JP2003181276A - Minus ion generator and air conditioner provided with the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a minus ion generator which appropriately controls the amount of generation of minus ion or the amount of irradiation generated from an exciting agent and, further, decreases the pressure loss caused by a mixture of powder having spontaneous polarization and the exciting agent. <P>SOLUTION: The spontaneous polarization filter 10 and an exciting filter 12 are disposed so as to face oppositely and be parallel with each other. Tourmaline 16 is retained as the powder having the spontaneous polarization on a mesh part 14 of the spontaneous polarization filter 10 and the exciting agent 18 is retained on the mesh part 14 of the exciting filter 12. By using such a constitution, the amount of tourmaline 16 and the exciting agent 18 which are retained in the filters can be easily changed. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a negative ion generator and an air conditioner including the negative ion generator.

[0002]

2. Description of the Related Art In recent years, negative ions have attracted attention because they activate physiological effects and have a positive effect on living organisms. Negative ions often occur in forests and waterfalls in the natural world, activate physiological functions of the body and adjust the function of autonomic nerves, and thus have a favorable effect on relief of psychological tension, recovery from fatigue, and deep sleep. This negative ion excites the powder having spontaneous polarization by bringing the powder as an exciter that generates radiation closer to the powder having spontaneous polarization, and the powder having spontaneous polarization thus excited. It originates from the body. Here, Japanese Patent Laid-Open No. 2001-
Japanese Patent No. 17526 discloses an air conditioner in which powder having spontaneous polarization and powder serving as an exciter that excites powder having spontaneous polarization so as to generate negative ions are arranged in a mixed state. , A powder collector having spontaneous polarization and a powder as an exciter are arranged in a mixed state. In addition, Japanese Patent Laid-Open No. 2001-201
Japanese Patent No. 51 discloses a synthetic fiber containing a powder having spontaneous polarization and a powder as an exciter. Further, Japanese Patent Laid-Open No. 2001-20177 discloses a textile fiber in which a powder having spontaneous polarization and a powder as an exciter are applied.

[0003]

In order to generate negative ions in these conventional techniques, it is necessary to mix a powder having spontaneous polarization and a powder as an exciter. At this time, since the powder having the spontaneous polarization and the powder as the exciter have different particle sizes and specific gravities, it is difficult to uniformly mix the powder having the spontaneous polarization and the powder as the exciter. Therefore, the conventional technique has a problem that the amount of negative ions generated or the amount of radiation generated from the exciter cannot be easily and appropriately adjusted.

Further, when these mixtures are applied to an air conditioner or the like, in order to generate a certain amount of negative ions, a mixture of a powder having spontaneous polarization and a powder as an exciter has a predetermined volume. It must be housed and placed tightly inside. Such a filter that holds the mixture that is tightly housed tends to have a large pressure loss, and there is a problem in that it is a great constraint in the design of the air conditioner.

The present invention solves the above problems and can appropriately adjust the amount of negative ions generated or the amount of radiation generated from an exciter, and further, a powder having spontaneous polarization and excitation. An object of the present invention is to provide a negative ion generator and an air conditioner that reduce pressure loss due to a mixture with powder as an agent.

[0006]

In order to solve the above problems, the present invention employs the following means.

The present invention is characterized by comprising a spontaneous polarization member holding a spontaneous polarization agent, and an excitation member holding an excitation agent that excites the spontaneous polarization agent so that negative ions are generated. .

The present invention is characterized in that the spontaneous polarization agent and the excitation agent are powders.

According to the present invention, the spontaneous polarization member and the excitation member are
It is characterized in that they are arranged facing each other.

Since the spontaneous polarization member and the excitation member are arranged so as to face each other, the spontaneous polarization agent and the excitation agent are
They will be held by different members. It is to be noted that the arrangement of facing each other preferably means that the air flows so as to face each other and to be parallel to each other, more specifically, to overlap when the other member is projected in the normal direction of one member. They are installed in series based on the direction. The normal direction and the air flow direction preferably coincide with each other. Therefore, it is not necessary to uniformly mix the powders with each other, which has been considered difficult in the past, and the powders are uniformly held by separate members.

The present invention is characterized in that the spontaneous polarization member and the excitation member are a spontaneous polarization filter and an excitation filter, respectively.

Since the powders are held in the respective filters, the powders having spontaneous polarization and the powders as the stimulant are not mixed but are held in different filters. Further, since the filter is made to hold each powder, negative ions are sequentially supplied to the fluid passing through the filter.

The present invention is characterized in that the spontaneous polarization filters and the excitation filters are provided alternately. It should be noted that the term “alternating arrangement” preferably means arranging toward the upstream side or the downstream side with reference to the air flow direction.

Since the spontaneous polarization filter and the excitation filter are arranged alternately, the amount of powder retained in each filter is increased by increasing the number of the spontaneous polarization filter and the excitation filter alternately installed. The amount of negative ions generated will increase without increasing it. Further, by reducing the number of the spontaneous polarization filter and the excitation filter that are alternately installed, the amount of negative ions generated and the radiation generated from the exciter without reducing the amount of powder retained in the filter. The amount will decrease. As described above, by alternately installing the spontaneous polarization filter and the excitation filter and increasing or decreasing the number of installed filters, the amount of negative ions generated can be easily adjusted.

An air conditioner according to the present invention is characterized by including the negative ion generator according to any one of claims 1 to 5.

Since this air conditioner generates negative ions, the powder having spontaneous polarization and the powder as the exciter are held by different members.
In addition, as the member in the air conditioner, for example, a filter mesh portion, a filter frame, an air filter mesh portion, an air filter frame, or a wall surface of the air outlet can be used. Further, the negative ions are supplied to the room together with the air whose temperature is adjusted by the air conditioner.

The negative ion generator according to the present invention is provided in an indoor unit.

[0018]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below. First, the mechanism of generation of negative ions by the powder of a substance having spontaneous polarization and the powder as an exciter will be outlined. Examples of substances having spontaneous polarization include tourmaline, BaTiO ₃ , PbTiO ₃ , PbZrO ₃ ,
KNbO ₃ , KTaO ₃ , LiNbO ₃ , Rochelle salt,
It is possible to use glycine sulfate, potassium phosphate, calcium strontium propionate and a mixture thereof, or a powder of an ore containing a part thereof, mixed with silica or the like, and then powdered again. Tourmaline is widely used as a spontaneous polarization agent because it has the largest spontaneous polarization, and it is preferable to use tourmaline as the spontaneous polarization agent also in the present invention. Tourmaline is prized as a gemstone, and the pure crystalline mineral is taumarin (T
Oumalin) and is produced all over the world. Tourmaline is polarized into a positive pole and a negative pole, and by forming fine particles, a high electric field is generated from the positive pole to the negative pole. When the radiation emitted from the exciter passes through the inside or the surface of tourmaline, the energy of the radiation excites the tourmaline to generate negative ions.

In order to increase the amount of negative ions generated, (1) increase the amount of substance having spontaneous polarization (tourmaline), (2) increase the amount of radiation emitted from the exciter, (3) ) The emission area may be widened, and (4) the temperature may be increased. However, regarding radiation, the amount of radiation must not be increased excessively in consideration of the effects on the human body.

Further, as the stimulant powder, David ore,
Brunnerite, uranium ore, gingko stone, linkai uranium stone, carnot stone, zamun stone, metachamun stone,
Powders of naturally occurring ores such as francevir stones, tall stones, coffin stones, Samalski stones, thorium stones, trogamstones, and mozna stones, or powders of ore containing some of these into silica etc. It is possible to use a powder that is mixed and sintered and then powdered again.

[First Embodiment] FIG. 1 is a perspective view showing an outline of a first embodiment of the present invention. According to FIG. 1, a plane-shaped spontaneous polarization filter 10 and a plane-shaped excitation filter 1 are shown.
2 are in series so as to face each other and to be parallel to each other, and more specifically, to overlap when the other filter is projected in the normal direction of one filter, with the air flow direction as a reference. is set up. The normal direction and the air flow direction preferably coincide with each other. The mesh portion 14 of the spontaneous polarization filter 10 holds tourmaline 16 as a powder having spontaneous polarization, and the mesh portion 14 of the excitation filter 12 holds an exciter 18. Here, the tourmaline 16 and the exciter 18 shown in the drawing are enlarged for easy understanding, and do not show relative sizes with respect to the filter. Further, the shapes of the tourmaline 16 and the exciting agent 18 are not limited to the spherical shape or the circular shape.

The spontaneous polarization filter 10 holds only the tourmaline 16, and the excitation filter 12 holds only the exciter 18. The tourmaline 16 and the stimulant 18 are (1) a method of making paper at the time of paper making of the filter, (2) a method of fixing the filter on the filter with a binder (the binder is a fiber constituting the filter and a powder to be retained). It is used for physically or chemically fixing the binder, for example, silica gel, polymer emulsion, acrylic, rubber latex, hot melt, etc.),
(3) Since it is held in the filter by a method such as kneading into the filter material, it can be held uniformly on the filter surface. The gap between the spontaneous polarization filter 10 and the excitation filter 12 is 0 to 200 mm, preferably 0 to 40 m.
By setting m, negative ions are generated from the surface of the tourmaline 16 by the radiation generated from the exciter 18. In addition, if the gap between the filters is eliminated,
Apparently, the plurality of filters are configured as a single filter, but such a form can of course be implemented. In this embodiment, since the distance between the tourmaline 16 and the exciter 18 is minimized, the amount of negative ions obtained per unit amount of tourmaline is large. Therefore, tourmaline 1
6 and the amount of the stimulant 18 can be reduced, the material cost and the manufacturing cost can be reduced. On the other hand, if the gap between the filters is widened, the amount of negative ions obtained per unit tourmaline amount decreases, so it is suitable for obtaining a relatively small amount of negative ions. However, since the indoor unit itself of the air conditioner becomes large if the above-mentioned void is expanded too much, the void is preferably 200 mm or less, particularly preferably 40 mm or less. Further, the amount of negative ions obtained can be adjusted by supporting the filter frame in a floating manner and having a structure in which the gap between the two or more filters described above can be adjusted.

As described above, when the tourmaline 16 and the exciter 18 are held in one filter, it is difficult to mix them uniformly before the step of holding them in the filter. On the other hand, it is also difficult to hold it uniformly. However, with the configuration shown in FIG. 1, it is not necessary to mix the tourmaline 16 and the exciter 18. In the configuration of FIG. 1, the filter that holds the tourmaline 16 and the filter that holds the exciter 18 are separate. Further, it becomes possible to design and manufacture the holding amount of the tourmaline 16 and the holding amount of the exciter 18 independently changing each other.

Further, since negative ions are generated, the physiological action of the body is activated and it becomes possible to positively affect the human body such as alleviating psychological tension.

Further, by adding new functions to the spontaneous polarization filter and the excitation filter, respectively,
It is possible to add value to the spontaneous polarization filter and the excitation filter. That is, if one filter is a filter with excellent dust removal function and the other filter is a filter with excellent deodorization function, in addition to the function of generating negative ions, it is possible to manufacture a filter that has both a dust removal function and a deodorization function. It will be possible. It should be noted that if a filter for providing a dust removing function or a deodorizing function is an electrically neutral filter, it is difficult to capture the negative charges, and therefore it is suitable for, for example, efficient emission of negative ions. On the other hand, the use of an electrically positively or negatively charged filter facilitates trapping of negative charges, which is suitable when it is desired to prevent excessive release of negative ions, for example. Further, by changing the charged state, it is possible to adjust the amount of negative ions emitted at any time. As a charged filter, for example, there is a filter having a dust removing function using an electrode to which a DC voltage is applied.

Second Embodiment FIG. 2 is a perspective view showing the outline of the second embodiment of the present invention. According to FIG. 2, the tourmaline 24 is held by the filter frame 20 (spontaneous polarization member), the filter frame 20 holds the mesh portion 14 (excitation member), and the stimulant 26 is held by the mesh portion 14 (excitation member). ing. The filter frame 20 and the mesh portion 14 are arranged so as to face each other. Specifically, the outer peripheral portion of the mesh portion 14 and the filter frame 20 are adjacent to each other, and the filter frame 20 is arranged so as to surround the four sides of the rectangular mesh portion 14. It is also possible to replace the tourmaline 24 and the exciter 26 with each other, and use a filter mesh as the spontaneous polarization member and a filter frame as the excitation member.

As the filter, another filter may be connected and used in the longitudinal direction of the one filter or in the direction orthogonal to this. The members shown in FIGS. 1 and 2 use a rectangular filter, but the shape of the filter is not limited to this and may be a polygon or a circle. It is also possible to use a filter having a filter frame having a large rectangular shape with small holes formed in a honeycomb shape and a filter mesh having the same shape as the large rectangular shape. Although such a filter has a large pressure loss, it can hold the tourmaline 24 and the stimulant 26 in close proximity, and is therefore preferably used when a large amount of negative ions are generated.

According to this embodiment, since the tourmaline 24 and the stimulant 26 are arranged on one filter, these powders are held close to each other.

As described above, in this embodiment, since negative ions are generated from the excited tourmaline, the physiological action of the body is activated, and it is possible to give a favorable effect such as relaxation of psychological tension. Becomes

Further, since the negative ions are generated by only one filter, when the negative ions are generated by using two or more filters, when applying this to an air conditioner, It is possible to reduce the pressure loss due to.

Reducing the pressure loss due to the filter means that the power of the fan can be reduced. Therefore, the fan can be downsized, which contributes to downsizing of the indoor unit of the air conditioner. It also contributes to the reduction of operating power consumption.

Third Embodiment FIG. 3 is a perspective view showing the outline of the third embodiment of the present invention. For convenience of description, FIG. 3 visibly illustrates a part of the internal structure that is originally hidden by the front panel 36 or the like and cannot be seen. Indoor unit 3
0 (indoor unit) is a part of a general air conditioner and is installed indoors. The front panel 36 forming the outer surface of the indoor unit 30 includes a suction grill 36b.
Is formed as a horizontally elongated hole on each of the front surface and the upper surface. The air in the room is the suction grill 36
By b, it is sucked into the indoor unit 30 from multiple directions. An air filter 34 is provided behind the suction grill 36b to remove dust such as sucked air. By removing the dust such as the sucked air, the spontaneous polarization filter 10 and the excitation filter 12, which will be described later, are prevented from being contaminated by the dust, and the negative ion generation is prevented from being hindered. An indoor heat exchanger 32 is installed inside the indoor unit 30 and inside the air filter 34 (on the right side in the drawing). An air outlet 36c is formed below the front panel 36. The air sucked from the suction grill 36b and adjusted in temperature by passing through the indoor heat exchanger 32 is blown out from the air outlet 36 into the room. In FIG. 3, inside the indoor unit 30 (indoor unit), one planar spontaneous polarization filter 10 and one planar excitation filter 12 are provided between the indoor heat exchanger 32 and the air filter 34. They are installed in parallel with each other so that they face each other. The spontaneous polarization filter 10
The excitation filter 12 and the excitation filter 12 may have a configuration in which the positional relationship is reversed.

Spontaneous polarization filter 10 and excitation filter 1
Since No. 2 is installed between the indoor heat exchanger 32 and the air filter 34, the negative ions generated from the spontaneous polarization filter 10 have dust removed by the air filter 34 and are cooled or heated by the indoor heat exchanger 32. Since it is introduced into the room through the outlet 36c together with the heated air, the air environment of the room can be kept comfortable. In addition, when the temperature adjustment of the air is not required, the function of the indoor heat exchanger 32 is stopped, and the operation mode in which the generation of negative ions and the blowing are combined can be used. Further, since the spontaneous polarization filter 10 and the excitation filter 12 are constantly exposed to the flow of air whose temperature is adjusted by the air conditioner, negative ions generated from tourmaline (not shown) retained in the spontaneous polarization filter 10 are generated. Is promptly carried on the air, and untreated air containing no negative ions continues to be sent to the surface of the spontaneous polarization filter 10.

With the configuration shown in FIG. 3, negative ions are emitted from the air outlet 36c of the air conditioner, so that the physiological action of the body is activated and the psychological tension is alleviated. Can be given. Further, since the spontaneous polarization filter 10 and the excitation filter 12 are constantly exposed to the flow of air, air that does not contain negative ions is sequentially sent to the tourmaline surface, so that negative ions continue to be effective. Occurs in.

In the present embodiment, tourmaline for generating negative ions and the exciter (not shown) are held in separate filters, but a plurality of these filters are alternately laminated. It is also possible to install in. In this case, the total amount of tourmaline retained by the filter and the exciter is increased, so that the amount of negative ions generated can be increased. Further, the spontaneous polarization member and the excitation member are not limited to the mesh portion of the filter, and for example, the frame of the filter, the mesh portion of the air filter 34, the frame of the air filter 34,
It is also possible to use the wall surface of the outlet 36c. When these are used, it is not necessary to newly install a dedicated filter as a member for generating negative ions, and the lower pressure loss enables the design and operation of the air conditioner.

[0036]

As described above, the present invention has the following unique effects. In the negative ion generator,
A spontaneous polarization member that holds a spontaneous polarization agent and an excitation member that holds an excitation agent that excites the spontaneous polarization agent so that negative ions are generated can easily change the amount retained in each member. Is possible. Therefore, it becomes possible to easily and appropriately adjust the amount of negative ions generated and the amount of radiation generated from the exciter.

In the negative ion generator, by using the spontaneous polarization agent and the excitation agent in the form of powder, it becomes possible to easily change the amount of powder held on the spontaneous polarization member and the excitation member. Therefore, it becomes possible to easily and appropriately adjust the amount of negative ions generated and the amount of radiation generated from the exciter.

In the negative ion generator, the spontaneous polarization member and the excitation member are arranged to face each other so that the spontaneous polarization agent and the excitation agent are held by the respective members. The amount can be easily changed. Therefore, it becomes possible to easily and appropriately adjust the amount of negative ions generated and the amount of radiation generated from the exciter.

By using the spontaneous polarization filter and the excitation filter in the negative ion generator, the powder having the spontaneous polarization and the powder as the exciter are uniformly held in each filter. Therefore, as compared with the case where the mixture of the powder having the spontaneous polarization and the powder as the exciter is held in one filter, the powder having the spontaneous polarization is uniformly held, and the powder as the exciter is also uniform. Therefore, the pressure loss caused by the filter can be reduced.

In the negative ion generator, the spontaneous polarization filter and the excitation filter are alternately provided to increase or decrease the number of these filters to be installed to generate the negative ions and the exciter. It becomes possible to adjust the radiation dose easily and appropriately.

With the air conditioner equipped with the negative ion generator according to the present invention, the amount of negative ions generated or the amount of radiation generated from the exciter can be adjusted appropriately. Furthermore, it becomes possible to provide an air conditioner capable of reducing the pressure loss due to the mixture of the powder having spontaneous polarization and the powder as the exciter.

[Brief description of drawings]

FIG. 1 is a perspective view showing a negative ion generator according to a first embodiment of the present invention.

FIG. 2 is a perspective view showing a negative ion generator according to a second embodiment of the present invention.

FIG. 3 is a perspective view showing an external appearance and an internal structure of an air conditioner according to a third embodiment of the present invention.

[Explanation of symbols]

10 Spontaneous polarization filter 12 Excitation filter 14, 22 mesh part 16,24 Tourmaline 18, 26 Exciting agent 20 Filter frame 30 indoor units 32 Indoor heat exchanger 34 Air filter 36 Front panel 36b Suction grill 36c outlet

Claims (7)

[Claims] 1. A spontaneous polarization member that holds a spontaneous polarization agent,
An anion generator, comprising: an excitation member that holds an exciter that excites the spontaneous polarization agent so that negative ions are generated. 2. The negative ion generator according to claim 1, wherein the spontaneous polarization agent and the excitation agent are powders. 3. The negative ion generator according to claim 1, wherein the spontaneous polarization member and the excitation member are arranged to face each other. 4. The negative ion generator according to claim 1, wherein the spontaneous polarization member and the excitation member are a spontaneous polarization filter and an excitation filter, respectively. 5. The negative ion generator according to claim 4, wherein the spontaneous polarization filter and the excitation filter are provided alternately. 6. An air conditioner comprising the anion generator according to any one of claims 1 to 5. 7. The air conditioner according to claim 6, wherein the negative ion generator is provided in an indoor unit.