JP3046795B2 - Building with comfortable indoor environment functions - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION The present invention relates to a composite ceramic obtained by mixing a plurality of ceramics, laying the composite ceramics in a pit under the floor, and sending air in contact with the composite ceramics to each room, so that the ceramics can be constantly used throughout the seasons. While maintaining a comfortable room temperature, it prevents the generation of general viable bacteria and mold, keeps sanitary pests such as fleas and ticks away, and further prevents the occurrence of dew condensation, as well as the odor of body odors, foodstuffs, tobacco, etc. Deodorizing daily odors and generating a large amount of negative ions in the air-supplied room to give the occupants a static and inhibitory effect to maintain the mental state in the best condition and obtain a comfortable indoor environment The present invention relates to a building having a comfortable indoor environment function.

[0002]

2. Description of the Related Art Heretofore, there has been no building having a comfortable indoor environment function using composite ceramics obtained by mixing a plurality of ceramics.

[0003]

Judging from the current structure of buildings such as houses and buildings and the materials of interior materials, it is not possible to maintain a comfortable room temperature throughout the season in the indoor environment. It does not prevent the generation of viable bacteria and mold, does not attract sanitary pests such as fleas and ticks, and cannot prevent the occurrence of dew condensation.It also deodorizes body odors, daily odors such as food and tobacco odors. In addition, if the amount of moisture in the air is low in the room, negative ions are not generated or the number of generated ions is small, so the mental state of the occupants in the room is kept in the best condition There was a problem that it was not possible.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned conventional problems. The present invention always keeps a comfortable room temperature throughout the four seasons, prevents the generation of general viable bacteria and mold, and attracts sanitary pests such as fleas and mites. In addition, deodorization is further prevented, and at the same time, daily odors such as body odor, food, and tobacco odors are deodorized.
In addition, a comfortable indoor environment function is provided in which the amount of moisture in the air in the room generates at least a large amount of negative ions to maintain the mental state of the occupant in the best state and obtain a comfortable indoor environment. It is intended to provide a equipped building.

[0005]

SUMMARY OF THE INVENTION The present invention is based on amphibole as a base material, and as a mixture, serpentine, quartz diorite, granite, phyllite, tuff, calcium oxide, magnesia and Among the ceramics of silica, composite ceramics obtained by mixing three or five types of ceramics are laid in the underfloor pits, and an air conditioner and air in contact with the composite ceramics in the underfloor pits. An air supply member that supplies air to each floor chamber and an outside air intake duct that introduces outside air to the underfloor pit are provided, and each floor chamber and each floor room are provided with a floor plate and a passage provided for ventilation. Means of sending air through the air port, using serpentine as a base material,
Among the ceramics, granite porphyry, phyllite, tuff, magnesia, silica and limestone
Alternatively, a composite ceramic obtained by mixing five types of ceramics is laid in the underfloor pit, and an air conditioner is supplied to the underfloor pit, and air is supplied from the underfloor pit to the respective floor chambers. An air intake duct for introducing outside air to the air member and the underfloor pit, and air is supplied from each of the floor chambers to each of the floor rooms through an air supply port provided on each of the floor plates and a wall provided with a ventilation passage. In the underfloor pit, the base material, amphibole 20 to 30% by weight,
As a mixed material, a composite ceramic obtained by mixing 20 to 30% by weight of quartz diorite, 20 to 30% by weight of calcium oxide and 20 to 30% by weight of magnesia is spread, and an air conditioner is installed in the underfloor pit and the underfloor. The pit includes an air supply member for supplying air contacting the composite ceramics to each floor chamber and an outside air intake duct for introducing outside air to the underfloor pit, and each floor plate and a ventilation passage from each floor chamber to each floor room. Means for supplying air through the air supply ports provided on the wall surface provided with the following. In the underfloor pit, the granite porphyry stone 5 to 15 as a mixed material with respect to the serpentine 40 to 60% by weight as the base material weight%,
A composite ceramic obtained by mixing 5 to 15% by weight of phyllite, 5 to 15% by weight of tuff, 5 to 15% by weight of silica and 5 to 15% by weight of limestone is laid, and air conditioning is applied to the underfloor pit. Machine, an air supply member for feeding air contacting the composite ceramics in the underfloor pit to each floor chamber and an outside air intake duct for introducing outside air to the underfloor pit, and each floor from the floor chamber to each floor room. A means for supplying air through air supply ports provided respectively on a floor plate and a wall provided with a passage for ventilation. In the underfloor pit, magnesia 20 is used as a mixed material with respect to 20 to 30% by weight of the base material serpentine. And 30% by weight of silica, 20-30% by weight of silica and 20-30% by weight of limestone, and the underfloor pit is air-conditioned. And an air supply member for feeding air contacting the composite ceramics to the respective floor chambers in the underfloor pit and an outside air intake duct for introducing outside air to the underfloor pit, and each floor plate from each floor chamber to each floor room. And means for supplying air through an air supply port provided on a wall provided with a ventilation passage,
In the underfloor pit, as a mixed material, 5 to 15% by weight of phyllite, 5% to tuff 5
A composite ceramic obtained by mixing 15% by weight, 5 to 15% by weight of calcium oxide, 5 to 15% by weight of magnesia and 5 to 15% by weight of silica is spread, and an air conditioner is provided in the underfloor pit and the underfloor pit is provided. An air supply member for feeding air contacting the composite ceramics to each floor chamber and an outside air intake duct for introducing outside air to the underfloor pit, and each floor plate and a passage for ventilation are provided from each floor chamber to each floor room. Means for supplying air through air supply ports provided on each of the provided wall surfaces. In the underfloor pit, 20-30% by weight of serpentine as a mixed material with respect to 20-30% by weight of amphibole as a base material; While laying a composite ceramic obtained by mixing 20 to 30% by weight of quartz diorite and 20 to 30% by weight of granite,
The underfloor pit has an air conditioner, an air supply member that supplies air that has contacted the composite ceramics in the underfloor pit to each floor chamber, and an outside air intake duct that introduces outside air to the underfloor pit. The above-mentioned problem has been solved by adopting one of means for sending air to each floor room through an air supply port provided on each floor plate and a wall surface provided with a ventilation passage.

[0006]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention is based on amphibole as a base material.
It was obtained by mixing 3 or 5 types of ceramics of serpentine, quartz diorite, granite, granite, phyllite, tuff, calcium oxide, magnesia and silica. Using a composite ceramic or serpentine as a base material and mixing it with 3 or 5 ceramics of granite porphyry, phyllite, tuff, magnesia, silica and limestone as a mixture A building having a comfortable indoor environment function in which the obtained composite ceramics are laid in the underfloor pit and air that comes in contact with the composite ceramics is sent into each room, the present invention will be described in further detail below. .

[0007] Single-component ceramics are optimal in all of the far-infrared emissivity, antibacterial rate, deodorizing rate and fungicide resistance, repelling rate and thermal conductivity showing the repelling effect of preventing sanitary pests such as fleas and mites from approaching. Is not present, but preferred ones are present in any of the above.

The inventor of the present invention individually measured far-infrared ray emissivity, antibacterial rate, deodorization rate, mold resistance, repellent rate, and thermal conductivity of a single-component ceramic, and measured the radiation distance of each ceramic. By infrared chemical reaction,
We thought that many negative ions might be generated based on the Leonard effect, and measured the number of negative ions generated by allowing each single component ceramic to stand in the room,
Suitable for any of far-infrared emissivity, antibacterial rate, deodorization rate, anti-mold resistance, repellency and thermal conductivity, and ability to contribute to the generation of negative ions even when the amount of water contained in the air is low The optimal one was extracted. And, by mixing 3 or 5 types of ceramics at a fixed ratio among the above ceramics, it has far-infrared radiation characteristics that can be employed in the present invention, and has antibacterial properties, deodorization properties, antifungal properties, and repellent effects. In addition, a composite ceramic having favorable thermal conductivity, contributing to the generation of negative ions even with a lower water content, and increasing the number of generated negative ions was obtained.

Table 1 shows the measurement results of the far-infrared emissivity, antibacterial rate, deodorizing rate, mold resistance, repellent rate and thermal conductivity of each single component ceramic constituting the composite ceramics which can be employed in the present invention. Show. Each ceramic 50 was placed in a 6 tatami room with a water content of 4 g / m ^3.
g and the amount of water were 7 g / m ^3, and 75 g of each ceramic was allowed to stand in a 6-tatami room, and the number of negative ions generated based on the Leonard effect and the surface area per 1 g of each ceramic were measured. It is shown in FIG. Table 3 is a table showing the results of measuring the number of negative ions generated based on the Leonard effect when the amount of water in a room of 6 tatami mats where the ceramics were not allowed to stand was 4 g / m ³ and 7 g / m ³ , respectively. , For comparison with Table 2.
Each ceramic has an average particle size of 10 to 100 m.
These were mixed as m and then measured for each of the above items. The anti-mold resistance was measured according to JIS Z2911, and the number of negative ions was measured using a negative ion meter.

[0010]

[Table 1]

[0011]

[Table 2]

[0012]

[Table 3]

From the measurement results in Table 1, the far-infrared emissivity of each ceramic is 80% for the lowest tuff, and 83 to 96% for all other ceramics, indicating that the far-infrared emissivity is extremely high. understood. The antibacterial rate against Escherichia coli was 98% for magnesia and 85% for calcium oxide.
%, While granite porphyry has 70%,
Quartz diorite and phyllite have a medium antibacterial rate of 65% and serpentine have a moderate antibacterial rate of 55%, while other ceramics have
The antibacterial rate is 35%, 0% or low, while the antibacterial rate against staphylococci is 9% for serpentine.
9%, magnesia 97%, calcium oxide 95%,
Amphibole has a high antibacterial rate of 83%, while phyllite has a high antibacterial rate of 73%, granite porphyry 67%, and quartz diorite 65%. 0 to
It was found that the antibacterial rate was 35%, 0%, or only a low antibacterial rate.

The deodorization rate for ammonia is 99% for tuff and 95% for silica, which are high, whereas phyllite is 65%, limestone is 60% and amphibolite is 50%.
%, While other ceramics have a low deodorization rate of 20-45%, while the deodorization rate for hydrogen sulfide is as high as 99% for serpentine and silica and 80% for tuff. While the deodorization rate is high, 70
%, Amphibole 63%, quartz diorite 57%, granite and limestone have a moderate deodorization rate of 50%, while other ceramics have a low deodorization rate of 35%. .

Furthermore, the antifungal resistance of serpentine and magnesia was the highest at 3, while amphibolite, quartz diorite, granite, phyllite, calcium oxide, silica and limestone were 2 at the highest. It has a moderate antifungal resistance, but the tuff is 1 and has almost no antifungal resistance. Moreover, the repellent rate showing the repellent effect of repelling sanitary pests such as fleas and ticks was in the range of 75 to 92% for all ceramics, indicating that the repellent rate was extremely high. Further, the thermal conductivity indicating the thermal conductivity is 0.7 to 1.2 Cal / cm · sec ·
° C.

Further, according to Table 2, the indoor water content is 4
Even if it is as low as g / m ³ , the moisture in the air is charged based on the Leonard effect due to the far-infrared chemical reaction radiated by each ceramics placed indoors, generating many negative ions, and generating The number is 2,500 amphibole per cm ^{3 the} highest, and 1,450 the lowest tuff,
Other ceramics were found to generate an extremely large number of negative ions in the range of 1,700 to 2,300. It was also found that more negative ions were generated when the indoor water content was 7 g / m ³ . That is, from Table 2, each of the ceramics has a large surface area per gram and is porous, and therefore has a large contact area with air. Therefore, air in contact with each of the ceramics can have much far-infrared radiation characteristics. It can contribute to the generation of negative ions. On the other hand, in the room without ceramics shown in Table 3, the water content was 4 g /
No negative ions are generated at m ³ , but when the water content is 7 g / m ³ , one negative ion is generated due to the Leonard effect.
It was found that 100 were generated per cm ³ . Therefore, it was found from the measurement results in Table 2 that a large amount of negative ions were generated by the chemical reaction of the far infrared rays emitted from each ceramic based on the Leonard effect even when the amount of moisture in the air was small.

On the basis of the above measurement results, the present inventor has recognized that the ceramics of a single component have a remarkable effect on the antibacterial property and the like by mixing each of the above ceramics at a predetermined ratio of 3 or 5 to form a composite ceramic. It is thought that those which could not be obtained may show high numerical values, and the far-infrared emissivity, antibacterial rate, deodorizing rate, and mold prevention of the composite ceramics obtained by mixing the various ceramics at various mixing ratios Resistance, repellency, and thermal conductivity were measured, and each composite ceramic was allowed to stand in a room to measure the number of negative ions generated for comparison.

As a result of the above examination, it was found that the preferred numerical values of the far-infrared emissivity, antibacterial rate, deodorization rate, mold resistance, repellency, thermal conductivity, and the number of negative ions generated based on the Leonard effect were obtained. The indicated amphibolite or serpentine is used as a base material. For the amphibolite or serpentine as a base material, serpentine (a mixed material when amphibolite is the base material) and quartz diorite are used as a mixture. By adding and mixing 3 or 5 types of stone, granite, phyllite, tuff, calcium oxide, magnesia, silica and limestone, far-infrared emissivity, antibacterial rate, deodorization rate, mold resistance It was found that a composite ceramic exhibiting a suitable numerical value in terms of the number of negative ions generated based on the repellency, thermal conductivity, and Leonard effect was obtained.

That is, when quartz diorite, calcium oxide and magnesia are mixed as a mixture with the amphibolite as a base material, the mixing ratio is 20 to 30% by weight of amphibolite and 20 to 30% by weight of quartz diorite. %, Calcium oxide 2
The content is preferably 0 to 30% by weight and magnesia 20 to 30% by weight, particularly preferably 25% by weight of amphibole, 25% by weight of quartz diorite, 25% by weight of calcium oxide and 25% by weight of magnesia. When granite porphyry, phyllite, tuff, silica and limestone are mixed as a mixture with the base material serpentine, the mixing ratio is 40-60% by weight serpentine, granite. Porphyry 5-15% by weight,
It is preferably 5 to 15% by weight of phyllite, 5 to 15% by weight of tuff, 5 to 15% by weight of silica, and 5 to 15% by weight of limestone, particularly preferably 50% by weight of serpentine and granite porphyry. 10
% By weight, phyllite 10% by weight, tuff 10% by weight, silica 10% by weight, limestone 10% by weight,
Further, when magnesia, silica and limestone are mixed as a mixture with the serpentine as a base material, the mixing ratio is 20 to 30% by weight of serpentine, 20 to 30% by weight of magnesia, 20 to 30% by weight of silica, Limestone 20-30% by weight
It is particularly preferable to use 25% by weight of serpentine, 25% by weight of magnesia, 25% by weight of silica, and 25% by weight of limestone. When phyllite, tuff, calcium oxide, magnesia and silica are mixed, the mixing ratio is 40-60% by weight of amphibole, 5-15% by weight of phyllite, 5-15% by weight of tuff, oxidized It is preferably 5 to 15% by weight of calcium, 5 to 15% by weight of magnesia, and 5 to 15% by weight of silica, and particularly preferably 50% by weight of amphibole, 10% by weight of phyllite, 10% by weight of tuff, and oxidation. It is recommended to use 10% by weight of calcium, 10% by weight of magnesia, and 10% by weight of silica. Further, serpentine, quartz diorite and granite are mixed with the amphibole as a base material. If Amphibole 20 to 30 and the mixture ratio
Wt%, serpentine 20-30 wt%, quartz diorite 20-3
It is preferably 0% by weight and 20 to 30% by weight of granite, particularly preferably 25% by weight of amphibolite, 25% by weight of serpentine, 25% by weight of quartz diorite and 25% by weight of granite. It is recommended that

The far-infrared ray emissivity, antibacterial rate, deodorizing rate, and the like of the composite ceramics obtained by mixing the single-component ceramics constituting the composite ceramics used in the present invention at a particularly preferable mixing ratio shown in Table 4 are shown. Mold resistance,
Table 5 shows the measurement results (characteristics of the composite ceramics) for the repellency and the thermal conductivity. In addition, the water content was 4 g /
m ³ and the 6-mat of each composite ceramic 50g indoors, and the water content on standing 7 g / m ³ and the 6 tatami in the room each composite ceramic 75g respectively, and the number of generated negative ions based on Leonard effect , Each composite ceramics 1
Table 6 shows the results of measuring the surface area per g. The composite ceramics A to E in Tables 5 and 6 were used.
Corresponds to the composite ceramics A to E in Table 4.

[0021]

[Table 4]

[0022]

[Table 5]

[0023]

[Table 6]

From the measurement results in Tables 5 and 6, the composite ceramics had a far-infrared ray emissivity of 92 to 95%, an antibacterial rate against Escherichia coli of 95 to 97%, and an antibacterial rate against staphylococci 93 to 98%. , The deodorization rate for ammonia is 94 to 96%, and the deodorization rate for hydrogen sulfide is 93 to 96.
%, The highest antifungal resistance is 3, the repellency against sanitary pests is high at 94 to 96%, and the heat conductivity is 0.1%.
7 to 0.9 Cal / cm · sec · ° C., a lower value of thermal conductivity than ceramics of a single component, and the number of anions generated based on the Leonard effect is 1 cm at a water content of 4 g / m ³ . 1,150 to 2,35 per ³
0 indicates a high value, and 1 cm at a water content of 7 g / m ³ .
^A higher value was shown at 1,300 to 2,450 pieces per ³ pieces. That is, from Table 6, each of the composite ceramics is 1
Since the surface area per g is large and porous, and therefore the contact area with air is large, air in contact with each of the composite ceramics can have much far-infrared radiation characteristics and contribute to the generation of negative ions. It is doing. From the above, each of the composite ceramics has far-infrared radiation properties, is excellent in antibacterial properties and deodorization properties, is excellent in mold resistance and insect repellency, and has more favorable thermal conductivity, and is radiated from the composite ceramics. It has been found that many negative ions are generated by the chemical reaction of far infrared rays based on the Leonard effect.

Generally, the water content in the air is approximately 7 g / m
^The phenomenon that negative ions are generated due to the charging of moisture when it reaches about ³ is called the Leonard phenomenon.However, the composite ceramics used in the present invention produces a photosensitivity phenomenon due to the far infrared rays emitted, and the action of this photosensitivity phenomenon causes Even when the amount of water in the air is about 4 g / m ³ , the water is charged to generate negative ions and the number of generated negative ions increases. That is, the far infrared rays contribute to the generation of negative ions.

The antibacterial mechanism of each of the composite ceramics is that the surface layer (wall) of general living bacteria such as Escherichia coli and staphylococci is negative ions, and therefore, in the neutral region (pH 7.0 to 7.5). Can only inhabit,
Each of the composite ceramics generates positive ions by far-infrared radiation, so that the cells (walls), which are negative ions, are destroyed by the positive ions, and at the same time, the bacterial proteins are denatured and become difficult to breathe and die. It is.

The deodorizing mechanism of each composite ceramics against ammonia and hydrogen sulfide is not a general effect such as physical adsorption or chemical adsorption, but is not saturated because of a decomposition effect based on far-infrared radiation. Like power, it has deodorizing power semi-permanently. Further, each of the composite ceramics has no toxicity.

The positive ions generated by the far-infrared radiation of each of the composite ceramics have a repellent effect on sanitary pests such as fleas and mites. Furthermore, the positive ions prevent the growth or growth of fungi, thereby fulfilling the function of preventing fungi.

According to the present invention, the composite ceramics are laid in an underfloor pit provided under the floor of a building, and air is sent over the laid composite ceramics to bring air into contact with the composite ceramics and then force air. Air is sent to each room by convection or natural convection, and each room is cooled / heated, ventilated or dehumidified, and the generation of general viable bacteria and mold in each room is prevented by the far-infrared radiation characteristics of the composite ceramics. To keep out pests, prevent dew condensation, deodorize body odors, daily odors such as food and tobacco odors, and generate more negative ions to stabilize the mental state of occupants. It is intended to provide a building having a comfortable indoor environment function. The details will be described below with reference to the drawings.

In the drawing, a general residential house is displayed as a building. FIG. 1 is a vertical cross-sectional view schematically showing the entire structure, in which a house body 1 is provided with an outer fabric base 3 on a ground 2 constructed above, and a ground 2 surrounded by the outer fabric base 3. On the upper side, as shown in FIG. 2, a predetermined inner cloth foundation 4 is provided with a ventilation opening 5 so that air circulates in the whole area surrounded by the outer circling cloth foundation 3, and concrete is further placed on the ground 2. Concrete floor surface 6
The composite ceramics 7 is laid on the concrete floor 6 while being insulated from the ground 2 surface. In addition,
It is recommended that a heat insulating material 8 such as polyurethane is preferably provided on the inner wall surface of the outer turning fabric base 3. The particle size of the composite ceramics 7 does not need to be particularly limited, but it is recommended to use one having a particle size of about 10 to 100 mm.

The outer cloth foundation 3 provided on the ground 2
And the house main body 1 is constructed on the inner cloth foundation 4. Although FIG. 1 shows a two-story building, the building may be a three-story building or a one-story building. The following description is based on the assumption that the present invention is applied to a two-story building according to the drawings.

A shielding plate 9 for shielding the space surrounded by the outer turning fabric base 3 is fixedly provided on the upper surface of the outer turning fabric foundation 3 and the inner cloth foundation 4. The shielding plate 9, the outer turning fabric base 3 and the concrete floor surface are provided. The space formed by 6 is a pit 10 under the floor.

On the shielding board 9 of the underfloor pit 10, a first-floor floor board 11 is fixedly provided with an interval, and a first-floor chamber 12 is formed between the shielding board 9 and the first-floor floor board 11. ,
A first-floor space 14 is constructed between the first-floor floor panel 11 and the first-floor ceiling panel 13, and a second-floor floor panel 15 is provided on the first-floor ceiling panel 13 provided on the first-floor space 14 with an interval. Fixed
A second-floor chamber 16 is formed between the first-floor ceiling plate 13 and the second-floor floor plate 15, and the second-floor floor plate 15 and the second-floor ceiling plate 1 are formed.
A second floor space 18 is constructed between the seven.

Inside the outer wall material 19 of the house body 1,
Between the first floor board 11 and the first ceiling board 13 and the second floor boards 15 and 2
Air-conditioning walls 20 for internal ventilation are provided at intervals between the floor ceiling plates 17, and a heat insulating material 21 made of polyurethane or the like is integrally fixed to the inner wall surface of the outer wall material 19, and the heat insulation is performed. An internal ventilation passage 22 is formed between the member 21 and the internal ventilation air conditioning wall 20. There are two types of the air-conditioning wall 20 for internal ventilation, the air-conditioning wall 20a for the first floor in the first floor and the air-conditioning wall 20b for the second floor in the second floor.

The first floor space 14 and the second floor space 1
The partition wall 23, which partitions the air conditioning wall 8 and forms the rooms R1 and R2, is provided with a heat insulating material 24 such as polyurethane at the center, and has a space on both side surfaces thereof so that the air-conditioning wall 2 for ventilation on both sides can be formed.
5 is provided, and a double-sided ventilation passage 26 is provided between the heat insulating material 24 and the double-sided ventilation air-conditioning wall 25, and a joint between the double-sided ventilation passage 26 and the internal ventilation passage 22 is opened. The passages 22 and 26 are formed continuously so that air can flow between the two passages 22 and 26. And the partition wall 2
Reference numeral 3 denotes a first-floor partition wall 23a that partitions the space 14 on the first floor and a second-floor partition wall 23b that partitions the space 18 on the second floor. The installation locations and numbers of the partition walls 23a and 23b are appropriately combined depending on the position and number of the rooms.

On the other hand, the outer turning fabric base 3 forming the underfloor pit 10 is provided with an electric damper 27 for introducing outside air into the underfloor pit 10 or exhausting air from the underfloor pit 10. A plurality of ventilation openings 28 are provided, and an outside air intake duct 29 for forcibly sucking outside air into the underfloor pit 10 is provided through the outside turning fabric base 3, and the outside air intake duct 29 An electric fan 30 is attached to an air supply port located in the underfloor pit 10. Instead of the underfloor ventilation port 28 having the electric damper 27, a ventilation port that is automatically opened and closed by a temperature sensor made of bimetal or a ventilation port that is manually opened and closed may be used.

The outside air intake duct 2 of the underfloor pit 10
9, an air conditioner 31 for both cooling and heating is installed at an interval downstream from the air inlet of
The air blown to the underfloor pit 10 is cooled or heated by the electric fan 30 provided in the underpowder 9, the air is forced into the underfloor pit 10, and the air is brought into contact with the composite ceramics 7. Have been. In addition, 31 a in the figure is an outdoor unit of the air conditioner 31.

The air conditioner 3 of the underfloor pit 10
1, a first-floor chamber air supply member 32 and a second-floor floor chamber air supply member 33 for supplying air from the underfloor pit 10 to the first-floor floor chamber 12 and the second-floor floor chamber 16 are provided. Each is installed. The air supply members 32 and 33 are separated from the air conditioner 31 so that the air discharged from the air conditioner 31 sufficiently contacts the composite ceramics 7 and then is drawn into the air supply members 32 and 33. It is installed in a position.

The first-floor chamber air supply member 32 is provided with an intake duct 3 installed horizontally on the downstream side of the air conditioner 31.
4 is a blower duct 35 whose lower end is connected and connected at a right angle,
The shield plate 9 is penetrated and the upper end thereof is opened to the first floor chamber 12. Further, an electric fan 36 is provided at an end of the air intake duct 34 on the side of the air conditioner 31. Electric dampers 37 and 38 are provided and formed at the downstream side and the opposite end of the electric fan 36 respectively.

The second floor floor chamber air supply member 33 includes:
A ventilation duct 40 whose lower end is connected at right angles to an air intake duct 39 installed horizontally on the downstream side of the air conditioner 31.
Are the shielding plate 9, the first floor plate 11 and the first floor ceiling plate 13.
And the upper end thereof is on the second floor floor chamber 16.
An electric fan 41 is provided at an end of the air intake duct 39 on the air conditioner 31 side.
On the downstream side of the electric fan 41 of the intake duct 39 and on the opposite end thereof, electric dampers 42 and 43 are provided and formed, respectively.

Since the air duct 40 of the air supply member 33 on the second floor chamber penetrates the first floor space 14, it is covered with a blind plate 44 to reduce the difficulty of viewing, or another pipe space such as a drain pipe is used. It is preferable to use and install.

The first floor plate 11 is provided with a plurality of air inlets 45 for supplying air from the first floor chamber 12 to the room R 1 on the first floor, and is installed on the first floor plate 11. A plurality of communication ports 46 for supplying air into the two-sided ventilation passage 26 of the first floor partition wall 23a are formed in the first floor plate 11. In addition, an air supply port for supplying air supplied into the double-sided ventilation passage 26 through the communication port 46 into the room R1 on the first floor is provided above the first floor partition wall 23a. 47
Are formed.

On the second floor board 15, a room R2 on the second floor is provided.
Air inlet 48 for supplying air from the second floor chamber 16
Are formed, and a plurality of communication ports 49 are formed in the second-floor floor plate 15 to supply air into the two-sided ventilation passage 26 of the second-floor partition wall 23b installed on the second-floor floor plate 15. . In the upper part of the second-floor partition wall 23b, an air supply port 50 for supplying air supplied into the double-sided ventilation passage 26 through the communication port 49 into the room R2 on the second floor.
Are formed.

The inside ventilation passage 22 of the first-floor ventilation air-conditioning wall 20a provided between the first-floor floor panel 11 and the first-floor ceiling panel 13
A plurality of communication ports 51 for supplying air from the first floor chamber 12 are formed in the first floor board 11, and the communication ports 51 are provided above the ventilation air conditioning wall 20 a in the first floor. The air blown into the internal ventilation passage 22 through the
A plurality of air supply ports 52 for supplying air into the room R1 on the floor are formed.

The ventilation passage 2 in the second floor ventilation air-conditioning wall 20b provided between the second floor plate 15 and the second ceiling plate 17 is provided.
2, a plurality of communication ports 53 for supplying air from the second floor chamber 16 are formed in the second floor plate 15,
An air inlet for blowing the air blown into the inner ventilation passage 22 through the communication port 53 into the room R2 on the second floor is provided above the second-floor ventilation air-conditioning wall 20b. 54 are formed.

Of the above members, each electric damper 27
37, 38, 42, 43, each electric fan 30, 36, 4
The air conditioner 1 and the air conditioner 31 are configured so that the operation and stop thereof can be set by a control panel (not shown) installed at a predetermined location in the house 1.

The operation of the apparatus of the present invention having the above-described structure will be described. FIG. 3 is a ventilation system diagram showing a cooling operation in a summer period of 28 ° C. or more, FIG. 4 is a ventilation system diagram showing a heating operation in a winter period of 15 ° C. or less, FIG. 5 is an air supply system diagram in an intermediate period of less than 28 ° C., and FIG. 6 is an air supply system diagram in an intermediate period of 28 ° C. or more. If the air conditioner and the electric fan in FIGS. 3 to 6 are not shaded, they indicate the operation time, and the hatched ones indicate the stop time. Further, when the electric damper is displayed with a white circle, it indicates that the electric damper is open, and when it is displayed with a black circle, it indicates when it is closed.

First, the operating state of each member during cooling in the summer time of 28 ° C. or higher will be described with reference to FIG. 3. The air conditioner 31 of the underfloor pit 10 performs cooling operation, and the electric fan 30 of the outside air intake duct 29 and the first floor. Floor chamber air supply member 3
The electric fans 36 and 41 of the second and second floor chamber air supply members 33 operate, and the electric fans 36 and 4 also operate.
The first electric dampers 37 and 42 on the downstream side are opened. Then, the electric dampers 38 and 43 located on the opposite side to the electric fans 36 and 41 and the electric damper 27 of the underfloor ventilation opening 28 are closed.

The outside air forcedly introduced into the underfloor pit 10 from the outside air intake duct 29 via the electric fan 30 is sent to the air-conditioning unit 31 which is operating for cooling, cooled and cooled. Exhausted from 31. Then, the exhausted cooling air comes into contact with the composite ceramics 7 spread in the underfloor pit 10.

Since the composite ceramics 7 has a small specific heat, a large heat capacity, and a low thermal conductivity, it absorbs heat from the cooled air, and the air is further cooled and flows through the underfloor pits 10 to form the air conditioning. By the electric fans 36 and 41 of the first-floor chamber air supply member 32 and the second-floor chamber air supply member 33 installed at a position distant from the machine 31, the cooled air passes through the intake duct 34 and the blow duct 35. The air is sent to the first floor chamber 12 via forced convection via the intake duct 39 and the air duct 40, and is also sent to the second floor chamber 16 via the forced convection.

The cooled air supplied to the first floor chamber 12 is supplied to the air supply port 4 provided in the first floor plate 11.
5, the air is supplied to the room R1 on the first floor via the air supply port 47 provided in the first-floor partition wall 23a and the air supply port 52 of the internal ventilation passage 22 of the air-conditioning wall for internal ventilation 20a and cooled. I do.

The cooled air supplied to the second floor chamber 16 is supplied to the air supply port 4 provided in the second floor plate 15.
8, the air vents 50 and 2 provided on the second-floor partition wall 23b
Air supply port 5 of internal ventilation passage 22 of floor air-conditioning wall 20b
The air is supplied to the room R2 on the second floor via the cooling unit 4 for cooling.

Next, the operating state of each member during heating in winter at 15 ° C. or less will be described with reference to FIG.
1 performs heating operation, the electric fan 30 of the outside air intake duct 29 operates, and the first floor chamber air supply member 3
The electric fans 36 and 41 of the second and second floor chamber air supply members 33 are stopped, and the electric fans 36 and 41 are further stopped.
Dampers 37 and 42 and underfloor ventilation port 2 on the downstream side of
Eight electric dampers 27 are closed. Then, the electric dampers 38 and 43 located on the side opposite to the electric fans 36 and 41 are opened.

The outside air forcedly introduced into the underfloor pit 10 from the outside air intake duct 29 via the electric fan 30 is sent to the air conditioner 31 which is operating for heating and is heated to be heated. Exhausted from 31. Then, the exhausted heated air comes into contact with the composite ceramics 7 laid in the underfloor pit 10.

As described above, the composite ceramics 7 has a small specific heat, a large heat capacity, and a low thermal conductivity. Therefore, the composite ceramics 7 stores heat with the air heated by the air conditioner 31 and stores the heat. The air that has been radiated from the composite ceramics 7 flows through the heated underfloor pit 10 and flows into the heated underfloor pit 10 and the air in each of the floor chambers 12 and 16 and each of the rooms R1 and R2. Because there is a temperature difference with air,
The heated air is supplied to the first-floor chamber air supply member 3 installed at a position separated from the air conditioner 31 by natural convection.
The air is supplied to the first floor chamber 12 and the second floor chamber 16 from the opened electric dampers 38 and 43 of the intake ducts 34 and 39 of the second and second floor chamber air supply members 33.

The heated air supplied to the first floor chamber 12 is supplied to the air supply port 4 provided in the first floor plate 11.
5, air is supplied to the room R1 on the first floor by natural convection through the air supply port 47 provided in the first-floor partition wall 23a and the air supply port 52 of the internal ventilation passage 22 of the air-conditioning wall 20a for internal ventilation. Being heated.

The heated air supplied to the second floor chamber 16 is supplied to the air supply port 4 provided in the second floor plate 15.
8, the air vents 50 and 2 provided on the second-floor partition wall 23b
Air supply port 5 of internal ventilation passage 22 of floor air-conditioning wall 20b
4, air is sent to the room R2 on the second floor by natural convection and heated.

Further, the operating state of each member in the intermediate period of less than 28 ° C. will be described with reference to FIG. 5. In FIG. 5, the operation of the electric fan other than the operation of the air conditioner 31 in FIG.・ Stopping and opening / closing of the electric damper are the same.

The outside air forced into the underfloor pit 10 from the outside air intake duct 29 via the electric fan 30 comes into contact with the composite ceramics 7 laid in the underfloor pit 10. When air flows through the underfloor pit 10 while contacting the composite ceramics 7 and a temperature difference occurs between the air in the underfloor pit 10 and the air in each of the floor chambers 12 and 16 and each of the rooms R1 and R2. The air in the underfloor pit 10 is supplied to each of the intake ducts 34 and 39 of the first floor chamber air supply member 32 and the second floor chamber air supply member 33 installed at a position separated from the outside air intake duct 29 by natural convection. First floor chambers 12 and 2 from the opened electric dampers 38 and 43 side
Air is supplied to the floor chamber 16.

The air supplied to the first floor chamber 12 is supplied to an air supply port 45 provided in the first floor plate 11, an air supply port 47 provided in the first floor partition wall 23 a, and an air conditioning system for ventilation in the first floor. Air is supplied to the room R1 on the first floor via the air supply port 52 of the internal ventilation passage 22 of the wall 20a.

The air supplied to the second floor chamber 16 is supplied to the air supply port 48 provided on the second floor plate 15 and the air supply port 50 provided on the second floor partition wall 23b and the air for ventilation in the second floor. The air is supplied to the room R2 on the second floor via the air supply port 54 of the internal ventilation passage 22 of the air conditioning wall 20b.

[0062] and further, when explaining the operation states of the respective members of the interim than 28 ℃ by Figure 6, the middle life of less than 28 ℃ in Figure 5 in the case of FIG. 6, the electric damper underfloor vents 2 8 Other than the opening of 27, the stopping of the other electric dampers and the opening and closing of the electric dampers are the same.

Thus, the air forcedly introduced into the underfloor pit 10 from the outside air intake duct 29 via the electric fan 30 and the outside air naturally taken in from the underfloor ventilation port 28 are:
It comes into contact with the composite ceramics 7 laid in the underfloor pit 10. The air flows through the underfloor pit 10 while being in contact with the composite ceramics 7, and the underfloor pit 10
Air and each floor chambers 12 and 16 and each room R1
If a temperature difference occurs between the air in R2 and the air in the underfloor pit 10, the air in the underfloor pit 10 is supplied by natural convection to the first-floor floor chamber air supply members 32 and 2 installed at a position away from the outside air intake duct 29. Each electric damper 38 of each of the intake ducts 34 and 39 of the floor chamber air supply member 33 opened.
Air is supplied from the 43 side to the first floor chamber 12 and the second floor chamber 16.

The air supplied to the first floor chamber 12 is supplied to an air supply port 45 provided in the first floor plate 11, an air supply port 47 provided in the first floor partition wall 23 a, and an air conditioning system for ventilation in the first floor. Air is supplied to the room R1 on the first floor via the air supply port 52 of the internal ventilation passage 22 of the wall 20a.

The air supplied to the second floor chamber 16 is supplied to the air supply port 48 provided on the second floor plate 15, the air supply port 50 provided on the second floor partition wall 23 b, and the ventilation for the second floor. The air is supplied to the room R2 on the second floor via the air supply port 54 of the internal ventilation passage 22 of the air conditioning wall 20b.

The operation of each member in the interim period is not limited to the operation shown in FIGS. 5 and 6, and each member is operated according to the condition of the resident, the room temperature or humidity, and the like. It can be set arbitrarily by a control panel (not shown).

Although the air conditioner 31 has been described as having a cooling / heating function, in addition to the cooling / heating function,
By using the air conditioner 31 also equipped with a dehumidifying function,
It can cope with an unpleasant climate with high humidity during the rainy season.

That is, when the humidity is high, the air conditioner 31
In addition to setting the dehumidifying function, the electric fans and the electric dampers are set in the same manner as in the cooling state in FIG. 3 to dehumidify instead of cooling the rooms R1 and R2. The function of each electric fan and electric damper and the flow of air are the same as those in FIG.

Thus, the current house is highly airtight in order to improve the cooling / heating efficiency, but the high airtightness causes a problem of dew condensation. In particular, condensation phenomena include surface, internal, and boundary condensation, and more generally in winter and winter.
There is a phenomenon of summer condensation. The occurrence of dew condensation and the occurrence of molds and ticks are in principle correlated, and the occurrence of dew condensation is caused by the moisture contained in the indoor air, and the dew condensation does not occur in dry air.

What is shown in Table 7 is the amount of moisture contained in the air. If the amount of moisture contained in the indoor air exceeds the value shown in Table 7, dew condensation occurs on the walls, windows and the like in the room.

[0071]

[Table 7]

Further, the basics of a building having a comfortable indoor environment are not only cooling and heating in all rooms, but also cleanliness and mental relief. That is, a comfortable building is free from dew condensation, mold, ticks, etc., does not smell, and has a large amount of negative ions.

As described above, in the building of the present invention, the air used in the entire building is caused to flow through the underfloor pit 10 to come into contact with the composite ceramics 7, and the air is sent to the respective rooms R1 and R2. is there. Since the composite ceramics 7 has an excellent far-infrared emissivity and has a far-infrared radiation characteristic, air in contact with the composite ceramics 7 is constantly irradiated with far-infrared rays, and invisible floating particles in the air are generated. The irradiation maintains the far-infrared radiation characteristics,
The radiation and absorption of heat constantly repeats the radiation and absorption of heat. Then, the air in the underfloor pit 10 is supplied to the air conditioner 3.
1, optimum temperature as indoor environment, preferably 18 to 2
The temperature is adjusted to 3 ° C. and the air is sent to each of the rooms R1 and R2 while keeping the far-infrared radiation characteristics.

By sending air to each of the rooms R1 and R2 while keeping the far-infrared radiation characteristics in the suspended particles in the air, each of the rooms R1 and R2 is cooled or heated or ventilated and dehumidified. By the action of infrared rays, it prevents the occurrence of general viable bacteria and mold, keeps sanitary pests such as fleas and ticks away, and further prevents the occurrence of dew condensation, as well as body odor, food products,
It deodorizes living odors such as the smell of cigarettes and generates many negative ions in the room.

[0075]

As described above, the present invention has a far-infrared radiation characteristic obtained by mixing a plurality of ceramics, and has an antibacterial property, a deodorizing property, an antifungal property, a repellent effect, and is suitable. Composite ceramics having a high thermal conductivity is laid in the underfloor pits, air is supplied onto the laid composite ceramics, air is brought into contact with the composite ceramics, and then air is forced into each room by forced convection or natural convection. By sending air, each room is cooled and heated or ventilated and dehumidified to maintain a comfortable room temperature throughout the seasons, and the far-infrared radiation characteristics of the composite ceramics prevent the generation of general viable bacteria and mold, and prevent fleas and fleas. Repels sanitary pests such as mites, further prevents the formation of condensation, deodorizes body odors, foodstuffs, daily odors such as tobacco odors, and is further radiated from the composite ceramics The far-infrared chemical reaction can generate a lot of negative ions based on the Leonard effect even if the amount of moisture in the air is small, so it gives the occupants a calming and suppressive effect to optimize the mental state It is possible to obtain a comfortable indoor environment by holding in the state of above, and since the composite ceramic has no change over time and its function lasts semi-permanently, there is no need for replacement and the running cost is low. It has an excellent effect.

[Brief description of the drawings]

FIG. 1 is a longitudinal sectional view schematically showing a building having a comfortable indoor environment function according to the present invention.

FIG. 2 is a cross-sectional view of an underfloor pit in a building having a comfortable indoor environment function according to the present invention.

FIG. 3 shows a temperature of 28 ° C. in a building having a comfortable indoor environment function according to the present invention.
It is a longitudinal cross-sectional view of the ventilation system which shows the time of cooling in the above summer.

FIG. 4 shows a temperature of 15 ° C. of a building having a comfortable indoor environment function according to the present invention.
It is a longitudinal cross-sectional view of the ventilation system which shows the time of heating in the following winter.

FIG. 5: 28 ° C. of a building having a comfortable indoor environment function according to the present invention
It is a longitudinal cross-sectional view of the ventilation system in the intermediate period of less than.

FIG. 6: 28 ° C. of a building having a comfortable indoor environment function according to the present invention
It is a longitudinal cross-sectional view of the ventilation system in the above-mentioned interim period.

[Explanation of symbols]

7 Composite ceramics, 10 Underfloor pit, 11
1st floor board, 12 1st floor chamber, 15 2nd floor board, 16 2nd floor chamber, 20, 20a, 20
b, 25 wall, 22, 2 6 ventilation passage 29
Outside air intake duct, 31 air conditioner, 32, 33 air supply member, 45, 47, 50, 52, 54 air supply port,
R1 1st floor room, R2 2nd floor room.

──────────────────────────────────────────────────続 き Continued on the front page (58) Field surveyed (Int.Cl. ⁷ , DB name) E04B 1/62-1/72 F24F 7/10 F24F 13/02

Claims (7)

(57) [Claims] 1. An amphibole as a base material, and a mixed material of each of ceramics of serpentine, quartz diorite, granite, phyllite, tuff, calcium oxide, magnesia and silica. Alternatively, a composite ceramic obtained by mixing five types of ceramics is laid in the underfloor pit, and an air conditioner is supplied to the underfloor pit, and air is supplied from the underfloor pit to the respective floor chambers. An air intake duct for introducing outside air to the air member and the underfloor pit, and air is supplied from each of the floor chambers to each of the floor rooms through an air supply port provided on each of the floor plates and a wall provided with a ventilation passage. A building with a comfortable indoor environment characterized by the following. 2. Serpentine is used as a base material, and three or five types of ceramics of granite porphyry, phyllite, tuff, magnesia, silica and limestone are mixed as a mixed material. While laying the obtained composite ceramic in the underfloor pit, an air conditioner in the underfloor pit,
In the underfloor pit, an air supply member that supplies air that has contacted the composite ceramics to each floor chamber and an outside air intake duct that introduces outside air into the underfloor pit,
A building provided with a comfortable indoor environment, wherein air is supplied from each floor chamber to each floor room through an air supply port provided on each floor plate and a wall provided with a ventilation passage. 3. An amphibole 20 to 3 as a base material in a pit under the floor.
0 to 30% by weight, 20 to 30 quartz diorite as a mixed material
Weight%, 20-30 weight% of calcium oxide and 20-30 weight% of magnesia are spread, and an air conditioner is provided in the underfloor pit.
In the underfloor pit, an air supply member that supplies air that has contacted the composite ceramics to each floor chamber and an outside air intake duct that introduces outside air into the underfloor pit,
A building provided with a comfortable indoor environment, wherein air is supplied from each floor chamber to each floor room through an air supply port provided on each floor plate and a wall provided with a ventilation passage. 4. Serpentine stones 40 to 6 as base materials are provided in underfloor pits.
5 to 15% by weight of granite, 5 to 15% by weight of phyllite, 5 to 15% by weight of tuff, 5 to 15% by weight of silica and 5 to 15% by weight of 0% by weight as a mixed material %, And an air conditioner is provided in the underfloor pit, and an air supply member for supplying air contacting the composite ceramic in the underfloor pit to each floor chamber and the underfloor pit. A comfortable room comprising an outside air intake duct for introducing outside air, wherein air is supplied from each floor chamber to each floor room through an air supply port provided on a wall provided with each floor plate and a ventilation passage. Building with environment. 5. Serpentine stones 20 to 3 as base materials are provided in underfloor pits.
Magnesia 20 to 30 as a mixed material with respect to 0% by weight
Wt%, silica 20-30 wt% and limestone 20-3
The composite ceramic obtained by mixing 0% by weight is spread, and an air conditioner is provided in the underfloor pit, an air supply member for supplying air contacting the composite ceramic in the underfloor pit to each floor chamber, and the underfloor. The pit is provided with an outside air intake duct for introducing outside air, and air is supplied from each floor chamber to each floor room through an air supply port provided on a wall provided with each floor plate and a ventilation passage. A building with a comfortable indoor environment. 6. An amphibole 40 to 6 as a base material in a pit under the floor.
5% to 15% by weight of phyllite, 5% to 15% by weight of tuff, 5% to 15% by weight of calcium oxide, 5% to 15% by weight of magnesia, and 5% to 15% by weight of 0% by weight
In addition, the composite ceramics obtained by mixing the mixed ceramics by weight are spread, and an air conditioner is provided in the underfloor pit, an air supply member that supplies air contacting the composite ceramics in the underfloor pit to each floor chamber, and the underfloor pit. A fresh air intake duct for introducing outside air to each of the floor chambers to each of the floor rooms through the air supply ports provided on the wall provided with the floor plates and the ventilation passages. Building with indoor environment. 7. An amphibole 20 to 3 as a base material in a pit under the floor.
20 to 30% by weight of serpentine, 20 to 30% by weight of quartz diorite and 20 to 30% by weight of granite porphyry as a mixed material with respect to 0% by weight.
A composite ceramic obtained by mixing 30% by weight is spread, an air conditioner is provided in the underfloor pit, an air supply member for supplying air contacting the composite ceramic in the underfloor pit to each floor chamber, and the underfloor. The pit is provided with an outside air intake duct for introducing outside air, and air is supplied from each floor chamber to each floor room through an air supply port provided on each floor plate and a wall provided with a ventilation passage. A building with a comfortable indoor environment.