JPWO2014024822A1 - Cooling member for outdoor heat exchanger and cooling device for outdoor heat exchanger using the same - Google Patents

Abstract

The cooling member for an outdoor heat exchanger includes a porous ceramic sintered body having a saturated moisture content of 25% by mass to 100% by mass. The outdoor heat exchanger cooling device includes the outdoor heat exchanger cooling member.

Description

The present invention relates to a cooling member for an outdoor heat exchanger and a cooling device for an outdoor heat exchanger.
This application claims priority based on Japanese Patent Application No. 2012-176133 filed in Japan on August 8, 2012 and Japanese Patent Application No. 2012-212005 filed in Japan on September 26, 2012. The contents are incorporated herein.

  In recent years, there has been an increasing need for further energy saving in order to cope with power shortages and to reduce carbon dioxide emissions generated by thermal power generation. In addition, with the recent rise in temperature, it is not uncommon for the maximum temperature to reach 35 ° C. or higher, and there are also people who suffer from heat stroke despite being indoors. Therefore, in addition to hydration, it is called to actively use air conditioning equipment to prevent heat stroke.

As the use of air conditioning equipment increases, the amount of power used is expected to increase, and thus the need to promote energy saving in air conditioning equipment is increasing.
As one of energy saving methods for air conditioning equipment, a method of cooling air supplied to an outdoor heat exchanger of the air conditioning equipment is known.
For example, by placing an artificial floor earth plate cultivated with plants such as Sedum in the shape of a louver in front of the air receiving port (suction port) of an outdoor heat exchanger of an air conditioner, it is 3-7 ° C. above the outside air temperature. An outside air cooling device for an air-cooled condenser that supplies low air to an outdoor heat exchanger is known (Patent Document 1).
An air conditioning system having a slit for cooling outside air upstream of the outdoor heat exchanger is known (Patent Document 2).

JP 2003-269748 A JP 2006-118797 A

However, the outdoor air cooling device described in Patent Document 1 is used in a high-temperature environment in summer and in an environment in which wind is always blowing by a cooling fan for supplying cooling air to the outdoor heat exchanger. . For this reason, the water evaporates immediately and it is necessary to frequently irrigate, and an irrigation device is required. In addition, soil filled between fibers may flow out due to rain and lose water retention, or may be sucked in with air supplied to the outdoor heat exchanger. It was. Moreover, weeds frequently grow on the soil, so weeding work was necessary. Therefore, maintenance of the outside air cooling device is complicated. In addition, when water is frequently sprayed from an irrigation device or the like during irrigation, if the stored water is used as the supplied water, the outdoor heat exchanger may become heavily soiled and heat exchange efficiency may be reduced. . On the other hand, when tap water is used as water sprayed during irrigation, the outdoor heat exchanger may be corroded by chlorine in the tap water.
Moreover, in the air conditioning system described in Patent Literature 2, a slit made of fiber or porous ceramic is used as a slit for cooling the outside air. However, since the slit is made of a fiber, it does not have a sufficient water content, so that it has been difficult to exert a sufficient cooling effect. Moreover, in the said literature, the moisture content etc. in case a slit is comprised with porous ceramics are not described, The cooling effect was unknown.

  Therefore, in the present invention, the temperature of the air supplied to the outdoor heat exchanger used in the air conditioning equipment can be reduced to save energy in the air conditioning equipment, and the cooling member for the outdoor heat exchanger and the outdoor heat exchanger that are easy to maintain It is an object to provide a cooling device.

In order to solve the above-mentioned subject, the cooling member for outdoor heat exchangers concerning the mode of the present invention has the following composition.
(1) The cooling member for an outdoor heat exchanger according to one aspect of the present invention includes a porous ceramic sintered body having a saturated moisture content of 25% by mass to 100% by mass.
(2) The cooling member for an outdoor heat exchanger according to (1), wherein the porous ceramic sintered body is a plate.
(3) The cooling member for an outdoor heat exchanger according to (1) or (2), wherein flat pores are formed inside the porous ceramic sintered body.
(4) The cooling member for an outdoor heat exchanger according to any one of (1) to (3), wherein a surface of the porous ceramic sintered body is ground.

Moreover, the cooling device for outdoor heat exchangers which concerns on 1 aspect of this invention has the following structures.
(5) An outdoor heat exchanger cooling device according to an aspect of the present invention includes the outdoor heat exchanger cooling member according to any one of (1) to (4).
(6) A cooling device for an outdoor heat exchanger according to one aspect of the present invention includes the cooling member for an outdoor heat exchanger according to (3) above, and the flat pores inside the porous ceramic sintered body are in a horizontal plane. The inclination angle is 30 ° or less.

An outdoor heat exchanger cooling member according to another aspect of one embodiment of the present invention is the outdoor heat exchange cooling member according to any one of (1) to (7), wherein the porous ceramic sintered body is sintered. The body has pores laminated in layers.
The cooling member for an outdoor heat exchanger according to another aspect of one embodiment of the present invention includes a porous ceramic sintered body having a saturated moisture content of 30% by mass to 100% by mass.

  The outdoor heat exchanger cooling member and the outdoor heat exchanger cooling device according to the aspect of the present invention can reduce the temperature of the air supplied to the outdoor heat exchanger used in the air conditioning equipment to save energy in the air conditioning equipment. Easy maintenance.

It is a front view of the cooling device for outdoor heat exchangers concerning the 1st example of the present invention. It is side surface sectional drawing of the cooling device for outdoor heat exchangers shown in FIG. It is a front view of the cooling device for outdoor heat exchangers which concerns on the 2nd example of this invention. It is a top view of the cooling device for outdoor heat exchangers which concerns on the 3rd example of this invention. It is a longitudinal cross-sectional view of the cooling device for outdoor heat exchangers shown in FIG. It is a figure explaining the preparation methods of the cooling device for outdoor heat exchangers shown in FIG. It is a top view of the cooling device for outdoor heat exchangers which concerns on the 4th example of this invention. It is a longitudinal cross-sectional view of the cooling device for outdoor heat exchangers shown in FIG. It is a figure explaining the preparation methods of the cooling device for outdoor heat exchangers shown in FIG. It is a figure explaining the usage pattern of the cooling device for outdoor heat exchangers shown in FIG. It is a side schematic sectional drawing of the measuring apparatus of the load of a ventilation fan and air temperature.

(Cooling member for outdoor heat exchanger)
Hereinafter, the cooling member for an outdoor heat exchanger according to the present embodiment will be described.
The cooling member for an outdoor heat exchanger according to this embodiment includes a porous ceramic sintered body having a saturated moisture content (measurement method will be described later) of 25% by mass or more and 100% by mass or less.

The porous ceramic sintered body used in the present embodiment is a ceramic sintered body having pores formed therein.
The size of the pores formed in the porous ceramic sintered body may be, for example, pores having a pore diameter of 10 to 1000 nm (pores on the order of nanometers), or pores having a pore diameter of 1 μm to 1000 μm (of the order of micrometers). Pores), pores having a pore diameter of 1 mm to 500 mm (pores on the order of millimeters), or these pores may be mixed. In particular, it is even better if pores in the order of millimeters, pores in the order of micrometers, and pores in the order of nanometers are mixed. When pores in the order of millimeters, pores in the order of micrometer and pores in the order of nanometers are mixed, while exhibiting air cooling performance, water evaporation is moderately suppressed and air cooling performance can be demonstrated over a long period of time.
The porous ceramic sintered body of the present embodiment is manufactured by a manufacturing method to be described later, and the pore diameter of the above-mentioned pores can be adjusted by combining the types of raw materials and the firing conditions during the manufacturing.
In the present embodiment, the pore diameter of the millimeter order pores is a value obtained by cutting the porous ceramic sintered body and measuring the major diameter of the pores using a scale. It is. The pore diameter of the nanometer-order and micrometer-order pores is a value obtained by cutting the porous ceramic sintered body and measuring the major diameter of the pores using an electron microscope.

The pores formed in the porous ceramic sintered body may be independent or may be communication holes communicating with each other. When the porous ceramic sintered body has communication holes, excellent cooling performance can be exhibited for a long period of time.
In addition, the shape of the pores of the porous ceramic sintered body is not particularly limited, and may be a flat shape in which one direction of the diameter in the cross section is longer than the other direction in addition to a shape close to a perfect circle or a square. . A plurality of flat pores may be formed in parallel. The term “formed in parallel” means, for example, a case where a plurality of flat pores having a long diameter in a cross section are arranged so as to align the long diameter direction. Furthermore, there is a case where they are stacked such that the direction in which the diameter is long is parallel to the surface of the sintered body. As will be described later, in a cooling device for an outdoor heat exchanger, a porous ceramic sintered body in which a plurality of flat pores are formed in parallel is used as a cooling member for an outdoor heat exchanger, and the flat pores are substantially parallel to a horizontal plane. If it arrange | positions so that it may become, it can hold water, such as rain, more fully, and can lower the temperature of the air supplied to an outdoor heat exchanger for a long period of time.

  The porous ceramic sintered body may have pores laminated in layers. The pores laminated in a layer form are those in which flat, millimeter-order pores are laminated in a layer form. As will be described later, this porous ceramic sintered body having pores laminated in layers is used as a cooling member for an outdoor heat exchanger, and the longer pores laminated in layers form the surface (with respect to the ground and the direction of gravity). If the porous ceramic composite is installed so that it is almost parallel to the horizontal plane (the inclination angle is 0 ° to 30 ° with respect to the horizontal plane), water such as rain can be retained sufficiently, and the outdoor The temperature of the air supplied to the heat exchanger can be lowered for a longer period.

  The porous ceramic sintered body has a saturated moisture content of 25% by mass or more. Here, the saturated water content is a value obtained by the following formula (1).

Saturated water content (mass%) = [(saturated mass−absolute dry mass) / absolute dry mass] × 100 (1)
Here, the saturated state refers to a state in which the pores are substantially filled with water. Specifically, the porous ceramic sintered body is immersed in water to replace the pore air with water. It is in the state. When measuring the saturation state mass, for the porous ceramic sintered body having parallel pores, immerse the porous ceramic sintered body in water for about 30 to 120 minutes so that the water does not flow out. You may take out and measure the mass.
The absolutely dry state is a state where the porous ceramic sintered body is dried at 105 to 115 ° C. (for example, 100 to 110 ° C.) until a constant weight is obtained (for example, 24 hours). More specifically, drying may be performed in accordance with JIS A 1509-3. When measuring the absolutely dry mass, you may measure using the drying loss method shown by JISK0067-1992, for example.

If the saturated moisture content of the porous ceramic sintered body is less than the lower limit of 25% by mass, a sufficient cooling effect may not be obtained. Moreover, when the period when it does not rain for a long time, the water inside the porous ceramic sintered body is almost evaporated, and the temperature of the air supplied to the outdoor heat exchanger cannot be lowered. There is a fear.
Moreover, frequent supply of water is required for the porous ceramic sintered body, and there is a risk that water supply means and frequent maintenance may be required. Furthermore, it is desirable that the saturated water content is 30% by mass or more, since both the cooling effect and the water content during use can be achieved to some extent. When the saturated water content is 40% by mass or more, these cooling effects and the water content during use can be further ensured. When the saturated water content is 50% by mass or more, these can be further ensured.
On the other hand, the saturated moisture content of the porous ceramic sintered body is 100% by mass or less. If the saturated moisture content exceeds 100% by mass, the strength may be insufficient when the porous ceramic sintered body is used as a plate-like material, and the plate-like material may break during construction. Moreover, when the evaporation rate of water becomes high and the period when it does not rain for a long time, the water inside the porous ceramic sintered body is almost evaporated. Therefore, as in the case where the saturated water content is low, the temperature of the air cannot be lowered for a long period of time, and there is a possibility that water supply means and frequent maintenance are required.
From the above, the saturated moisture content of the porous ceramic sintered body is 25 to 100% by mass, may be 30 to 100% by mass, may be 40 to 100% by mass, and is 50 to 100% by mass. Even better.

  Examples of a method for adjusting the saturated moisture content of the porous ceramic sintered body include a method for adjusting components to be blended in the production method described later, a ratio of each component, a method for adjusting the firing temperature, and the like.

The apparent density of the porous ceramic sintered body may preferably be 0.4 to 1.3 g / cm ³ . Here, the apparent density is a value obtained by [mass (g) of completely dry porous ceramic sintered body] / [volume of porous ceramic sintered body (cm ³ )]. If the apparent density is equal to or higher than the above lower limit, the strength of the porous ceramic sintered body can be further increased. If the apparent density is equal to or lower than the upper limit, the weight load on the installation location of the outdoor heat exchanger cooling device should be reduced. Can do.
The apparent density is sometimes referred to as bulk specific gravity. However, the bulk specific gravity is a dimensionless number without a unit.
The apparent density may be 0.45 to 1.1 g / cm ³ . The apparent density may be 0.55 to 0.85 g / cm ³ .

The shape of the porous ceramic sintered body is not particularly limited, and examples thereof include a plate-like material and a granular material.
Examples of the plate-like material include a rectangular parallelepiped shape having a long side of 3 cm or more and a disk shape. In the present embodiment, a columnar object whose length in one direction is longer than the other direction is included in the form of “plate-shaped object”.
Examples of the granular material include those obtained by crushing the plate-like material, and those obtained by forming pellets and firing, and having a long side of less than 3 cm, such as a columnar shape, needle shape, spherical shape, plate shape, or irregular shape. In addition, even if the major axis is 3 cm or more, an irregular shape is a granular material.

If the porous ceramic sintered body is a plate-like material, the water retention time in the porous ceramic sintered body will be long, and water will be replenished even in the midsummer under hot weather (high temperature, sunshine, etc.) The number of times can be reduced. In addition, since weeds are difficult to grow, maintainability becomes higher.
In addition, when flat pores are formed inside the porous ceramic sintered body as described above (or when the porous ceramics sintered body has a layered pore), the porous ceramic sintered body may be a plate-like material. In this case, it becomes easy to arrange the flat pores substantially horizontally, and it is easy to maintain water retention as described above.
If the porous ceramic sintered body is granular, the surface area is increased, the contact area with air is increased, and the cooling effect is further exhibited.

The surface of the porous ceramic sintered body may be ground. On the surface of the porous ceramic sintered body that has not been subjected to the grinding process, the opening of the pores may be narrower or clogged than the original opening diameter of the pores. In such a case, the porous ceramic sintered body is difficult to absorb water in the pores and may not exhibit sufficient cooling performance. If the surface of the porous ceramic sintered body is ground, the narrow pores can be widened. Therefore, the water absorption speed of the surface of the porous ceramic sintered body is improved, the water is absorbed quickly, and the evaporation speed of the retained water is improved to further cool the air supplied to the outdoor heat exchanger. Can do. Even if the evaporation rate of water is improved, the porous ceramic sintered body used for the outdoor heat exchanger cooling member of the present embodiment has a high saturated water content, and therefore can exhibit the air cooling performance over a long period of time. .
In particular, when the porous ceramic sintered body is a plate-like material, the effect of the grinding process is more exhibited.

The size of the porous ceramic sintered body is not particularly limited. For example, in the case of a plate-shaped object, the length 3 is considered in consideration of the target degree of air cooling and the size of the outdoor heat exchanger. ˜200 cm × width 3 to 200 cm × thickness 1 to 10 cm (or dimensions are not limited to vertical, width and thickness, and the size is 3 to 200 cm × 3 to 200 cm × 1 to 10 cm). More than 5 mm and 3 cm or less.
The size can be measured using a scale if it is a plate-like material, and can be measured using a sieve if it is a granular material. For example, a particle diameter of 1 cm or less is passed through a sieve having an opening of 1 cm, and a diameter exceeding 1 cm is not passed. Among those having a particle diameter of 1 cm or less, those having passed through a sieve having an aperture of 0.5 mm are set to have a particle diameter of 0.5 mm or less, and those not passing through the sieve are those having a particle diameter of 0.5 to 1.0 cm. It is a granular material.

The cooling member for an outdoor heat exchanger according to this embodiment may be configured by combining a plurality of porous ceramic sintered bodies. Combining a plurality refers to using a porous ceramic sintered body having the same shape, size, apparent density, pore diameter or arrangement, and / or different porous ceramic sintered bodies. When combining a plurality of porous ceramic sintered bodies, for example, plates may be combined, a plate and a granular material may be combined, or a granular material may be combined.
Moreover, the cooling member for outdoor heat exchangers may consist only of a porous ceramic sintered body, or may be used in combination with other cooling members.
Moreover, in the cooling member for an outdoor heat exchanger of the present embodiment, a plant such as a succulent plant such as lawn, moss, or sedum is planted on the porous ceramic sintered body within a range that does not inhibit the effect. It doesn't matter.

  Examples of the porous ceramic sintered body include a ceramic sintered body described in JP-A-2005-239467, a porous ceramic sintered body described in International Publication No. 10/106724 pamphlet, and the like. And the like. In addition, the “Green Biz” series (trademarks “Green Biz r”, “Green Biz w”, etc., manufactured by Komatsu Seiren Co., Ltd.), which are porous ceramic sintered bodies, and those crushed if necessary It is done.

<Method for producing porous ceramic sintered body>
As a method for producing a porous ceramic sintered body, for example, raw materials are mixed to form a mixture (hereinafter sometimes simply referred to as “mixture”) (mixing step), and the mixture is formed into a formed body (forming step). And a method of firing a compact to obtain a porous ceramic sintered body (firing step).

The mixing step is a step of obtaining a mixture by mixing raw materials including clay.
As a mixture, at least 1 sort (s) selected from the group which consists of slag, organic sludge, diatomaceous earth, a filler, etc., for example, and clay may be included. The mixture may contain slag, organic sludge and clay. By using slag, it is possible to form pores on the order of millimeters in the porous ceramic sintered body, and it is possible to form pores on the order of micrometers in the porous ceramic sintered body by using diatomaceous earth. Moreover, by using organic sludge, pores in the micrometer order and smaller pores can be formed in the porous ceramic sintered body. If the mixture contains slag, organic sludge, and clay, or slag, diatomaceous earth, and clay, the saturated moisture content can be secured for the porous ceramic sintered body, so that the water retention capability is improved. In addition, the apparent density can be reduced. When a mixture containing organic sludge, diatomaceous earth, and clay is used in the mixture, the strength of the porous ceramic sintered body is improved, and the saturated water content can be secured, so that the water retention ability can be improved. If the mixture contains slag, organic sludge, diatomaceous earth, and clay, the strength, water retention ability and apparent density of the porous ceramic sintered body can be further balanced. The porous ceramic sintered body obtained by firing the mixture listed here has communication holes and many pores.

  The slag is not particularly limited, for example, in blast furnace slag generated during metal refining, municipal waste melting slag generated during melting of municipal waste, sewage sludge melting slag generated during melting of sewage sludge, or cast iron such as ductile cast iron Vitreous slag such as cast iron slag generated may be used. Among them, since the composition is stable, a stable foamed state can be obtained, and cast iron slag having a foaming ratio of about 1.5 to 2 times that of other slag may be used. When cast iron slag is used in the mixture, it becomes easy to form a plurality of flat, millimeter-order pores in parallel in the porous ceramic sintered body, and the water permeability and water retention of the porous ceramic sintered body are further increased. It is done.

  The blending amount of slag in the mixture can be determined in consideration of the moldability of the mixture. For example, it is preferably 80% by mass or less with respect to the total mass of the mixture. Within the above range, the moldability of the mixture can be smoothly and smoothly formed, and the apparent density of the porous ceramic sintered body can be set within a suitable range. In order to combine these advantages, it may be used in an amount of 20 to 80% by mass, more preferably 30 to 70% by mass, and even more preferably 40 to 60% by mass with respect to the entire mass of the mixture.

  Instead of the above-described slag, the mixture may be a foamed material that foams during firing, such as calcium carbonate, silicon carbide, or magnesium carbonate, or may be used in combination with slag.

Organic sludge is sludge containing an organic substance as a main component. Any organic sludge can be used as the organic sludge to be added to the mixture, and activated sludge derived from wastewater treatment such as sewage or factory may be used. The activated sludge is discharged from a wastewater treatment facility using the activated sludge method through a coagulation / dehydration process. By using such organic sludge in the mixture, pores on the order of micrometers can be efficiently formed, and pores on the order of nanometers can be formed. By forming pores in the order of nanometers, a porous ceramic sintered body having a low apparent density can be obtained, and water retention can be further increased. Furthermore, the activated sludge derived from wastewater treatment, which has been positioned as waste, can be reused as a raw material.
The moisture content of the organic sludge may be, for example, 5 to 90% by mass, 50 to 90% by mass, or 60 to 90% by mass with respect to the total mass of the mixture. . Yes. Within this range, a homogeneous mixture can be obtained and good moldability can be easily maintained. When the water content is 65 to 85% by mass, the homogeneity and the moldability can be further achieved.

  The organic matter content in the organic sludge is not particularly limited. For example, the organic matter content (organic matter content) in the solid content of the organic sludge is 70% by mass or more based on the total mass of the organic sludge. Also good. The larger the organic content, the easier it is to form micrometer-order pores, and nanometer-order pores. The organic matter content may be 80% by mass or more based on the total mass of the organic sludge, and these pores can be more suitably formed within this range. In addition, organic substance content is a value calculated | required by the following (2) formula, measuring ash content (mass%) at the carbonization temperature of 700 degreeC according to JISM8812-1993 for the sludge after drying.

Organic content (mass%) = 100 (mass%) − ash (mass%) (2)

  The average particle diameter of the organic sludge may be 1 to 5 μm. Since organic sludge is burned off by firing and pores are formed there, pores on the order of micrometers can be formed more easily as the average particle size is smaller, and pores on the order of nanometers can be formed. The average particle diameter may be 1 to 3 μm, and these pores can be more suitably formed within this range. The average particle diameter is a volume-based median diameter (50% volume diameter) measured by a particle size distribution measuring device (LA-920, manufactured by Horiba, Ltd.).

  The content of organic sludge in the mixture can be determined in consideration of the moldability of the mixture. 1-60 mass% may be sufficient with respect to the whole mass of a mixture. If it is in the said range, a mixture will have moderate fluidity | liquidity and plasticity, a moldability will improve, and it can shape | mold smoothly, without obstruct | occluding a shaping | molding apparatus. The content may be 5 to 30% by mass or may be 5 to 20% by mass.

Diatomaceous earth is a deposit made of diatom remains and is porous with pores on the order of micrometers. By using diatomaceous earth for the mixture, fine pores derived from diatomaceous earth can be formed in the porous ceramic sintered body.
As diatomaceous earth, it is not specifically limited, The thing similar to what was conventionally used for a fireproof heat insulation brick or a filter medium etc. can be used. For example, it is not necessary to separate and refine clay minerals (montmorillonite, etc.), quartz, or feldspar, etc., which are narrow, and the amount of the mixture can be adjusted after recognizing these contents. In addition, it is preferable to use refractory heat-insulated bricks, filter media, stoves, and the like that are manufactured and discarded using diatomaceous earth because waste can be reduced.

The moisture content of diatomaceous earth is not particularly limited, and for example, the moisture content in a naturally dried state may be 20 to 60 mass% with respect to the entire mass of diatomaceous earth. If it is in the said range, a mixture with favorable moldability can be obtained by removing and using the coarse particle content in a narrow thing in the case of mixing, recognizing a moisture content. The moisture content may be 30 to 50% by mass, or may be 35 to 45% by mass.
The moisture content of diatomaceous earth is a value obtained by drying the sample (200 ° C., 12 minutes) using the infrared moisture meter with the following specifications, which is a weight loss method, and calculating the following equation (3).

<Specifications>
Measurement method: Drying loss method (heat drying / mass measurement method),
Minimum display: moisture content; 0.1% by mass,
Measurement range: moisture content; 0.0 to 100% by mass,
Drying temperature: 0 to 200 ° C
Measurement accuracy: sample weight 5g or more, moisture content ± 0.1% by mass,
Heat source: infrared lamp; 185W

Moisture content (mass%) = [(m ₁ -m ₂ ) / (m ₁ -m ₀ )] × 100 (3) m ₁ : between the mass of the container before drying and the mass of the sample before drying Total mass (g), m ₂ : Total mass (g) of the mass of the container after drying and the mass of the sample after drying, m ₀ : Mass of the container after drying (g)

  The content of diatomaceous earth in the mixture can be determined in consideration of the saturated moisture content and strength required for the porous ceramic sintered body, and may be, for example, 55% by mass or less based on the total mass of the mixture. If the upper limit value or less, the moldability of the mixture is good. If the lower limit value or more, a porous ceramic sintered body having a desired saturated moisture content or a porous ceramic sintered body having a desired strength is obtained. Easy to obtain. That is, the content may be 1 to 55% by weight. The content may be 1 to 45% by mass, and in this range, a more preferable saturated water content and strength of the porous ceramic sintered body can be obtained.

The clay in the present embodiment is a mineral material having a clay-like property generally used as a ceramic raw material, and is other than diatomaceous earth.
As clay, the well-known thing used for a ceramic sintered compact can be used. These clays are mainly composed of mineral compositions such as quartz, feldspar, clay, etc., and the constituent minerals are mainly kaolinite and contain halloysite, montmorillonite, illite, bentonite or pyrophyllite. May be. Among them, quartz particles having a particle diameter of 500 μm or more may be included from the viewpoint of suppressing the progress of cracks during sintering and preventing the destruction of the porous ceramic sintered body. The coarse particle diameter of the quartz may be 5 mm or less. Examples of such clays include cocoon clay. As clay, various types having different physical properties such as composition (including the above-described various minerals), constituting particle diameters, and moisture content can be blended alone or in combination of two or more.

  The clay content in the mixture can be determined in consideration of the strength and formability required of the porous ceramic sintered body, and may be 5 to 60% by mass. If the clay content in the mixture is within the above range, the moldability of the mixture can be smoothly formed without being impaired, and the strength of the porous ceramic sintered body can be made sufficient. For the advantage of improving the moldability of the mixture and the strength of the porous ceramic sintered body, the content may be 5 to 50% by mass, or 10 to 40% by mass.

Examples of the filler in the present embodiment include particles of high melting point glass having a melting temperature of 900 ° C. or higher, particulate filler such as fly ash; and fibrous filler such as carbon fiber, basalt fiber, or rock wool. Among them, particles of high melting point glass, fly ash or fibrous filler are preferable, and particles of high melting point glass are more preferable. Here, fly ash is particles discharged when, for example, coal is burned at a thermal power plant. By using high melting point glass particles as the filler contained in the mixture, the strength of the porous ceramic sintered body can be further improved, and good formability can be obtained.
For example, when a raw material containing high melting point glass particles as a filler is sintered, the high melting point glass particles are partially melted and fused with each other, or function as a binder for the clays, diatomaceous earth, etc. By doing so, the strength of the porous ceramic sintered body can be further improved.
Alternatively, the fibrous filler can be further improved in the strength of the porous ceramic sintered body by being taken into the porous ceramic sintered body.

  As the high melting point glass, one having a melting temperature of 900 ° C. or higher can be used. If the melting temperature of the high melting point glass is equal to or higher than the above lower limit value, the particles of the high melting point glass are partially melted in the firing step described later, and are fused with the particles of the high melting point glass, or clays and diatomaceous earth It can function as a binder. In addition, the higher the melting temperature, the higher the strength of the porous ceramic sintered body. The melting temperature may be 1000 ° C. or higher, and the strength is further improved within this range. The melting temperature may be 1200 ° C. or higher, and the strength is further improved within this range. The melting temperature of the high melting point glass may be 1800 ° C. or less. If the melting temperature of the high melting point glass exceeds the above upper limit, the particles of the high melting point glass are difficult to melt when sintered, and the strength of the porous ceramic sintered body may not be sufficiently improved. The melting temperature of the high melting point glass may be 1600 ° C. or less, and the ease of melting and the strength are further improved in this range. From the above, the melting temperature of the refractory glass may be 900 to 1800 ° C, may be 1000 to 1600 ° C, and may be 1200 to 1600 ° C.

The material of the high melting point glass is not particularly limited, but may be alkali-free glass, aluminosilicate glass, borosilicate glass, or quartz glass. With such a material, the strength of the porous ceramic sintered body can be sufficiently improved. When the material is borosilicate glass, particularly high strength can be obtained.
The alkali-free glass is a glass that does not substantially contain an alkali metal element such as sodium, potassium, or lithium. “Substantially not contained” means that the content of the alkali metal element in the glass composition is 0.1% by mass or less in terms of oxide.
Aluminosilicate glass is an oxide glass mainly composed of aluminum and silicon.
Borosilicate glass is an oxide glass mainly composed of boron and silicon.
Quartz glass refers to glass made from quartz and having high silicon oxide purity.
Borosilicate glass is an oxide glass mainly composed of boron and silicon. Examples of the borosilicate glass include AN100 (trade name, non-alkali borosilicate glass, manufactured by Asahi Glass Co., Ltd.).

The high melting point glass is, for example, a liquid crystal display such as a liquid crystal television, a panel such as a plasma display, a cover glass for EL, a cover glass for a solid-state image sensor (represented by a CCD), a glass for an optical filter (hand pass filter, etc.) It is used for various products such as glass for glass substrates, flasks or beakers for chip-on-glass applications.
As the particles of the high melting point glass used in the present embodiment, waste glass discharged in the above-described product manufacturing process, or a panel recovered from a discarded liquid crystal television or the like can be used.
In particular, flat display panels such as liquid crystal televisions generate a large amount of waste glass when the flat display is manufactured with an increase in size. Waste can be reduced by making the waste glass of the flat display panel into particles of high melting point glass. In addition, the waste glass of the flat display panel can be used as a high-melting glass having a stable quality without special purification because the purity of the glass composition is high.

  The particle diameter of the high melting point glass particles may be 0.3 to 5 mm. . When the particle diameter is less than 0.3 mm, pores are not sufficiently formed in the porous ceramic sintered body, or the apparent density is increased. If the pores are not sufficiently formed, water retention and transpiration are impaired, water permeability is difficult to obtain, or a porous ceramic sintered body having a desired apparent density may not be obtained. If the particle diameter is more than 5 mm, moldability may be deteriorated, or the metal fitting at the extrusion port may be damaged during molding.

  The content of the high melting point glass particles in the mixture may be 10 to 40 parts by mass with respect to a total of 100 parts by mass of raw materials other than the filler. If the content of the high melting point glass particles in the mixture is less than the lower limit, the strength of the porous ceramics may not be sufficiently improved, and if it exceeds the upper limit, the moldability of the mixture may be impaired. There is. The content may be 15 to 40 parts by mass. Within this range, both the strength of the porous ceramic and the moldability of the mixture can be suitably obtained.

  0.01-20 mass parts may be sufficient as content of the fibrous filler in a mixture. If it is less than the said lower limit, there exists a possibility that the intensity | strength of a porous ceramic sintered compact cannot fully be improved, and if it exceeds the said upper limit, there exists a possibility that a moldability may be impaired. The content may be 0.01 to 10 parts by mass. If the content is within this range, both the strength of the porous ceramic and the moldability of the mixture can be obtained more suitably. In order to achieve both the strength of the porous ceramic and the moldability of the mixture, the content may be 0.05 to 5 parts by mass, and particularly preferably 0.1 to 2 parts by mass.

The mixture may contain an arbitrary component as long as the effect of the present embodiment is not impaired. Examples of optional components include naphthalene-based fluidizing agents such as Mighty 2000WH (trade name, manufactured by Kao Corporation), melamine-based fluidizing agents such as Melment F-10 (trade name, manufactured by Showa Denko KK), and the like. Polycarboxylic acid fluidizers such as Darex Super 100pH (trade name, manufactured by Grace Chemicals Co., Ltd.), antibacterial agents such as silver, copper and zinc, deodorizers such as ammonium chloride and zinc chloride, zeolite, apatite, etc. Adsorbent or metallic aluminum.
When mix | blending an arbitrary component with a mixture, the range of 5-10 mass% may be sufficient as the compounding quantity of an arbitrary component, for example.
In addition, for the purpose of adjusting the fluidity of the mixture, water may be appropriately blended, but when organic sludge is blended at a suitable blending ratio, it is not necessary to add water in the mixing step. Also good.

The mixing apparatus used for a mixing process is not specifically limited, A well-known mixing apparatus can be used.
Examples of the mixing device include a kneader such as a mix muller (manufactured by Toshin Kogyo Co., Ltd.), a kneader (manufactured by Moriyama Co., Ltd.), a mixer (manufactured by Nippon Ceramic Science Co., Ltd.), and the like.

The mixing time in the mixing step can be determined in consideration of the mixing ratio of the raw materials, the fluidity of the mixture, etc., and it is preferable to determine the mixing time such that the mixture is in a plastic state. The mixing time may be, for example, in the range of 15 to 45 minutes. The mixing time may be better in the range of 25 to 35 minutes.
The temperature in the mixing step is not particularly limited, and can be determined in consideration of the mixing ratio of raw materials, moisture content, and the like. For example, the temperature may be in the range of 40 to 80 ° C, or may be in the range of 50 to 60 ° C. .

The forming step is a step of forming the mixture obtained in the mixing step into an arbitrary shape.
A known molding method can be used as the molding method, and can be determined in consideration of the properties of the mixture and the desired shape of the molded body. The molding method is, for example, a method of obtaining a molded body such as a plate, a granule, or a column including pellets using a molding machine, a method of obtaining a molded body by filling a mixture into a mold of any shape, or Examples thereof include a method of extruding and rolling the mixture and then cutting it into an arbitrary dimension. From the viewpoint of forming layered pores, a method of extrusion and / or stretching or / and rolling may be used.
As the molding machine, a vacuum clay molding machine, a flat plate press molding machine, a flat plate extrusion molding machine, or the like may be used. Among these, a vacuum clay molding machine can be suitably used.

The firing step is a step of drying the formed body obtained in the forming step (drying operation), firing the dried formed body (firing operation), and sintering diatomaceous earth or clay to obtain a ceramic sintered body. .
Operation performed by the said drying operation is not specifically limited, A well-known method can be used. For example, the molded body may be naturally dried, or may be dried by treating for an arbitrary time in a hot air drying oven at 50 to 220 ° C. Although the moisture content of the molded object after drying is not specifically limited, For example, less than 5 mass% may be sufficient. The moisture content may be less than 1% by mass. Moreover, when obtaining a granular material, it is not necessary to perform drying operation.
The operation performed in the baking operation is not particularly limited, and a known method can be used. Examples thereof include a method of firing at an arbitrary temperature using a continuous sintering furnace such as a roller hearth kiln or a batch sintering furnace such as a shuttle kiln. Among these, a continuous sintering furnace may be used for the firing operation. By using a continuous sintering furnace for the firing operation, the productivity of the porous ceramics is improved.
The firing temperature can be determined according to the properties of the mixture, and may be, for example, 900 ° C to 1200 ° C. When the firing temperature is equal to or higher than the above lower limit value, the odor component derived from the organic sludge is thermally decomposed and eliminated, and most of the organic matter in the organic sludge is volatilized and reduced. If the firing temperature exceeds the upper limit, vitrification of the entire structure of the ceramic sintered body proceeds, and the molded body may be damaged or pores may be blocked.

After the firing step, the porous ceramic sintered body may be cut into an arbitrary size as necessary.
Moreover, you may give the grinding process process which grinds the surface of a porous ceramic sintered compact. The surface on which the porous ceramic sintered body is subjected to grinding can be determined in consideration of the form and usage of the porous ceramic sintered body (usage conditions or conditions such as the arrangement inside the cooling member for the outdoor heat exchanger). . For example, when manufacturing a plate-shaped porous ceramic sintered body, grinding may be performed on both surfaces or one surface in the thickness direction of the plate-shaped porous ceramic sintered body. Examples of tools used for grinding include cutting machines such as the vertical milling machine PV series (Amitex Co., Ltd.), grinders, sandpapers, and the like.
The degree of grinding is determined in consideration of the properties and size of the porous ceramic sintered body. For example, the grinding is performed to a depth of about 0.5 to 5 mm from the surface of the porous ceramic sintered body. Also good. If the grinding depth is less than the lower limit, it is difficult to obtain the effect of grinding, and if it exceeds the upper limit, the strength of the porous ceramic sintered body after grinding may be lowered.
When grinding is performed, the porous ceramic sintered body can maintain an excellent water absorption rate over a long period of time when it is used as a cooling member for an outdoor heat exchanger in the state of a plate-like material, quickly absorbs rainwater, Water can be taken into the porous ceramic sintered body. In addition, the evaporation rate of the retained water is improved, and the air supplied to the outdoor heat exchanger can be further cooled.

  Moreover, the manufacturing method of a porous ceramic sintered compact may have a crushing process. In the crushing step, the porous ceramic sintered body obtained in the firing step can be crushed (crushing operation) with a hammer mill or the like to obtain a granular porous ceramic sintered body. The obtained crushed material may be sieved as necessary to obtain a crushed material having an arbitrary particle size (sieving operation). When a granular ceramic sintered body having a particle diameter in a desired range can be obtained by setting the conditions for the crushing operation, the sieving operation may not be performed.

<Effect>
The outdoor heat exchanger cooling member of the present embodiment includes a porous ceramic sintered body having a saturated moisture content in the above range and containing a large amount of water, and the air that has passed through the cooling member is generated by the heat of vaporization of water. Heat is taken away and it is cooled. Moreover, if water is supplied so as to keep the water content of the porous ceramic sintered body above 15 mass%, the effect of cooling the air can be exhibited more. Therefore, if the outdoor heat exchanger cooling member of the present embodiment is installed in the vicinity of the outdoor heat exchanger, the temperature of the air supplied to the outdoor heat exchanger can be lowered to save energy in the air conditioning equipment.
In the porous ceramic sintered body described above, water such as rain is usually sufficiently retained and the water is gradually vaporized, so that the air can be cooled over a long period of time, and it is almost necessary to supply water. There is no. Even if the day when it does not rain continues, depending on the outside air temperature or the amount of air blown by a blower fan, etc., depending on the hose or watering, about 1 to 3 times a week, more preferably about 1 to 7 times, porous ceramics The effect of cooling the air can be exerted if sufficient water is supplied to the sintered body to a saturated water content state. Accordingly, the outdoor heat exchanger cooling member of the present embodiment is easy to maintain for maintaining the cooling performance over a long period of time.

(Cooling device for outdoor heat exchanger)
Below, the cooling device for outdoor heat exchangers which concerns on this embodiment is demonstrated. In addition, a part of the description of the porous ceramic sintered body already described above is omitted.
A cooling device for an outdoor heat exchanger according to the present embodiment includes an outdoor heat exchanger cooling member including the porous ceramic sintered body, for example, cooling equipment such as an air conditioner, a large refrigerator, or a refrigerator. It is used when lowering the temperature of the air supplied to the outdoor heat exchanger.

In the outdoor heat exchanger cooling device of the present embodiment, the outdoor heat exchanger cooling member may be disposed in the frame. Here, the frame body can accommodate the cooling member for the outdoor heat exchanger, and at least two side surfaces facing each other are opened.
The frame housing the outdoor heat exchanger cooling member may be directly attached to the ground, the rooftop, the roof, or the exterior of the outdoor unit in which the outdoor heat exchanger is housed by bolts or welding. Further, the frame body may be combined with a column or the like, and may be fixed to a ground, a rooftop, a roof, an exterior of an outdoor unit in which an outdoor heat exchanger is stored, or the like by bolts or welding, or a concrete block It may be fixed to a heavy object such as.
In addition, the outdoor heat exchanger cooling device of the present embodiment may be one in which a plate-shaped outdoor exchanger cooling member is attached between the columns without using a frame, or for a granular outdoor heat exchanger The cooling member may be filled in a container (for example, a container using a net or the like) in which a hole communicating with the outside is formed.
The cooling device for an outdoor heat exchanger is formed by forming a cylindrical body with a plate-shaped object of an outdoor heat exchanger cooling member, and filling the inside of the cylindrical body with a granular outdoor heat exchanger cooling member. Also good.

As an outdoor heat exchanger cooling member constituting the outdoor heat exchanger cooling device, a plate-like material of a porous ceramic sintered body may be used. This configuration is suitable for an application in which cooled air is supplied to the outdoor heat exchanger over a long period of time.
In addition, as the plate-like material of the porous ceramic sintered body, a plate in which a plurality of flat pores are formed in parallel may be used. Furthermore, the flat pores may be arranged substantially horizontally. If the flat pores are arranged almost horizontally, the amount of water that can be retained in the porous ceramic sintered body will increase, and water such as rain can be absorbed and retained reliably. Air cooling effect can be obtained.
Here, “the flat pores are almost horizontal” means that the direction in which the diameter of the flat pores is long is 30 ° or less with respect to the horizontal surface of the ground surface. Further, the inclination angle of the flat pores with respect to the horizontal surface of the ground surface may be 20 ° or less, may be 10 ° or less, and may be 5 ° or less. As the tilt angle decreases, the amount of water that can be retained in the porous ceramic sintered body increases, and water such as rain can be absorbed and retained reliably. It is done. It is particularly preferable that the flat pores are 0 ° (almost 0 °), that is, horizontal with respect to the horizontal surface of the inclined angle surface. When the inclination angle is 0 °, the load on the blower fan that sends air to the outdoor heat exchanger can be minimized.
On the other hand, if the inclination angle of the flat pores with respect to the horizontal surface of the ground surface exceeds 30 °, water in the pores may flow out from the porous ceramic sintered body, and the water retention of the porous ceramic sintered body may be reduced. There is.

Moreover, in the outdoor heat exchanger cooling device, the outdoor heat exchanger cooling member should be arranged so that the contact area between the air supplied to the outdoor heat exchanger and the outdoor heat exchanger cooling member is increased. Is preferred. More specifically, the contact area between the air supplied to the outdoor heat exchanger and the outdoor heat exchanger cooling member is cooled, for example, with the opening ratio of the opening formed by the outdoor heat exchanger cooling member. It can adjust with the length of the cooling member for outdoor heat exchangers in the flow direction of air. When the aperture ratio decreases or the length of the cooling member for the outdoor heat exchanger in the flow direction of the air to be cooled increases, the air supplied to the outdoor heat exchanger through the cooling device for the outdoor heat exchanger Since the contact probability with the outdoor heat exchanger cooling member is increased, the temperature of the air is more likely to be lowered.
When the aperture ratio becomes extremely small, for example, when the outdoor heat exchanger cooling members are arranged close together so as to cover almost the entire front surface of the air inlet for supplying air to the outdoor heat exchanger, the pressure Loss increases, the load of the blower fan increases, and the energy saving effect tends to decrease. Therefore, it is preferable to arrange the porous ceramic sintered body while appropriately adjusting it by trial and error so as to ensure a gap that does not increase the load of the blower fan.

Since the outdoor heat exchanger cooling device is installed outdoors, water is supplied to the porous ceramic sintered body due to rain, etc., so means and devices for supplying moisture to the porous ceramic sintered body are separately provided. Cooling is possible without providing it. On the other hand, the means may be provided. For example, the dew condensation water generated in the indoor heat exchanger may be supplied to the porous ceramic sintered body constituting the cooling member for the outdoor heat exchanger. . As a specific method for supplying condensed water, there is a method in which the condensed water is dropped on the upper surface of the porous ceramic sintered body. As another supply method, the condensed water is accumulated in a container or the like, and a porous ceramic sintered body is disposed so as to be in contact with the condensed water, and water is generated by capillary action due to a communication hole in the porous ceramic sintered body. And a method of supplying moisture into the porous ceramic sintered body.
Further, in the outdoor heat exchanger cooling device of the present embodiment, water supply means such as a water spray device, a dripping device, and a water tank may be installed so that water can be supplied to the porous ceramic sintered body. . The water supply means is preferably such that the outdoor heat exchanger is not directly exposed to water.

Further, in the outdoor heat exchanger cooling device of the present embodiment, the outdoor heat exchanger cooling member may be installed upstream of the outdoor heat exchanger in the air flow supplied to the outdoor heat exchanger. Good. In many cases, the outdoor heat exchanger is supplied with cooling air using a blower fan. In this case, an outdoor heat exchanger cooling member may be disposed between the outdoor heat exchanger and the blower fan. And an outdoor heat exchanger may be arrange | positioned between the cooling member for outdoor heat exchangers and a ventilation fan, and a ventilation fan may be arrange | positioned between the outdoor heat exchanger and the cooling member for outdoor heat exchangers. From the viewpoint of the cooling effect, it is preferable to dispose a blower fan between the outdoor heat exchanger and the outdoor heat exchanger cooling member.
In addition, when the outdoor heat exchanger itself contains a blower fan, the outdoor heat exchanger provided with a cooling member for the outdoor heat exchanger in the vicinity of the air inlet for supplying air to the outdoor heat exchanger What is necessary is just to install the cooling device for equipment.
In this case, it is preferable to install the outdoor heat exchanger cooling device such that the outdoor heat exchanger cooling member covers substantially the entire air inlet. If the cooling member for the outdoor heat exchanger covers almost the entire air inlet, most of the air supplied to the outdoor heat exchanger is cooled by the cooling member for the outdoor heat exchanger. More energy can be saved.
Also, an outdoor heat exchanger cooling device may be installed at the air exhaust port of the outdoor heat exchanger, or the entire outdoor heat exchanger is surrounded by the outdoor heat exchanger cooling device and added to the air intake port. An outdoor heat exchanger cooling member may also be disposed in the vicinity of the exhaust port.

A first specific example of the outdoor heat exchanger cooling device of the present embodiment will be described.
As shown in FIGS. 1 and 2, the outdoor heat exchanger cooling device 4 of this example includes a plurality of rectangular plate-like porous ceramic sintered bodies 1 and a frame for fixing the porous ceramic sintered bodies 1. A body 2. The porous ceramic sintered body 1 used in this example has a plurality of flat pores formed in parallel therein. The flat pores are formed so that the direction in which the diameter of the flat pores is long is perpendicular to the thickness direction of the porous ceramic sintered body 1. The frame body 2 has a rectangular parallelepiped shape, and an opening is formed on two surfaces facing each other out of the four side surfaces and is opened.
Each porous ceramic sintered body 1 is horizontally attached to an unopened side surface of the frame body 2 so that the inclination angle of the flat pores with respect to the horizontal plane becomes 0 °. In addition, the porous ceramic sintered body 1 is arranged in the frame 2 at regular intervals. Between the porous ceramic sintered bodies 1, spaces 3 serving as air passages are formed by the arrangement at regular intervals.
In the outdoor heat exchanger cooling device 4 of the present example, air can be passed through the space 3 and brought into contact with the porous ceramic sintered body 1 for cooling by passing air from one of the openings toward the other. .

A second specific example of the outdoor heat exchanger cooling device of the present embodiment will be described.
The cooling device for the outdoor heat exchanger of the second specific example is the same as the cooling device for the outdoor heat exchanger of the first specific example except that the arrangement of the porous ceramic sintered bodies is different. In this example, as shown in FIG. 3, a stage in which three porous ceramics sintered bodies 1a are arranged at regular intervals in the horizontal direction, and four porous ceramics sintered bodies 1b and 1c are arranged in the horizontal direction. Steps arranged at regular intervals are alternately stacked.
In the stage where the porous ceramic sintered bodies 1a are arranged at regular intervals in the horizontal direction, all the three porous ceramic sintered bodies 1a have the same shape. At the stage where the four porous ceramic sintered bodies 1b and 1c are arranged at regular intervals in the horizontal direction, the two porous ceramic sintered bodies 1b adjacent to the frame body 2 have the same shape, and the center 2 The individual porous ceramic sintered bodies 1c have the same shape. In addition, the porous ceramic sintered body 1b adjacent to the frame 2 is thinner than the central porous ceramic sintered body 1c. Moreover, the porous ceramic sintered body 1a and the porous ceramic sintered body 1c have the same shape.
In the outdoor heat exchanger cooling device 4 of this example, the space 3 is formed between the porous ceramic sintered bodies adjacent to each other in the horizontal direction, and the adjacent spaces 3 and 3 do not overlap each other. ing. Therefore, in the outdoor heat exchanger cooling device 4 of this example, the air can be cooled by bringing the porous ceramic sintered bodies 1a, 1b, and 1c into contact with each other by passing the air through the space 3.

A third example of the outdoor heat exchanger cooling device of the present embodiment will be described.
As shown in FIGS. 4 and 5, the cooling device for an outdoor heat exchanger according to the third specific example includes a plurality of porous ceramics sintered bodies 11, a frame body 12, and a plurality of insertion rods 14.
The porous ceramic sintered body 11 used in this specific example is a disk-shaped body, and a plurality of flat pores are formed in parallel inside thereof. The flat pores are formed so that the direction in which the diameter is long is perpendicular to the thickness direction of the porous ceramic sintered body 11. A through hole 11a is formed in the center of the disk-shaped porous ceramic sintered body 11 along the thickness direction.
The frame 12 has a rectangular parallelepiped shape, and includes a rectangular bottom plate portion 12a, a column portion 12b erected from each corner of the bottom plate portion 12a, and a top plate portion 12c removably mounted on the column portion 12b. Become. In the present embodiment, the frame body 12 and the insertion rod 14 are made of stainless steel, but are not particularly limited thereto, and can be appropriately selected.
The insertion rod 14 is disposed along the vertical direction with respect to the bottom plate portion 12a and the top plate portion 12c of the frame body 12, and one end is fixed to the bottom plate portion 12a. The thickness of the insertion rod 14 is slightly smaller than the through hole 11 a of the porous ceramic sintered body 11. The plurality of insertion rods 14, 14 are arranged in a row, and the interval between the insertion rods 14, 14 is made shorter than the diameter of the disk-shaped porous ceramic sintered body 11. Further, the other end of the insertion rod 14 is fixed to the top plate portion 12c by a stopper 15 (in this example, a nut) to prevent the tipping over.

  Each porous ceramic sintered body 11 is horizontally disposed so that the through hole 11a is inserted into the insertion rod 14 and the inclination angle of the flat pores with respect to the horizontal plane is 0 °. The flat pores are formed so that the direction in which the diameter is long is perpendicular to the thickness direction of the porous ceramic sintered body 11. Moreover, the porous ceramic sintered bodies 11 are alternately arranged so that a space 13 is formed between the porous ceramic sintered bodies 11 and 11.

  As a method for producing the outdoor heat exchanger cooling device, for example, with the top plate portion removed, the through hole 11a of the porous ceramic sintered body 11 is inserted into the insertion rod 14 as shown in FIG. A method of attaching the top plate portion 12c to the column portion 12b after all the porous ceramic sintered bodies 11 have been inserted can be mentioned.

  Also in the outdoor heat exchanger cooling device of this example, air can be brought into contact with the porous ceramic sintered body 11 and cooled by passing air through the space 13.

A fourth example of the outdoor heat exchanger cooling device of the present embodiment will be described.
As shown in FIGS. 7 and 8, the outdoor heat exchanger cooling device of the fourth specific example includes a plurality of porous ceramic sintered bodies 21, a plurality of insertion rods 24, a stopper 25, and a protection plate 26. .
The porous ceramic sintered body 21 used in this example is a disk-shaped body, and a plurality of flat pores are formed in parallel inside thereof. Two through holes 21 a are formed in the vicinity of the periphery of the disk-shaped porous ceramic sintered body 21 along the thickness direction. These two through-holes 21a and 21a have the same distance from the center of the porous ceramic sintered body 21, and when the two through-holes 21a and 21a are connected with a straight line, the straight line becomes the porous ceramic sintered body. It is formed so as to pass through the center of the bonded body 21.
The thickness of the insertion rod 24 is slightly smaller than the through hole 21 a of the porous ceramic sintered body 21. The plurality of insertion rods 24, 24 are arranged in a row, and the interval between the insertion rods 24, 24 is made shorter than the diameter of the disk-shaped porous ceramic sintered body 21.
The protection plate 26 has a disk shape with the same diameter as the porous ceramic sintered body 21. In the vicinity of the periphery of the protective plate 26, a through hole 26a is formed at a position corresponding to the through hole 21a when the porous ceramic sintered body 21 is stacked.
In the present embodiment, the protective plate 26 and the insertion rod 24 are made of stainless steel, but are not limited thereto and can be selected as appropriate.

  Each porous ceramic sintered body 21 is horizontally arranged so that the through hole 21a is inserted into the insertion rod 24 and the inclination angle of the flat pores with respect to the horizontal plane is 0 °. Moreover, the porous ceramic sintered bodies 21 are alternately arranged so that a space 23 is formed between the porous ceramic sintered bodies 21 and 21.

Examples of a method for producing the outdoor heat exchanger cooling device include the following methods.
First, after attaching the stopper 25 to one end of the insertion rod 24, the through hole 26a of the protective plate 26 is inserted into the insertion rod 24, and the top plate is removed as shown in FIG. The through hole 21 a of the porous ceramic sintered body 21 is inserted into the insertion rod 24. The porous ceramic sintered bodies 21 and 21 adjacent to each other in the vertical direction are inserted into the common insertion rod 14 only in one through hole 21a. The other through-hole 21a of the upper porous ceramic sintered body 21 and the other through-hole 21a of the lower porous ceramic sintered body 21 are each inserted into another insertion rod 24. After all the porous ceramic sintered bodies 21 have been inserted into the insertion rod 24, the other end of the insertion rod 24 is inserted into the through hole 26a of the other protective plate 26, and a stopper is attached to this end. After attaching 25, a top plate part is attached to a pillar part.

Moreover, in the cooling apparatus for outdoor heat exchangers of this example, the porous ceramic sintered body 21 can be rotated about each insertion rod 24 as a rotation axis. Therefore, in the cooling device for an outdoor heat exchanger of this example, as shown in FIG. 10, the arrangement of the porous ceramic sintered bodies 21 can be meandered in a top view, and the corrugated plate can be bent in a zigzag manner. it can. In such a corrugated outdoor heat exchanger cooling device, the contact area of the air supplied to the outdoor heat exchanger can be increased, and the cooling performance of the air becomes higher.
Moreover, in the cooling device for outdoor heat exchangers of this example, since the shape in the width direction can be arbitrarily changed, it can be bent along the outer periphery of the outdoor heat exchanger.

In addition, the cooling device for outdoor heat exchangers of this embodiment is not limited to said specific example. For example, the outdoor heat exchanger cooling device of the present embodiment may be one in which the outdoor heat exchanger cooling devices of each example are arranged in series, or the outdoor heat exchanger cooling device of the first to fourth specific examples. Any two or more of them may be arranged in series.
When a plurality of outdoor heat exchanger cooling devices are arranged in series, the space of each outdoor heat exchanger cooling device is zigzag along the air flow direction so that the air flow is not linear. If the space is arranged in this way, the air cooling effect is further enhanced. However, since the resistance in the air flow increases, the load of the blower fan tends to increase and the amount of electricity consumed tends to increase.

The space in the outdoor heat exchanger cooling device in the first to fourth specific examples may be filled with a granular porous ceramic sintered body.
Further, the direction of the long diameter of the flat pores formed inside the porous ceramic sintered body is another embodiment in which the inclination angle with respect to the horizontal plane is more than 30 °, for example, 45 ° or 90 °. There may be. In this other embodiment, when the inclination angle of the long diameter of the flat pores with respect to the horizontal plane is more than 30 °, water contacts the lower surface of the porous ceramic sintered body. It is preferable to provide a water tank so that water is supplied into the porous ceramic sintered body.

Since the outdoor heat exchanger cooling device of the present embodiment described above includes the outdoor heat exchanger cooling member, it has excellent air cooling performance over a long period of time. Therefore, the temperature of the air supplied to the outdoor heat exchanger used for the cooling facility can be reduced to save energy in the cooling facility.
Moreover, the maintenance for maintaining the cooling performance of the outdoor heat exchanger cooling device is easy.

  EXAMPLES Hereinafter, although an Example is shown and embodiment of this invention is described in detail, this invention is not limited by the following description.

(Raw materials used)
The raw materials used in the examples are as follows.
<Organic sludge>
As the organic sludge, the activated sludge discharged from the wastewater treatment facility by the activated sludge method of the dyeing factory (Komatsu Seiren Co., Ltd.) through the coagulation / dehydration process was used. The organic matter content (relative to the solid content) of the activated sludge was 83% by mass with respect to the total mass in the sludge measured after drying. Moreover, the dry sludge mass in the dehydrated sludge was determined from the mass after aggregation / dehydration and after drying (dried at 105 to 110 ° C. for 2 hours), and the water content of the activated sludge determined therefrom was 85% by mass. .
<Clay>
As the clay, Sakaime clay (produced in Gifu Prefecture or Aichi Prefecture) was used.
<Foaming agent (slag)>
Cast iron slag was used as a foaming agent. The cast iron slag _is a ductile iron slag _{SiO 2, Al 2 O 3,} CaO, Fe 2 O 3, FeO, MgO, MnO, the _{K 2} O and Na ₂ O as main components.
<Diatomaceous earth>
As the diatomaceous earth, powdered diatomaceous earth having a moisture content of 5% by mass was used as a raw material for refractory bricks from the Noto area.
<Filler>
As a filler, the thing which grind | pulverized the waste glass of the glass panel for flat displays of liquid crystal television, and was used as the particle | grains of the high melting glass was used. The particles of the high-melting glass pass through a sieve having an opening of 1.2 mm and do not pass through a sieve having an opening of 0.6 mm (particle diameter greater than 0.6 mm and 1.2 mm or less). Moreover, the said glass panel is a non-alkali glass with a melting temperature exceeding 1300 degreeC, and is not provided with the polarizing plate.

[Example 1]
Slag, organic sludge, clay, and water were mixed with a mix muller (manufactured by Shinto Kogyo Co., Ltd.) with the composition shown in Table 1 to obtain a plastic mixture (mixing step).
Subsequently, the obtained mixture was extruded with a vacuum kneading machine (manufactured by Takahama Kogyo Co., Ltd.) and rolled to obtain a band-shaped primary molded body having a width of 60 cm and a thickness of 2 cm. The primary molded body was cut at an arbitrary pitch and width to obtain a substantially square flat plate-shaped molded body having a thickness of 2 cm (molding step).
The obtained molded body was dried with a hot air dryer (180 ° C., 0.5 hour) to a moisture content of 1% by mass or less, and then using a continuous sintering furnace, the firing temperature was 1050 ° C. at the firing temperature. Firing was performed under firing conditions of a residence time of 7 minutes (firing step). As the continuous sintering furnace, a roller hearth kiln (effective length of the sintering furnace: total length 15 m, the sintering furnace was divided into zones 1 to 10 each having a length of 1.5 m) was used.
After firing, side edges were cut along the four side surfaces of the porous ceramic sintered body and trimmed, and the surface of the porous ceramic sintered body was ground. As a result, a plate of porous ceramic sintered body having a length of 20 cm, a width of 30 cm, and a thickness of 3 cm was obtained. This porous ceramic sintered body was formed such that a plurality of flat pores having a pore diameter (major axis) of about 3 cm and a thickness of about 1 mm were arranged in parallel in the thickness direction.
The porous ceramic sintered body was immersed in water to obtain a saturated water-containing state.

  Next, as shown in FIG. 1, five porous ceramic sintered bodies 1 are horizontally arranged in a frame 2 having a width of 30 cm, a height of 36 cm, and a depth of 20 cm to form a cooling member for an outdoor heat exchanger. Thus, a cooling device for the outdoor heat exchanger was obtained. The arrangement of each porous ceramic sintered body 1 is such that the side of 30 cm × 3 cm is the front (depth 20 cm), the inclination angle of the flat pores with respect to the horizontal plane is 0 °, and the porous ceramic sintered body 1 is porous The ceramic sintered bodies 1 and 1 were arranged so that the distance between them was approximately 3 cm.

[Example 2]
Example except that the composition of the mixture was changed as shown in Table 1 and the size of the porous ceramic sintered body was changed to two types of length 20 cm × width 8 cm × thickness 3 cm, length 20 cm × width 4 cm × thickness 3 cm. In the same manner as in Example 1, a porous ceramic sintered body was obtained.
The outdoor heat exchanger cooling device was the same as in Example 1 except that a porous ceramic sintered body as shown in FIG. 3 was placed in a frame having a width of 30 cm, a height of 36 cm, and a depth of 20 cm. Thus, a cooling device for the outdoor heat exchanger was obtained.
As the porous ceramic sintered bodies 1a and 1c in FIG. 3, those having a length of 20 cm, a width of 8 cm, and a thickness of 3 cm were used, and the porous ceramic sintered bodies 1a and 1c were arranged so that the surface of 8 cm × 3 cm was the front. As the porous ceramic sintered body 1b, a 20 cm vertical x 4 cm wide x 3 cm thick one was used, and the 4 cm x 3 cm surface was placed in front.
The interval between the porous ceramic sintered bodies adjacent to each other in the horizontal direction was set to 3 cm. The number of stages of the porous ceramic sintered body was 12.
Each porous ceramic sintered body was arranged so that the inclination angle of the flat pores with respect to the horizontal plane was 0 °.

[Example 3]
Example except that the composition of the mixture was changed as shown in Table 1 and the size of the porous ceramic sintered body was changed to two types of length 20 cm × width 8 cm × thickness 3 cm, length 20 cm × width 4 cm × thickness 3 cm. In the same manner as in Example 1, a porous ceramic sintered body was obtained. Using this porous ceramic sintered body, an outdoor heat exchanger cooling device was obtained in the same manner as in Example 2.

[Example 4]
The composition of the mixture was changed as shown in Table 1, and the filler was blended in 30 parts by mass with respect to 100 parts by mass of the raw material other than the filler, the surface grinding was omitted, and the size was vertical 20 cm x horizontal 8 cm x thickness 3 cm. A porous ceramic sintered body was obtained in the same manner as in Example 1 except that the length was 20 cm × width 4 cm × thickness 3 cm. Using this porous ceramic sintered body, an outdoor heat exchanger cooling device was obtained in the same manner as in Example 2.

(Measurement / Evaluation)
The apparent density, saturated water content, and presence / absence of communication between pores of the obtained cooling member were measured as follows. Moreover, the performance of the cooling device for outdoor heat exchangers was measured as follows. The results are shown in Table 1.

<Apparent density>
Using a caliper, the length, width, and thickness of the porous ceramic sintered body were measured to determine the volume (cm ³ ), and the mass (g) of the porous ceramic was measured. And the apparent density was calculated | required from the formula of [the mass (g) of the completely dry porous ceramics] / [volume of the porous ceramics (cm ³ )].

<Saturated water content>
After the plate-like porous ceramic sintered body whose apparent density has been measured is immersed in water for 60 minutes, the porous ceramic sintered body is prevented from flowing out of the porous ceramic sintered body when the surface is turned upside down and tilted. The ligature was removed from the water without tilting. Next, excess moisture adhering to the surface of the porous ceramic sintered body was wiped with a cloth, the mass was immediately measured (saturated mass), and the saturated moisture content was determined by the following equation (1).
Saturated water content (mass%) = [(saturated mass−absolute dry mass) / absolute dry mass] × 100 (1)

<Confirmation of communication between pores>
Confirmation of the presence or absence of communication between pores in the porous ceramic sintered body was confirmed by immersing the obtained porous ceramic sintered body in water, sufficiently absorbing water, cutting it, and observing its cross section. . As a result of this observation, when it was recognized that moisture was evenly distributed and retained in the porous ceramic sintered body, it was judged that the pores communicated with each other (indicated in the table as “○”). ) As a result of this observation, when it is recognized that moisture does not spread inside the porous ceramic sintered body, the individual pores or pores are independent and the pores are not in communication or inadequate communication. It was judged that it was present (indicated by “x” in the table, meaning “poor”, which is not included in this example).

<Performance measurement of outdoor heat exchanger cooling system: Measurement of fan fan load and air temperature>
Using the apparatus shown in FIG. 11, the load of the blower fan and the air temperature were measured.
The blower fan 5 was installed in a container 7 having openings 7a and 7b on the side surfaces facing each other, air was sucked in from one opening 7a, and air was exhausted from the other opening 7b. Air movement is indicated by A. Here, the blower fan 5 is assumed to be a blower fan for sending air to the outdoor heat exchanger, and is installed in the vicinity of the opening 7b on the downstream side.
Moreover, the cooling device 4 for outdoor heat exchangers was attached to the vicinity of the opening part 7a. The opening 7 a has the same area and shape as the surface of the maximum area of the outdoor heat exchanger cooling device 4.
Then, a distance L1 (l1 = 19 cm in the figure) from the installation surface, a distance L2 (l2 = 5 cm in the figure) upstream from the outdoor heat exchanger cooling device 4 (intake temperature measurement position 81), and outdoor heat exchange. The temperature of the air (suction temperature, intake air temperature) was measured at each position in the container 7 (intake air temperature measurement position 82) at a distance L3 (L3 = 3 cm in the figure) from the device cooling device 4.
At that time, the wind speed from the blower fan 5 was adjusted using the variable transformer 6 so as to be 3 m / sec at a position 8 cm from the air exhaust port. By reading the voltage of the variable transformer 6 at this time, it was confirmed whether or not the power consumption of the blower fan 5 was increased by using the outdoor heat exchanger cooling device 4.
Further, as a comparison, the measurement was also performed with the outdoor heat exchanger cooling device 4 not installed and the opening 7a opened (Comparative Example 1, suction port release).

In Example 1 using the outdoor heat exchanger cooling device including the outdoor heat exchanger cooling member according to this embodiment, the intake air temperature after passing through the outdoor heat exchanger cooling device is 1.5 ° C. lower than the suction temperature. It was. In Example 2, the intake air temperature after passing through the outdoor heat exchanger cooling device was 2.7 ° C. lower than the intake temperature. In Example 3, the intake air temperature after passing through the outdoor heat exchanger cooling device was 2.3 ° C. lower than the intake temperature. In Example 4, the intake air temperature after passing through the outdoor heat exchanger cooling device was 1.8 ° C. lower than the intake temperature. In Comparative Example 1 (intake port release), it was also confirmed that there was almost no difference between the intake temperature and the intake temperature.
Therefore, in Examples 1-4, the air supplied to an outdoor heat exchanger can be cooled, and the heat exchange efficiency of a cooling facility can be raised. Further, it was confirmed that the supply voltage to the blower fan did not change much compared to the case where the outdoor heat exchanger cooling device was not installed, that is, the power consumption did not change so much and contributed to energy saving.
In addition, in the cooling member for outdoor heat exchangers of Examples 1 to 4, although depending on the outside air temperature and the air flow rate, sufficient water is stored by 1 to 3 degrees of rain per week, and frequent watering is necessary. In addition, since the soil of the outdoor heat exchanger cooling member does not flow out and lose the cooling effect, and weeds do not grow frequently, maintenance is easy.

  The outdoor heat exchanger cooling member and the outdoor heat exchanger cooling device according to the aspect of the present invention can reduce the temperature of the air supplied to the outdoor heat exchanger used in the air conditioning equipment to save energy in the air conditioning equipment. Easy maintenance.

1,1a, 1b, 1c, 11,21 Porous ceramic sintered body (cooling member for outdoor heat exchanger)
2,12 Frame 3,13,23 Space 4 Cooling device for outdoor heat exchanger 5 Blower fan 6 Variable transformer 7 Container 12a Bottom plate portion 12b Column portion 12c Top plate portion 14, 24 Insertion rod 15, 25 Stopper 81 Intake temperature Measurement position 82 Intake air temperature measurement position A Air movement L1, L2, L3 Distance

Claims (6)

  A cooling member for an outdoor heat exchanger comprising a porous ceramic sintered body having a saturated moisture content of 25% by mass or more and 100% by mass or less.   The cooling member for an outdoor heat exchanger according to claim 1, wherein the porous ceramic sintered body is a plate-like object.   The cooling member for an outdoor heat exchanger according to claim 1 or 2, wherein flat pores are formed inside the porous ceramic sintered body.   The cooling member for an outdoor heat exchanger according to any one of claims 1 to 3, wherein a surface of the porous ceramic sintered body is ground.   The cooling device for outdoor heat exchangers provided with the cooling member for outdoor heat exchangers as described in any one of Claims 1-4.   The outdoor heat exchanger cooling member according to claim 3, wherein the flat pores inside the porous ceramic sintered body are arranged so that the inclination angle is 30 ° or less with respect to the horizontal plane. Cooling system.

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