particles such as dust Can be measured.
[0028]
Further, a display panel 56 is connected to the control unit 50. The display panel 56 displays an operation mode, monitor information by various sensors, timer information, maintenance information, and the like so that a user or the like can visually check through the display panel opening 17 from the outside. The display panel 56 can be constituted by a liquid crystal display panel, an LED, another display element, or a combination thereof.
[0029]
Furthermore, the control unit 50 is connected to the fan motor 21 and can control the operation of these devices in accordance with user operations, detection results of various sensors, and the like.
[0030]
(Filter unit)
The filter unit 30 is provided inside the casing 10 and removes particulates contained in room air sucked from the suction ports 13, 14, and 16. As shown in FIG. 2, the filter unit 30 includes a prefilter 31, a plasma ionization unit 32, a first photocatalytic filter 33, a second photocatalytic filter 34, and an inverter lamp 35. The filter unit 30 is configured such that the indoor air sucked from each suction port passes through the filter unit 30 in the order of the pre-filter 31, the plasma ionization unit 32, the first photocatalytic filter 33, and the second photocatalytic filter 34.
[0031]
The pre-filter 31 is a filter for removing relatively large dust from the air sucked into the casing 10 by the blower mechanism 20.
[0032]
The plasma ionization unit 32 charges the dust or the like contained in the air after passing through the prefilter 31 by applying a strong charge. This charging increases the collection efficiency of dust and the like in the electrostatic filter of the first photocatalytic filter 33 described later.
[0033]
FIG. 4A shows a side view of the first photocatalytic filter 33, and FIG. 4B shows a front view of the first photocatalytic filter 33. The 1st photocatalyst filter 33 is made into the roll shape which wound the length for several times, and when the surface in use becomes dirty, it is the structure which pulls out and cuts the dirty part. The first photocatalytic filter 33 has a dust collection part 330 and a rubber string 331. The dust collection unit 330 collects particles in the passing air. The rubber cords 331 are a pair of rubber cords provided on the air flow upstream surface and the downstream surface of the dust collection unit 330. In the first photocatalytic filter 33, the rubber cords 331 are provided at three locations, approximately the center in front view and both left and right ends in front view. When the first photocatalytic filter 33 is not used, the rubber string 331 extends so that the dust collecting unit 330 is in an extended state. At this time, the rubber string 331 holds the extended state of the dust collecting unit 330. Moreover, at this time, the dust collection part 330 is wound by the cylindrical shape. In the first photocatalytic filter 33 in use, the rubber string 331 is contracted so that the dust collecting portion 330 has a triangular waveform. At this time, the rubber string 331 holds the triangular waveform forming the dust collection portion and the pitch of the triangular waveform. The pitch of the triangular waveform has a certain length. Further, the triangular waveform of the dust collection unit 330 in use is formed by a fold 332 in the dust collection unit 330. The first photocatalytic filter 33 is formed by laminating an electrostatic filter (not shown) and a photocatalytic filter (not shown). The electrostatic filter is disposed on the upstream side of the air flow by the blower mechanism 20, and the photocatalytic filter is disposed on the downstream side of the air flow. The electrostatic filter adsorbs dust or the like charged by the plasma ionization unit 32. Dust that passes through the electrostatic filter adheres to the photocatalytic filter.
[0034]
The second photocatalytic filter 34 carries titanium oxide having a photocatalytic action. The second photocatalytic filter 34 adsorbs dust and dirt in the air that has not been adsorbed by the first photocatalytic filter 33. The second photocatalyst filter 34 sterilizes mold bacteria and bacteria contained in the adsorbed dust or dust with titanium oxide.
[0035]
The inverter lamp 35 is disposed between the first photocatalytic filter 33 and the second photocatalytic filter 34. This inverter lamp 35 irradiates the photocatalytic filter of the first photocatalytic filter 33 and the second photocatalytic filter 34 with ultraviolet rays, and activates the photocatalytic action of each photocatalytic filter.
[0036]
<Features of this air purifier>
(1)
In the air cleaner 1, the dust collecting unit 330 is formed into a triangular waveform by the rubber cord 331 during use. That is, the first photocatalytic filter 33 has a rubber string 331 having a dust collection portion 330 having a triangular waveform. Therefore, it is not necessary for the user of the air cleaner 1 or the like to perform some work to make the dust collection unit 330 into a triangular waveform. For this reason, in this air cleaner 1, a filter can be installed easily. Further, when the dust collection unit 330 is used, the dust collection unit 330 is formed into a triangular waveform by the rubber string 331. Therefore, the surface area of the dust collection unit 330 that contacts the passing air increases, and the dust collection efficiency is improved. For this reason, in the air cleaner 1, the 1st photocatalyst filter 33 can be installed easily and dust collection efficiency can be improved.
[0037]
(2)
In the air cleaner 1, when the dust collection unit 330 is not used, the dust collection unit 330 is extended by a rubber string 331. Therefore, the first photocatalytic filter 33 can be stored in close contact with no gap. For this reason, in this air cleaner 1, the storage space of the 1st photocatalyst filter 33 can be reduced.
[0038]
(3)
In the air cleaner 1, the corrugated shape of the dust collection unit 330 is held by the rubber string 331 when the dust collection unit 330 is used. That is, the triangular waveform shape of the dust collection unit 330 does not change during the dust collection. Therefore, during the dust collection, the dust collection efficiency in the dust collection unit 330 is kept constant. Further, when the dust collection unit 330 is stored, the stretched state of the dust collection unit 330 is held by the rubber cord 331. That is, the extended state of the dust collecting unit 330 does not change during storage.
[0039]
(4)
In the air cleaner 1, the pitch of the waveform forming the triangular waveform of the dust collecting unit 330 is held by the rubber string 331. For this reason, in this air cleaner 1, the full length of the dust collection part 330 at the time of use can be hold | maintained.
[0040]
(5)
In the air cleaner 1, the dust collection unit 330 has a fold 334 that forms a triangular waveform of the dust collection unit 330. Therefore, for example, when the operator or the like alternately bends the dust collecting portion 330, the fold 334 can be easily manufactured. For this reason, in this air cleaner 1, the 1st photocatalyst filter 33 can be manufactured easily.
[0041]
(6)
In the air cleaner 1, the pitch of the waveform forming the triangular waveform of the dust collection unit 330 is constant. Therefore, the dust collection unit 330 can collect particles in the air uniformly over the entire surface. For this reason, in this air cleaner 1, the surface of the dust collection part 330 is utilized effectively for dust collection of the particle | grains in air.
[0042]
(7)
In the air cleaner 1, the dust collection unit 330 is wound in a cylindrical shape when stored. Therefore, the storage space for the first photocatalytic filter 33 is reduced during storage. For this reason, in this air cleaner 1, the storage space of the 1st photocatalyst filter 33 is further reduced.
[0043]
(8)
In the air cleaner 1, when the dust collection unit 330 is used, the dust collection unit 330 is formed into a triangular waveform by the rubber string 331. Therefore, it is possible to improve the dust collection efficiency of the first photocatalytic filter 33 while keeping the thickness of the first photocatalytic filter 33 constant. Therefore, the resistance of the air passing through the first photocatalytic filter 33 is reduced as compared with the case where the photocatalytic filter having a large thickness is used. For this reason, in this air cleaner 1, the air resistance of the air which passes the 1st photocatalyst filter 33 is reduced.
[0044]
<Other embodiments>
Although the present invention has been described above, the specific configuration is not limited to the above embodiment, and can be changed without departing from the scope of the invention.
[0045]
(A)
In the above-described embodiment, the rubber string 331 is contracted so that the dust collecting unit 330 has a triangular waveform during use. However, the waveform shape of the dust collecting portion of the filter in which the present invention is adopted is not limited to the triangular waveform. For example, the first photocatalytic filter may be the first photocatalytic filter 400 shown in FIG.
[0046]
The 1st photocatalyst filter 400 has the dust collection part 430 and the rubber string 431 (refer FIG. 5). In the first photocatalytic filter 400 in use, the rubber string 431 is contracted so that the dust collecting portion 430 has a sine waveform. At this time, the rubber string 431 holds the sine waveform forming the dust collecting portion and the pitch of the sine waveform. The pitch of this sine waveform is a fixed length. The other components of the first photocatalytic filter 400 have the same configuration as the other components of the first photocatalytic filter 33.
[0047]
Even in the air cleaner having the first photocatalytic filter 400, the dust collector 430 is formed into a sine waveform by the rubber string 431 when the dust collector 430 is used. Accordingly, the surface area of the dust collection portion 430 that contacts the passing air increases, and the dust collection efficiency is improved. For this reason, in this air cleaner, dust collection efficiency can be improved.
[0048]
(B)
In the above embodiment, the rubber string 331 is contracted so that the dust collecting section 330 has a triangular waveform with a constant pitch. However, the waveform pitch of the dust collecting portion of the filter in which the present invention is adopted is not limited to a certain length. For example, the first photocatalytic filter may be the first photocatalytic filter 500 shown in FIG.
[0049]
The first photocatalytic filter 500 includes a dust collecting portion 530 and a rubber string 531 (see FIG. 6). In the first photocatalytic filter 500 in use, the rubber string 531 is contracted so that the dust collecting portion 430 has a triangular waveform. At this time, the rubber string 531 holds the triangular waveform forming the dust collecting portion and the pitch of the triangular waveform. The pitch of the triangular waveform is not a fixed length. Further, the triangular waveform of the dust collection unit 330 in use is formed by the folds 532 of the dust collection unit 530. The other components of the first photocatalytic filter 500 have the same configuration as the other components of the first photocatalytic filter 33.
[0050]
Even in the air cleaner having the first photocatalytic filter 500, when the dust collecting unit 530 is used, the dust collecting unit 530 has a triangular waveform shape with an indefinite pitch by the rubber cord 531. Therefore, the surface area of the dust collection part 530 that contacts the passing air increases, so that the dust collection efficiency is improved. For this reason, in this air cleaner, dust collection efficiency can be improved.
[0051]
(C)
In the above-described embodiment, the dust collection unit 330 is wound in a cylindrical shape when stored. However, the shape of the dust collecting portion during storage is not limited to a cylindrical shape. For example, the first photocatalytic filter may be the first photocatalytic filter 600 shown in FIG.
[0052]
The 1st photocatalyst filter 600 has the dust collection part 630 and the rubber string 631 (refer FIG. 7). When the dust collecting portion 630 is not used, the rubber cord 631 extends by folding the dust collecting portion 630. At this time, the rubber string 631 holds the extended state of the dust collecting portion 630. The other components of the first photocatalytic filter 600 have the same configuration as the other components of the first photocatalytic filter 33.
[0053]
Even in the air purifier having the first photocatalytic filter 600, the dust collecting unit 630 at the time of storage is closely folded. Therefore, the storage space for the first photocatalytic filter 600 is reduced during storage. For this reason, in this air cleaner, the storage space for the first photocatalytic filter 600 is further reduced.
[0054]
(D)
In the above embodiment, the present invention is applied to the first photocatalytic filter 33. Instead of this (in addition), the present invention may be adopted for the pre-filter 31 and the second photocatalytic filter 34.
[0055]
(E)
In the above embodiment, the shape of the dust collecting part is changed and held using a rubber string. Instead of this, the shape of the dust collecting part may be changed and held using another elastic body (spring or the like) excluding the rubber string.
[0056]
(F)
In the said embodiment, although this invention is applied to the air cleaner 1, you may apply this invention to the air conditioner 100 which performs air conditioning as shown in FIG.
[0057]
The air conditioner 100 is a device for supplying conditioned air into a room, and includes an indoor unit 101 attached to a wall surface of the room and an outdoor unit 102 installed outside the room. The indoor unit 101 is provided with a suction port 105 for taking indoor air into the air conditioner 100, and a filter unit (not shown) is provided inside the suction port 105. Even when the present invention is applied to this filter unit, the filter storage space can be reduced and the dust collection efficiency can be improved.
[0058]
【The invention's effect】
As described above, according to the present invention, the following effects can be obtained.
[0059]
In the invention according to claim 1, for example, there is no need to filter the bent state such as the user performs some work. For this reason , installation of a filter becomes easy. Further, at the time of dust collection, the dust collection portion is in a bent state. Therefore, since the area of the surface part which contacts air increases, dust collection efficiency is improved. For this reason, in this filter, it can install easily and dust collection efficiency can be improved. Here, the dust collecting portion is wound in a cylindrical shape when stored. Therefore, the storage space is reduced during storage. For this reason, in this roll filter, the storage space is further reduced.
[0060]
In the invention which concerns on Claim 2 , the dust collection part has the crease | fold which forms a waveform. Therefore, for example, when a worker or the like alternately folds the dust collecting portion, the fold can be easily manufactured. For this reason, in this roll filter, the ease of manufacture improves.
[0061]
In the invention which concerns on Claim 3 , the pitch of the waveform which a dust collection part has is constant. Therefore, the dust collection unit can uniformly collect particles in the air. For this reason, in this roll filter, the entire surface of the dust collecting portion is effectively used for collecting particles in the air.
[0062]
In the invention according to claim 4, for example, there is no need to filter the bent state such as the user performs some work. For this reason, in this air conditioner, it is easy to install the filter. Further, at the time of dust collection, the dust collection portion is in a bent state. Therefore, since the area of the surface part which contacts air increases, dust collection efficiency is improved. Further, here, the dust collecting unit, during storage, is wound into a cylindrical shape. Therefore, the storage space is reduced during storage. For this reason, in this roll filter, the storage space is further reduced.
[Brief description of the drawings]
FIG. 1 is an external view of an air purifier in which an embodiment of the present invention is adopted.
FIG. 2 is an exploded perspective view of a filter unit and a blower mechanism.
FIG. 3 is a schematic block diagram of a control unit.
FIG. 4A is a side view of a first photocatalytic filter.
(B) The front view of a 1st photocatalyst filter.
FIG. 5 is a side view of a first photocatalytic filter in which another embodiment of the present invention is employed.
FIG. 6 is a side view of a first photocatalytic filter in which another embodiment of the present invention is employed.
FIG. 7 is a side view of a first photocatalytic filter in which another embodiment of the present invention is employed.
FIG. 8 is an external view of an air conditioner in which another embodiment of the present invention is employed.
[Explanation of symbols]
1 Air cleaner (air conditioner)
10 Casing 20 Blower mechanism (Blower part)
33, 400, 500, 600 First photocatalytic filter (filter)
100 Air Conditioner 330, 430, 530, 630 Dust Collection Part 331, 431, 531, 631 Rubber String ( Elastic Body )
332, 532 break

Claims (4)

Elastic bodies (331, 431, 531, 631);
A part of the elastic body is fixed at a predetermined interval along the expansion / contraction direction, and when the elastic body is stretched, it becomes a planar shape, and the elastic body from the state of the elastic body when the planar shape is obtained. And a dust collection part (330, 430, 530, 630) that becomes a bent shape when the
The dust collecting portion is wound in a cylindrical shape with the elastic body extended so as to maintain a planar shape.
Roll filter (33, 400, 500, 600). The roll filter (33, 400, 500, 600) according to claim 1 , wherein the dust collecting part (330, 430, 530, 630) has folds (332, 532) forming a waveform. The pitch of the waveform is constant,
The roll filter (33, 400, 500, 600) according to claim 2 . A casing (10);
A blower (20) for sucking air in a predetermined space into the casing (10) and blowing out the air sucked into the casing (10) into the predetermined space;
An air conditioner (1, 100) comprising: the roll filter (33, 400, 500, 600) according to any one of claims 1 to 3 incorporated in the casing (10).

Images