JP6463531B2 - Snow melting block and snow melting roadbed - Google Patents

Description

  The present invention relates to a snow melting block and a snow melting roadbed, and more specifically, a first layer made of foamed concrete using at least the following (a), (b) and (c) as raw materials, (a) a heat insulating material, (B) sand, (c) cement; and formed on the first layer, and using at least the following (d), (e), (f), (g) and (h) as raw materials, A second layer composed of concrete, (d) a far-infrared radiation material, (e) steel slag, (f) sand, (g) gravel, (h) cement; The present invention relates to a snow melting block including a mesh-shaped reinforcing material and a heating element in contact with a layer or in the vicinity of the contact surface, and a snow melting roadbed constituted by the snow melting block.

  In roads and passages such as roadways and sidewalks where people, cars, bicycles and the like pass, those road surfaces are usually formed by asphalt pavement or concrete pavement. In cold regions, the road surface becomes slippery due to snow and freezing in the winter, increasing the risk of slipping and falling accidents such as cars, bicycles, and pedestrians. A so-called snow melting device for melting snow and ice, such as a heat pipe supplied with heat and an electric heater that generates heat when energized, is embedded.

  Also, depending on the characteristics, environment, and usage of the road or passage, the road surface may be formed by laying paving blocks made of asphalt material, concrete, mortar, resin, rubber, etc. on the roadbed. . In the case of general asphalt pavement and concrete pavement, the snow melting device is buried at the time of pavement, but when the road surface is formed by the pavement block, a pavement block (snow melting block) with a snow melting function is laid on the ground. Yes.

  As such a snow melting block, for example, a heat insulating material, a heat diffusing material provided on the heat insulating material, a heating element provided on the heat diffusing material, and a concrete molded part precast-molded so as to embed them. A heat generating block (Patent Document 1) including a surface layer, a far infrared radiation layer including natural ore formed by depositing diatoms as a far infrared radiation material, and a heat generation layer for heating the far infrared radiation layer Snow melting device (Patent Document 2), a rectangular thin plate front-end snow melting unit (Patent Document 3) in which a heating element is laid in a resin frame and concrete mixed with a far-infrared radiation material and heat storage / reinforcing material is poured In addition, a heat storage layer is provided on the ground that generates geothermal heat, an artificial heat source is provided thereon, a heat transfer / heat radiation layer is further laminated thereon, and a far infrared radiation layer is further laminated thereon as desired. Snow melting cis (Patent Document 4), comprising a base plate portion having a porous structure having legs, and a lattice-like or mesh-like support plate portion and a support plate portion that are held and engaged with the support plate portion for external power supply An example of a heat-generating block for snow melting and heat insulation (Patent Document 5) in which a linear or belt-like long heating element portion that can be connected is provided.

JP 2001-193008 A JP 2006-249770 A JP 2010-024693 A JP-A-11-222803 Japanese Patent Laid-Open No. 2015-135027

  However, in the heating block disclosed in Patent Document 1, the heat diffusing material and the heating element are covered with the concrete molding part, so that the heat generated from the heating element is absorbed by the concrete molding part. As a result, the heat generated from the heating element does not reach the surface of the heating block, resulting in poor snow melting effect.

  Further, in the snow melting device disclosed in Patent Document 2, a heat generating layer is formed on the heat insulating layer, and a far infrared emitting layer including a far infrared emitting material is formed on the upper layer of the heat insulating layer. Where the water-permeable rubber chip elastic pavement layer containing the infrared radiation material is disposed, the exposed layer has low strength because the top layer is the water-permeable rubber chip elastic pavement layer, while the heat insulation layer and the far infrared radiation layer are water permeable. Since water permeability is poor compared to rubber chip elastic pavement layer, the water generated by melting snow and icing on the exposed surface will not flow underground from the pavement layer, resulting in saturation of the pavement layer with that water. As a result, the exposed surface overflows, so that the snow melting efficiency decreases as the snow accumulation on the exposed surface and the melting of icing progress.

  Further, in the frontage snow melting unit disclosed in Patent Document 3, a foam heat insulating material, an aluminum vapor-deposited heat insulating sheet, and a reinforcing bar are laid in order from the lowest layer, and a high power heater or a heat radiating pipe is further laid. As a result, concrete mixed with carbon and steel fiber as heat storage / reinforcing material is poured and hardened. As a whole, the strength against compression is guaranteed, but the tensile strength is inferior. In addition to being unsuitable as a block, as with the snow melting device disclosed in Patent Document 2, concrete mixed with carbon as a far-infrared radiation material and steel fiber as a heat storage / reinforcement material has poor water permeability and is exposed to concrete. The exposed surface is exposed to water generated as the surface snow and icing melt. It will be one after another accumulated again, resulting in lowered snow melting efficiency as melting of snow and ice of the exposed surface progresses.

  On the other hand, in the case of the snow melting system disclosed in Patent Document 4, although there is a description in the document that a material that contributes to appropriate heat storage and heat insulation is used for the heat storage layer, the heat storage layer It is clear that it has no heat insulation because it absorbs geothermal heat released from the ground, and therefore heat generated from an artificial heat source in general places where geothermal heat is not released from the ground. It is difficult to melt the snow on the snow melting system because the heat is not transmitted to the heat transfer / heat dissipation layer laminated on the heat storage layer.

  On the other hand, in the case of the heat-generating block for snow melting and heat insulation disclosed in Patent Document 5, since it has a porous structure, it has water permeability and water permeability, but gravel, pebbles, rock fragments, lava stone Since granular materials such as crushed bodies, concrete crushed bodies, and ceramic crushed bodies are used as materials, there is a doubt that they may be denatured by long-term use and have weather resistance. Since it has a qualitative structure, structural strength is difficult. In addition, since the connectors cannot be connected in series and become parallel, the resistance value increases, and as a result, the amount of power consumption becomes enormous.

  Therefore, the present invention has been made to solve the above-described problems, and heat generated from the heating element is easily conducted to the surface (exposed surface) of the second layer or the third layer which is the uppermost layer. Since the first layer is well insulated and heat is easily stored inside the second layer, it is easy to melt by supplying abundant heat due to radiant heat on the surface (exposed surface) of snow and icing. The water generated by the melting of ice and icing does not collect on the surface (exposed surface), but permeates into the interior and flows into the ground. As a result, power consumption can be greatly reduced compared to conventional snow melting blocks and snow melting roadbeds. Excellent heat insulation, abundant calorific value, excellent heat storage, high water permeability, and structural strength , Especially snow melting blocks with high compression strength and And to provide a snow melting roadbed composed of snow-melting block.

  As a result of diligent research, the present inventors, as a result of diligent research, at least a first layer composed of foamed concrete made from a heat insulating material, sand and cement as raw materials, at least a far-infrared radiation material, steel slag, sand and gravel. A second layer made of concrete made of cement as a raw material, and by providing a mesh-like reinforcing material and a heating element near or in contact with the first layer and the second layer, A third layer composed of at least one or more sand selected from the group consisting of olivine sand, silica sand, zircon sand and chromite sand, a far-infrared radiation material, steel slag, and a mortar made of cement. Thus, it is possible to form a snow melting block having a high structural strength, particularly a high compressive strength, and the heat generated from the heating element of the snow melting block is the uppermost layer. It becomes easy to conduct to the surface (exposed surface) of a certain second layer or third layer, and heat is firmly insulated in the first layer and heat is easily stored inside the second layer. As a result, the surface (exposed surface) Abundant amount of heat due to radiant heat can be supplied to snow cover and ice accretion, and the water generated by melting of the snow cover and ice osmosis sequentially penetrates into the interior and flows into the ground. As a result, it was found that the power consumption can be greatly reduced as compared with conventional snow melting blocks and snow melting roadbeds, and the following inventions have been completed.

(1) a first layer composed of foamed concrete using at least the following (a), (b) and (c) as raw materials, (a) a heat insulating material, (b) sand, (c) cement; A second layer made of concrete, formed on the first layer and made of at least the following (d), (e), (f), (g) and (h): (d) A far-infrared radiation material, (e) steel slag, (f) sand, (g) gravel, (h) cement; and in contact with the first layer and the second layer or in the vicinity of the contact surface A snow melting block provided with a mesh-shaped reinforcing material and a heating element, wherein the ratio of the raw materials of the foamed concrete constituting the first layer and the concrete constituting the second layer is the following (A) and (B) At least one of the snow melting blocks; (A) constituting the first layer The ratio of the raw material of the foamed concrete is such that (a) the heat insulating material is 150 to 250 parts by volume with respect to (c) 100 parts by volume of the cement, and (b) ) Sand is 50 to 300 parts by volume; (B) The ratio of the raw materials of the concrete constituting the second layer is (d) far from (h) cement and (e) 100 parts by volume of steel slag. The infrared radiation material is 1 to 20 parts by volume, the (f) sand is 50 to 350 parts by volume with respect to the (h) cement and (e) 100 parts by volume of the steel slag, and the (h) Said (g) gravel is 150 to 450 parts by volume with respect to 100 parts by volume of cement and (e) steel slag.

(2) at least the following (a), (b) and (c) as a raw material, a first layer composed of foamed concrete, (a) heat insulating material, (b) sand, (c) cement; A second layer made of concrete, formed on the first layer and made of at least the following (d), (e), (f), (g) and (h): (d) A far-infrared radiation material, (e) steel slag, (f) sand, (g) gravel, (h) cement; and at least the following (i), (j), A third layer composed of mortar, using (k) and (l) as raw materials, (i) one or more sands selected from the group consisting of olivine sand, quartz sand, zircon sand and chromite sand, (j A far infrared radiation material, (k) steel slag, and (l) cement. A snow melting block comprising a mesh-like reinforcing material and a heating element in contact with or in the vicinity of the second layer, foamed concrete constituting the first layer, concrete constituting the second layer, and The snow melting block in which the ratio of the raw material of the mortar constituting the third layer is at least one of the following (A), (B) and (C); (A) the raw material of the foamed concrete constituting the first layer The ratio of (c) 100 parts by volume of the cement is 150 to 250 parts by volume of the (a) heat insulating material, and (c) 100 parts by volume of the cement (b) 50% of the sand. (B) The ratio of the raw materials of the concrete constituting the second layer is (d) the far-infrared radiation material (d) with respect to (h) cement and (e) 100 parts by volume of steel slag. To 20 parts by volume, and (f) 50 to 350 parts by volume of (f) sand with respect to 100 parts by volume of (h) cement and (e) steel slag, and (h) cement and (e And (g) gravel is 150 to 450 parts by volume with respect to 100 parts by volume of steel slag; (C) the proportion of raw materials of mortar constituting the third layer is (l) cement and (k) steel One or more sands selected from the group consisting of (i) olivine sand, silica sand, zircon sand and chromite sand are 100 to 200 parts by weight with respect to 100 parts by weight of slag, and (l) cement And (j) 1-20 weight part of said (j) far-infrared radiation | emission materials are with respect to 100 weight part of said steel slag.

(3) The snow melting block according to (2), wherein a suspended portion is formed on the surface layer of the third layer.

(4) The snow melting block according to any one of (1) to (3), wherein the heat insulating material is a resin foam.

(5) The snow melting block according to any one of (1) to (4), wherein the mesh-shaped reinforcing material and the heating element are mesh heaters.

(6) A snowmelt roadbed comprising the snowmelt block according to any one of (1) to (5).

  According to the snow melting block and the snow melting roadbed according to the present invention, it is possible to provide a snow melting block having a high structural strength, in particular, a high compressive strength. It is easy to conduct to the surface (exposed surface) of the snowmelt roadbed, and it can supply abundant amount of heat due to radiant heat to the snow and icing on the surface (exposed surface) to quickly melt the snow and icing. In addition, the water generated by melting these snow accumulations and ice accretion can be passed through the snow melting block or the snow melting roadbed in sequence and flow into the ground. It can be melted and power consumption can be greatly reduced compared to conventional snow melting blocks and snow melting roadbeds. Moreover, since the raw material is inexpensive, the manufacturing cost of the snow melting block can be suppressed, and since the snow melting block itself has a simple form, it can be easily laid.

It is a longitudinal cross-sectional view of 1st Embodiment of the snow melting block which concerns on this invention. 1 is an exploded perspective view of a first embodiment of a snow melting block according to the present invention. It is a longitudinal cross-sectional view of 2nd Embodiment of the snow melting block which concerns on this invention. It is a disassembled perspective view of 2nd Embodiment of the snow melting block which concerns on this invention. It is a longitudinal cross-sectional view of 3rd Embodiment of the snow melting block which concerns on this invention. It is a longitudinal cross-sectional view of 4th Embodiment of the snow melting block which concerns on this invention. It is the longitudinal cross-sectional view and top view of embodiment of the snowmelt roadbed which concern on this invention. It is a figure which shows the dimension measurement location of the snow melting block 1 of this 2nd Embodiment which is a test body.

  Hereinafter, 1st Embodiment of the snow melting block which concerns on this invention is described in detail using drawing. As shown in FIGS. 1 and 2, the snow melting block 1 of the first embodiment includes a first layer 2 and a second layer 3, and a contact surface 5 or a contact between the first layer 2 and the second layer 3. A mesh-like reinforcing material 51 and a heating element 52 are provided in the vicinity of the surface 5. Hereinafter, each configuration will be described in detail.

  In the snow melting block 1 of the first embodiment, the first layer 2 is made of foamed concrete using at least (a) a heat insulating material, (b) sand, and (c) cement as raw materials, and the second layer 3 is , At least (d) far infrared radiation material, (e) steel slag, (f) sand, (g) gravel, and (h) concrete made from cement. In the first layer 2 and the second layer 3 of the snow melting block 1 of the first embodiment, “at least” means that the foamed concrete constituting the first layer 2 does not impair the characteristics of the present invention. (A) Insulating material, (b) Sand and (c) Substances other than cement are also included in the range of the snow melting block 1 of the first embodiment, and constitute the second layer 3. As long as the concrete does not impair the characteristics of the present invention, (d) far-infrared radiation material, (e) steel slag, (f) sand, (g) gravel and (h) materials other than cement may be used as raw materials. This is to be included in the range of the snow melting block 1 of the first embodiment.

  In general, “foamed concrete” is also referred to as cellular concrete. In addition to heat insulating material, sand, cement, water and gravel as needed are mixed into the concrete to make it porous with small bubbles. A lightweight, lightweight concrete with excellent heat insulation. In the “foamed concrete” in the snow melting block 1 of the first embodiment, the heat insulating material plays the role of gravel to form a void.

  The “heat insulating material” in the snow melting block 1 of the first embodiment is not particularly limited as long as it uses a material having low heat transfer properties. Examples of such a heat insulating material include sawdust and hollow glass beads. , Shirasu balloon, perlite, silica powder, glass wool, felt, silica-alumina powder, foaming material, foaming material having water resistance, strong corrosion resistance, and excellent thermal insulation, A resin-based foam material is more preferable. Examples of the resin-based foam material include foamed polystyrene, foamed urethane, foamed polystyrene, foamed polyethylene, and the like. Among them, foamed polystyrene having water resistance, resistance to corrosion, and excellent heat insulation is more preferable.

  As described above, the first layer 2 in the snow melting block 1 of the first embodiment constituted by at least (a) a heat insulating material, (b) sand, and (c) foamed concrete generated using cement as a raw material is excellent. Since it has both water permeability, water resistance, and heat insulation properties, it can store heat firmly in the second layer 3 of the snow melting block 1 by using heat generated from the heating element 52 as radiant heat, as well as snow accumulation on the surface (exposed surface) of the snow melting block 1 and Water generated by melting of the icing can be sequentially permeated into the snow melting block 1 to flow into the ground, and as a result, the snow and icing can be continuously melted. In addition, it is preferable not to use gravel whose voids increase when used, whereby the structural strength, particularly the compressive strength, can be increased.

  In the snow melting block 1 of the first embodiment, the proportions of (a) heat insulating material, (b) sand and (c) cement, which are raw materials of the foamed concrete constituting the first layer 2, are the same as those in (c) cement. It is preferable that (a) the heat insulating material is 150 to 250 parts by volume with respect to 100 parts by volume, and (b) the sand is 50 to 300 parts by volume with respect to 100 parts by volume of the cement. It is. By such blending, in general, in foamed concrete having a low structural strength, the structural strength, particularly the compressive strength, can be further increased, and the water permeability, water resistance and heat insulation can be further increased.

  In the snow melting block 1 of the first embodiment, the “far infrared radiation material” refers to a material having high thermal conductivity that emits far infrared rays when heat is applied. In the snow melting block 1 of the first embodiment, The far-infrared emitting material is not particularly limited as long as it emits far-infrared when heat is applied and has high thermal conductivity, but emits far-infrared rays of 3 to 20 μm in view of the intended purpose of melting snow and preventing freezing. Those which emit far infrared rays of 5 to 20 μm are more preferred. Examples of such far-infrared emitting materials include carbon materials, quartz-based volcanic rocks, granite and rhyolite fine powders mainly composed of silica oxide and alumina oxide, Manchu talc, fly ash (coal ash), and the like. Far-infrared ceramics; zeolite; mica; molybdenum dioxide; metal oxides such as aluminum titanate, aluminum oxide, and magnesium oxide; radium ore; natural formed by depositing diatoms such as graphite silica (black silica, silica black) An ore can be mentioned. In the snow melting block 1 of the first embodiment, one or more can be selected and used, and can be used together with magnetite such as ferrite, but has a characteristic of emitting far infrared rays semipermanently. Therefore, natural ore formed by depositing diatoms is preferable, and graphite silica (black silica, silica black) that emits far infrared rays of 90% or more (4 to 12 μm) at room temperature is more preferable.

“Iron and steel slag” refers to molten solidified products such as metal oxides that are produced at the same time as the production of iron and steel. By refining blast furnace slag that is by-produced when producing pig iron in a blast furnace, hot metal and scrap, etc. The steelmaking slag is classified into a converter slag and an electric furnace slag according to the type of refining furnace. Steel slag is mainly composed of lime (CaO) and silica (SiO ₂ ), and as other components, blast furnace slag contains alumina (Al ₂ O ₃ ), magnesium oxide (MgO) and a small amount of sulfur (S), Steelmaking slag contains iron oxide (FeO) and magnesium oxide (MgO). In addition, since the drainage standard pH is pH 5-9, the steel slag in the snow melting block 1 of the first embodiment is adjusted to the pH of the water in contact (JIS K 0058-1 “Slag chemical test method—first Part: Dissolution amount test method "is not particularly limited as long as it is a steel slag that does not exceed pH 9 in" 5.4 Preparation of test solution ".

  Since all steel slag has hydraulic properties, the strength of concrete and mortar produced using steel slag as a raw material improves with time. In addition, it is known that concrete and mortar produced using steel slag as a raw material have water permeability and water retention. In particular, blast furnace slag is known to give higher water permeability and water retention to concrete and mortar produced using this as a raw material, and can be suitably used. In the snow melting block 1 of the first embodiment, (e) steel slag and (h) cement that are raw materials for the concrete constituting the second layer 3 include (e) steel slag and (h) cement. Slag cement mixed in advance can be suitably used.

  Thus, at least (d) far-infrared radiation material, (e) steel slag, (f) sand, (g) gravel, and (h) concrete made from concrete as a raw material. The second layer 3 in the snow melting block 1 has high structural strength and has excellent water permeability, water resistance, heat storage, thermal conductivity, thermal diffusivity, and is excellent in environment directivity. The heat generated from the body 52 and the heat stored in the second layer 3 of the snow melting block 1 are easily conducted to the surface (exposed surface) of the snow melting block 1, and the snow accumulation and icing on the surface (exposed surface) can be promptly performed. It is possible to melt, and the water generated by melting the snow accumulation and icing can be sequentially permeated into the snow melting block 1 to flow into the ground. As a result, the snow accumulation and icing are continuously conducted. Can be melted.

  In the snow melting block 1 of the first embodiment, (d) far-infrared radiation material, (e) steel slag, (f) sand, (g) gravel and ( h) The proportion of the cement is 1 to 20 parts by volume of the (d) far-infrared radiation material with respect to 100 parts by volume of the (h) cement and (e) the steel slag, and the (h) cement and the ( e) 50 to 350 parts by volume of (f) sand with respect to 100 parts by volume of steel slag, and (g) gravel with respect to 100 parts by volume of (h) cement and (e) steel slag. It is suitable that it is 150-450 volume parts. With such a blend, the structural strength of the second layer 3, particularly the compressive strength, can be further increased, and the water permeability, water resistance, heat storage property, thermal conductivity, thermal diffusivity can be further increased, The amount of power consumption can be further reduced as compared with the snow melting block.

  Further, in the snow melting block 1 of the first embodiment, the ratio of (a) heat insulating material, (b) sand and (c) cement, which are raw materials of the foamed concrete constituting the first layer 2, is the above (c) cement. The (a) heat insulating material is 150 to 250 parts by volume with respect to 100 parts by volume, and the (b) sand is 50 to 300 parts by volume with respect to 100 parts by volume of the cement, and The ratio of (d) far-infrared radiation material, (e) steel slag, (f) sand, (g) gravel, and (h) cement, which are the raw materials of the concrete constituting the second layer 3, is the above (h) cement and The (d) far-infrared radiation material is 1 to 20 parts by volume with respect to 100 parts by volume of the (e) steel slag, and (f) with respect to the (h) cement and the (e) 100 parts by volume of the steel slag. ) 50-350 parts by volume of sand Ri, and it is more preferable wherein the (h) cement and the (e) the relative steel slag 100 parts by volume (g) gravel is 150 to 450 parts by volume. Such a blend can further increase the structural strength, particularly compressive strength, of the snow melting block 1 of the first embodiment, and further increase water permeability, water resistance, heat insulation, heat storage, and thermal conductivity. The power consumption can be further reduced as compared with the conventional snow melting block.

  In addition, the snow melting block 1 of the first embodiment includes the first layer 2 composed of foamed concrete formed by the ratio of the above-described (a) heat insulating material, (b) sand and (c) cement, and the above-mentioned. (D) a far-infrared radiation material, (e) steel slag, (f) sand, (g) gravel, and (h) at least one of the second layers 3 composed of concrete formed by a proportion of cement It only has to be.

  The mesh-like reinforcing material 51 in the snow melting block 1 of the first embodiment is not particularly limited as long as it is a mesh-like reinforcing material 51 that can be appropriately selected by those skilled in the art unless the characteristics of the present invention are impaired. For example, a horizontal mesh line, a wire mesh, etc. can be mentioned. Further, the heating element 52 in the snow melting block 1 of the first embodiment is not particularly limited as long as the heating element 52 can be appropriately selected by those skilled in the art as long as the characteristics of the present invention are not impaired. A heater wire, a heat radiating sheet, a heat radiating pipe and the like arranged in a circulating shape can be exemplified. Furthermore, the mesh-shaped reinforcing material 51 and the heating element 52 in the snow melting block 1 of the first embodiment can be integrated, and as such a mesh-shaped reinforcing material 51 and the heating element 52, For example, a heater wire that is detoured along with the mesh-like reinforcing material 51 and integrated with the mesh-like reinforcing material 51 can be used.

  The snow melting block 1 of the first embodiment as described above can be used alone (only one), but it is preferable to use a plurality (two or more) in combination.

  Next, a second embodiment of the snow melting block according to the present invention will be described in detail with reference to the drawings. As shown in FIGS. 3 and 4, the snow melting block 1 of the second embodiment includes a first layer 2, a second layer 3, and a third layer 4, and the first layer 2 and the second layer 3 are in contact with each other. A mesh-like reinforcing material 51 and a heating element 52 are provided in the vicinity of the surface 5 or the contact surface 5. Hereinafter, each configuration will be described in detail. Note that, in the second embodiment of the snow melting block 1, the same or corresponding / corresponding configurations as those of the first embodiment of the snow melting block 1 described above are denoted by the same reference numerals and the description thereof is omitted.

  In the snow melting block 1 of the second embodiment, the first layer 2 is made of foamed concrete using at least (a) a heat insulating material, (b) sand, and (c) cement as raw materials, and the second layer 3 is , At least (d) far infrared radiation material, (e) steel slag, (f) sand, (g) gravel, and (h) concrete made from cement, and the third layer 4 is at least (i 1) One or more sands selected from the group consisting of olivine sand, quartz sand, zircon sand and chromite sand, (j) far infrared radiation material, (k) steel slag, and (l) mortar made from cement. Has been. In the third layer 4 in the snow melting block 1 of the second embodiment, “at least” means that the mortar constituting the third layer 4 does not impair the characteristics of the present invention, and (i) olivine sand, Even if the raw material is one or more sands selected from the group consisting of silica sand, zircon sand and chromite sand, (j) far infrared radiation material, (k) steel slag and (l) materials other than cement, The purpose is to be included in the range of the snow melting block 1 of the second embodiment.

The “olivine sand” is made of peridotite, which is crushed and sieved, rich in forsterite, and is generally represented by (Mg, Fe) ₂ SiO ₄ . In addition, “silica sand (silica sand, silica sand)” is quartz sand mainly composed of silicic acid (SiO ₂ ), and is distributed in the form of quartz sand in land layers, or in estuaries and coastal sand beaches. It is classified into two types: the developed natural silica sand and the artificial silica sand that has been crushed and screened from silica ore. The "zircon sand" is a sand mainly zircon (ZrSiO _4), a ZrO ₂ about 66%, contains SiO ₂ about 33%. The "chromite sand" is a sand-rich chromite, the _Al 2 _{O 3} about 15%, the _Fe 2 _{O 3} about 25%, contains _Cr 2 _{O 3} about 45%.

  These olivine sand, silica sand, zircon sand and chromite sand have a relatively round particle size, a fine particle surface, smoothness with few irregularities, a low coefficient of thermal expansion, excellent crushing resistance and disintegration, fire resistance, Because of its high thermal conductivity, olivine is suitable as a raw material for the third layer 4 that is the uppermost layer of the snow melting block 1 of the second embodiment and has a specific gravity of 20% or more larger than that of general crushed stone. Sand is more preferred.

  Therefore, at least (i) one or more sands selected from the group consisting of olivine sand, quartz sand, zircon sand and chromite sand, (j) far-infrared radiation material, (k) steel slag, and (l) cement as raw materials The third layer 4 in the snow melting block 1 of the second embodiment configured as mortar has a high structural strength and excellent water permeability, water resistance, heat storage, thermal conductivity, thermal diffusivity. The heat generated from the heating element 52 and the heat stored in the second layer 3 of the snow melting block 1 are conducted to the surface (exposed surface) of the snow melting block 1. It is easy to melt the snow and icing on the surface (exposed surface) quickly, and the water generated by melting the snow and icing is passed through the snow melting block 1 in order to make it underground. Can flow to As a result, it is possible to melt them snow and ice continuously.

  Further, in the snow melting block 1 of the second embodiment, (i) one or more selected from the group consisting of (i) olivine sand, quartz sand, zircon sand and chromite sand, which are raw materials of mortar constituting the third layer 4 The ratio of sand, (j) far-infrared radiation material, (k) steel slag, and (l) cement is the ratio of (i) olivine sand and silica sand to 100 parts by weight of (l) cement and (k) steel slag. One or more sands selected from the group consisting of zircon sand and chromite sand are 100 to 200 parts by weight, and (j) far infrared rays with respect to (l) cement and (k) 100 parts by weight of steel slag. The radiation material is preferably 1 to 20 parts by weight. With such a composition, the structural strength of the third layer 4 can be further increased, and the water permeability, water resistance, heat storage property, and thermal conductivity can be further increased. The amount of electric power can be further reduced.

  Further, in the snow melting block 1 of the second embodiment, the ratio of (a) heat insulating material, (b) sand and (c) cement, which are raw materials of the foamed concrete constituting the first layer 2, is the above (c) cement. The (a) heat insulating material is 150 to 250 parts by volume with respect to 100 parts by volume, and the (b) sand is 50 to 300 parts by volume with respect to 100 parts by volume of the cement. The ratio of (d) far-infrared radiation material, (e) steel slag, (f) sand, (g) gravel, and (h) cement, which are the raw materials of the concrete constituting the layer 3, is the above (h) cement and ( e) 1 to 20 parts by volume of the (d) far-infrared radiation material with respect to 100 parts by volume of the steel slag, and (f) sand with respect to (h) cement and (e) 100 parts by volume of the steel slag. Is 50 to 350 parts by volume, The (g) gravel is 150 to 450 parts by volume with respect to 100 parts by volume of the (h) cement and the (e) steel slag, and is a raw material of mortar constituting the third layer 4 (i 1) One or more sands selected from the group consisting of olivine sand, silica sand, zircon sand and chromite sand, (j) far-infrared radiation material, (k) steel slag and (l) the proportion of cement is 100) 200 parts by weight of 1 or 2 or more sand selected from the group consisting of (i) olivine sand, silica sand, zircon sand and chromite sand with respect to 100 parts by weight of cement and (k) steel slag It is more preferable that the (j) far-infrared emitting material is 1 to 20 parts by weight with respect to 100 parts by weight of (l) cement and (k) steel slag. Such a blend can further increase the structural strength, in particular, the compressive strength, of the snow melting block 1 of the first embodiment, and further improve water permeability, water resistance, heat insulation, heat storage, and thermal conductivity. The power consumption can be further reduced as compared with the conventional snow melting block.

  In addition, the snow melting block 1 of the second embodiment includes the first layer 2 composed of the above-mentioned (a) heat insulating material, (b) sand and (c) foamed concrete formed by the proportion of cement, and the above-mentioned. (D) far-infrared radiation material, (e) steel slag, (f) sand, (g) gravel and (h) second layer 3 composed of concrete formed by the proportion of cement, and (i) described above From one or more sands selected from the group consisting of olivine sand, quartz sand, zircon sand and chromite sand, (j) far-infrared radiation material, (k) steel slag and (l) concrete formed by the proportion of cement It suffices to have at least one of the third layers 4 to be configured.

  The snow melting block 1 of the second embodiment as described above can be used alone (only one), but it is preferable to use a plurality (two or more) in combination.

  Next, a third embodiment of the snow melting block according to the present invention will be described in detail with reference to the drawings. As shown in FIG. 5, the snow melting block 1 of the third embodiment has a hanging portion 41 on the surface layer of the third layer 4. Hereinafter, each configuration will be described in detail. Note that, in the third embodiment of the snow melting block 1, the same or corresponding / corresponding configurations as those of the first embodiment and the second embodiment of the snow melting block 1 described above are denoted by the same reference numerals again. Description is omitted.

  “Hatsuri (sharping, shaving)” means breaking concrete or mortar structures or shaving the surface to adjust the shape. In the snow melting block 1 of the third embodiment, The shaving (cutting) refers to cutting the surface of concrete or mortar, and the hanger 41 is formed by holding the surface (exposed surface) of the snow melting block 1.

  By forming the hanger portion 41, the water generated by melting snow and icing on the surface (exposed surface) of the snow melting block 1 can be made to permeate into the snow melting block 1 and flow into the ground. As a result, the snow accumulation and icing can be further melted continuously.

  The snow melting block 1 of the third embodiment as described above can be used alone (only one), but it is preferable to use a plurality (two or more) in combination.

  Next, a fourth embodiment of the snow melting block according to the present invention will be described in detail with reference to the drawings. As shown in FIG. 6, the snow melting block 1 of the fourth embodiment includes a mesh-like reinforcing material 51 and a heating element 52 in the contact surface 5 between the first layer 2 and the second layer 3 or in the vicinity of the contact surface 5. A mesh-like heating element 52 and a mesh heater 53 formed in combination are provided. Hereinafter, each configuration will be described in detail. In the fourth embodiment of the snow melting block 1, the same reference numerals are used for the same or corresponding / corresponding configurations to those of the first, second, and third embodiments of the snow melting block 1 described above. A description thereof will be omitted.

  In the snow melting block 1 of the fourth embodiment, the mesh heater 53 is not particularly limited as long as it is a mesh-like heating element 52. Examples of such a mesh heater 53 include a hot water circulation pipe, a nichrome heater, and a ceramic heater. , Conductive polymer heaters, blade heaters, and the like.

  The snow melting block 1 of the fourth embodiment as described above can be used alone (only one), but it is preferable to use a plurality (two or more) in combination.

  Hereinafter, embodiments of a snowmelt roadbed according to the present invention will be described in detail with reference to the drawings. Of the present embodiment and the fourth embodiment of the snowmelt roadbed 6, the same or corresponding / corresponding configurations to those of the first embodiment, the second embodiment, and the third embodiment of the snowmelt block 1 described above are the same. The description will be omitted.

  As shown in FIG. 7, the snow melting roadbed 6 of this embodiment is comprised from either the snow melting block 1 of 1st Embodiment, 2nd Embodiment, 3rd Embodiment, and 4th Embodiment. The form of the snow melting block 1 has a substantially rectangular surface (exposed surface) as shown in FIG. 7 and is laid so as to be spread, and is laid by forming joints as interlocking blocks. Is preferred.

  Next, the operation of the snow melting block 1 and the snow melting roadbed 6 according to the present invention will be described in detail with reference to the drawings.

  As shown in FIGS. 1 to 4 and FIG. 6, the snow melting block 1 forms a first layer 2 by placing at least (a) a heat insulating material, (b) sand, and (c) foamed concrete made from cement. Then, after the mesh-shaped reinforcing material 51 and the heating element 52 or the mesh heater 53 are disposed on the upper surface of the first layer 2, at least (d) a far-infrared radiation material, (e) steel slag, and (f) Sand, (g) gravel, and (h) concrete made from cement are cast to form the second layer 3 and, on top of that, if desired, at least (i) olivine sand, quartz sand, zircon sand And a third layer 4 by placing mortar made of one or more sands selected from the group consisting of chromite sand, (j) far infrared radiation material, (k) steel slag, and (l) cement. Manufactured by forming. When placing the third layer 4, a color hardener can be formed by kneading a colorant as a raw material, and this can be placed as the third layer 4. As shown in FIG. 5, when placing the third layer 4, it is preferable to form the suspended portion 41 by peeling the surface (exposed surface) of the third layer 4.

  Next, laying of the snow melting block 1 (laying of the snow melting roadbed 6) will be described. Cushion sand is laid in advance (not shown), and the second layer 3 or the third layer 4 is on the road surface so that the second layer 3 or the third layer 4 is on the plurality of snow melting blocks 1 produced thereon. As shown in Fig. 1, lay down so that the upper surface (surface, exposed surface) is aligned. The laying is preferably based on an interlocking method. After laying the snow-melting blocks 1, the adjacent snow-melting blocks 1 arranged side by side are waterproofed by taping, and as shown in FIG. 7, by connecting their heating elements 52 or mesh heaters 53, structural strength, In particular, the snowmelt roadbed 6 is formed which has a high compressive strength, is excellent in water permeability, water resistance, heat storage property, and heat conductivity, and can significantly reduce power consumption as compared with a conventional snowmelt block.

  When the heating element 52 or the mesh heater 53 is turned on and the heating element 52 or the mesh heater 53 is energized, the heat generated from the heating element 52 or the mesh heater 53 is radiated heat to the highly insulating first layer 2. Without being conducted, it is temporarily accumulated in the second layer 3 of the snow melting block 1 or directly conducted to the second layer 3 or the second layer 3 and the third layer 4, and the surface of the snow melting block 1 (exposed) The surface (exposed surface) and quickly melt snow and icing on the surface. The water generated by melting snow and icing with the passage of time sequentially passes through the second layer 3 or the second layer 3 and the third layer 4, and further passes through the first layer 2. Then flow into the ground. The snow and icing can be continuously melted by the circulation as described above.

According to the snow melting block 1 and the snow melting roadbed 6 as described above, the following effects can be obtained.
1. Excellent structural strength, especially compressive strength, excellent water permeability, water resistance, heat storage, thermal conductivity, thermal diffusivity, excellent environmental directivity, and compared with conventional snow melting blocks and snow melting roadbeds Power consumption can be greatly reduced.
2. Heat generated from the heating element 52 and heat stored in the snow melting block 1 can be easily conducted to the surface (exposed surface) of the snow melting block 1, and snow accumulation on the surface (exposed surface) of the snow melting block 1 and the snow melting roadbed 6 The icing can be melted quickly.
3. Water generated by melting snow and icing on the surface (exposed surface) of the snow melting block 1 and the snow melting roadbed 6 can be sequentially passed through the snow melting block 1 to flow into the ground. And icing can be melted continuously.

  In addition, the snow melting block and snow melting roadbed which concern on this invention are not limited to each embodiment mentioned above, It can change suitably.

  Hereinafter, a snow melting block and a snow melting roadbed according to the present invention will be described based on examples. The technical scope of the present invention is not limited to the features shown by these examples.

<Example 1>
Samples were prepared and compared for the composition and effects of the raw materials of the first layer 2, the second layer 3, and the third layer 4 of the snow melting block 1 according to the first embodiment and the second embodiment described above. The sample is made so that the upper surface (exposed surface) is approximately square of 500 mm square and the height is about 50-60 mm, and snow is piled on the top so that the height is 25 cm, and the degree of melting and watering are determined. evaluated. In the evaluation, “ordinary” was ▲, “good” was △, “substantially good” was ◯, and “very good” was ◎. Table 1, Table 2, Table 3, Table 4, and Table 5 show the ratios of main raw materials of the first layer 2, the second layer 3 and the third layer 4 of the snow melting block 1 and the evaluation results. In addition, the ratio of the raw material in the 1st layer 2 and the 2nd layer 3 is a volume ratio, and the ratio of the raw material in the 3rd layer 4 is a weight ratio.

[Table 1]

[Table 2]

[Table 3]

[Table 4]

[Table 5]

  For sample 26, sample 28, sample 30 and sample 32, sample 1, sample 2, sample 3, sample 4, sample 5, sample 6, sample 7, sample 8, sample 9, sample 10, sample 11, sample 11 12, Sample 13, Sample 14, Sample 15, Sample 16, Sample 17, Sample 18, Sample 19, Sample 20, Sample 21, Sample 22, Sample 23, Sample 33, Sample 35, Sample 37, and Sample 39 Sample 73, sample 74, sample 75, sample 76, sample 77, sample 78, sample 79, sample 80, sample 97, sample 99, sample 101 and sample 103, sample 68, sample 70 and The sample 72 is relatively superior, and compared to the sample 68, the sample 70, and the sample 72, the sample 41, the sample 42, the sample 57, the sample 58, the sample 59, the sample 60, the sample 61, the sample 62, the sample 63, the sample 64, Sample 65, Sample 81, Sample 83, Sample 85, and Sample 87 were relatively superior.

  Also, sample 89, sample 90, sample 91, sample 92, sample 93, sample 94, sample 95, sample 96, sample 105, sample 107, sample 109 and sample 111, sample 98, sample 100, sample 102 and sample 104. And 89, sample 90, sample 91, sample 92, sample 93, sample 94, sample 95, sample 96, sample 98, sample 100, sample 102, sample are not changed. Sample 66, Sample 82, Sample 84, Sample 86 and Sample 88 are relatively superior to Sample 104, Sample 105, Sample 107, Sample 109 and Sample 111. Pull 82, to the sample 84, sample 86 and sample 88, sample 24, sample 34, sample 36, towards the sample 38 and sample 40 were relatively good. Further, the samples 106, 108, 110, and 112 were most excellent overall.

  From the above results, the ratio of (a) heat insulating material, (b) sand, and (c) cement, which are raw materials of the foamed concrete constituting the first layer 2, is the above (c) It is preferable that a) a heat insulating material is 150 to 250 parts by volume, and (b) sand is 50 to 300 parts by volume with respect to (c) 100 parts by volume of cement. The ratio of (d) far-infrared radiation material, (e) steel slag, (f) sand, (g) gravel, and (h) cement, which is a raw material of the concrete that constitutes (h) cement and (e) The (d) far-infrared radiation material is 1 to 20 parts by volume with respect to 100 parts by volume of the steel slag, and (f) 50 sands with respect to the (h) cement and 100 parts by volume of the (e) steel slag. ~ 350 parts by volume, and the above ( It is preferable that (g) gravel is 150 to 450 parts by volume with respect to 100 parts by volume of cement and (e) steel slag, and is a raw material of mortar constituting the third layer 4 (i) The ratio of one or more sands selected from the group consisting of olivine sand, quartz sand, zircon sand and chromite sand, (j) far-infrared radiation material, (k) steel slag, and (l) the ratio of cement is (l 100) 200 parts by weight of 1 or 2 or more sand selected from the group consisting of (i) olivine sand, silica sand, zircon sand and chromite sand with respect to 100 parts by weight of cement and (k) steel slag (1) It becomes clear that the (j) far-infrared emitting material is preferably 1 to 20 parts by weight with respect to 100 parts by weight of cement and (k) steel slag. The ratio of (a) heat insulating material, (b) sand, and (c) cement, which is a raw material of foamed concrete constituting 2, is 150 to 250 (a) heat insulating material relative to 100 parts by volume of (c) cement. (D) far-infrared rays which are volume parts and (c) 100 parts by volume of cement and (b) sand is 50 to 300 parts by volume, and is a concrete raw material constituting the second layer 3 The ratio of the radiation material, (e) steel slag, (f) sand, (g) gravel, and (h) cement is (d) far away from 100 parts by volume of (h) cement and (e) steel slag. The infrared radiation material is 1 to 20 parts by volume, the (f) sand is 50 to 350 parts by volume with respect to the (h) cement and (e) 100 parts by volume of the steel slag, and the (h) Cement and (e) steel It becomes clear that (g) gravel is more preferably 150 to 450 parts by volume with respect to 100 parts by volume of rug, and (a) a heat insulating material that is a raw material of foamed concrete constituting the first layer 2 The ratio of (b) sand and (c) cement is 150 to 250 parts by volume of (a) heat insulating material with respect to 100 parts by volume of (c) cement, and (c) 100 parts by volume of cement. (B) Sand is 50 to 300 parts by volume, and (d) far-infrared radiation material, (e) steel slag, (f) sand, (g) The proportion of gravel and (h) cement is 1 to 20 parts by volume of the (d) far-infrared emitting material with respect to 100 parts by volume of the (h) cement and (e) steel slag, and (h) Cement and (e) steel slag 1 The (f) sand is 50 to 350 parts by volume with respect to 0 part by volume, and the (g) gravel is 150 to 450 parts by volume with respect to 100 parts by volume of the (h) cement and the (e) steel slag. And (i) one or more sands selected from the group consisting of olivine sand, quartz sand, zircon sand and chromite sand, and (j) far infrared radiation. The ratio of the material, (k) steel slag and (l) cement consists of (i) olivine sand, silica sand, zircon sand and chromite sand with respect to 100 parts by weight of (l) cement and (k) steel slag. 100 or 200 parts by weight of one or more sand selected from the group, and (j) far-infrared emitting material is 1 to 100 parts by weight of (l) cement and (k) steel slag. 0 it is parts by weight was found to be more preferable.

<Example 2>
A bending strength test was performed on the snow melting block 1 of the second embodiment described above. This test was commissioned to the Northern Institute for Architecture Research, Architectural Research Headquarters, Hokkaido Research Institute.
Test number: Kenken No. 29-3 (accepted on May 8, 2017)
Test implementation date: May 10, 2017 Test location: Hokkaido Research Institute, Architectural Research Headquarters, Kitakata Architectural Research Institute Test contents: Bending strength to pressurize the specimen and check for cracks test

  The test body was the snow melting block 1 of the second embodiment shown in FIGS. 1 and 2, and the number of test bodies was three. In addition, the size of the upper surface (exposed surface) was approximately a square of 500 mm square and the height was approximately 60 mm. The dimensions of each test specimen are shown in Table 6, and symbols (dimension measurement locations) in Table 6 are shown in FIG.

[Table 6]

[Test method]
Using a fully automatic product external pressure / bending tester (CPA-100R-F (capacity is 1000 kN (102 t); Maekawa Tester Mfg. Co., Ltd.)), the monotonic force was applied by manual control with the upper surface of the test body down. The span was 240 mm, and a rubber plate was inserted into the pressure surface and the support surface to apply linear force.

[Test results]
Table 7 shows the presence / absence of cracks and the maximum load in each specimen when the bending cracking strength (20.0 kN (2.04 t)) specified in JIS A 5371: 2016 is used.

[Table 7]

  As shown in Table 7, among the three test specimens, the smallest load was 16.12 kN (1.64 t), and the largest load was 20.16 kN (2.06 t). No cracks occurred. This is an extremely high load value (about twice) as compared with a conventional snow melting block. From the above results, it was shown that the structural strength, particularly the compressive strength, of the snow melting block 1 of the second embodiment is extremely high.

<Example 3>
The power consumption of the snow melting block 1 of the second embodiment was examined. The snow melting block 1 (upper surface (exposed surface) is approximately a square of 500 mm square and the height is about 60 mm) in the second embodiment is composed of 4 pieces (2 each in length and width), conventional road heating (Sapporo, Hokkaido) City) and conventional road heating (Tobetsu-cho, Ishikari-gun, Hokkaido) in heavy snowfall areas were investigated and compared with the power consumption of the snow melting block 1 of the second embodiment. The results are shown in Table 8.

[Table 8]

As shown in Table 8, the power consumption of conventional road heating (Sapporo, Hokkaido) is 300 to 330 Wh / m ² , and the power consumption of conventional road heating (Tobetsu-cho, Ishikari-gun, Hokkaido) in heavy snowfall areas. Is 350 to 400 Wh / m ² , whereas the power consumption of the snow melting block 1 of the second embodiment is 145 Wh / m ² . This power consumption is 36.25 Wh / m ² per one of the snow melting blocks 1 of the second embodiment (the upper surface (exposed surface) is a substantially square of 500 mm square and the height is about 60 mm). From the above results, the power consumption of the snow melting block 1 of the second embodiment is the power consumption of the conventional road heating (Sapporo, Hokkaido) and the conventional road heating (Tobetsu-cho, Ishikari-gun, Hokkaido) in the heavy snow region. It became clear that it was extremely small compared to.

DESCRIPTION OF SYMBOLS 1 Snow melting block 2 First layer (of snow melting block 1) 3 Second layer (of snow melting block 1) 4 Third layer (of snow melting block 1) 41 Hanging part 5 Contact surface of first layer 2 and second layer 3 51 mesh-like reinforcing material 52 heating element 53 mesh heater 6 snowmelt roadbed

Claims (5)

A first layer composed of foamed concrete having at least the following (a), (b) and (c) as raw materials;
(A) insulation material,
(B) sand,
(C) cement;
And a second layer made of concrete, formed on the first layer and using at least the following (d), (e), (f), (g) and (h) as raw materials,
(D) far infrared radiation material,
(E) Steel slag,
(F) sand,
(G) gravel,
(H) cement;
And a third layer made of mortar, formed on the second layer and using at least the following (i), (j), (k) and (l) as raw materials:
(I) one or more sands selected from the group consisting of olivine sand, quartz sand, zircon sand and chromite sand;
(J) far-infrared radiation material,
(K) Steel slag,
(L) cement;
A snow-melting block comprising a mesh-like reinforcing material and a heating element in the vicinity of or in contact with the first layer and the second layer, foamed concrete constituting the first layer , The snow melting block in which the ratio of the raw material of the concrete constituting the second layer and the mortar constituting the third layer is at least one of the following (A) , (B) and (C) ;
(A) The ratio of the raw material of the foamed concrete constituting the first layer is such that (a) the heat insulating material is 150 to 250 parts by volume with respect to 100 parts by volume of the (c) cement, and the (c) cement The (b) sand is 50 to 300 parts by volume with respect to 100 parts by volume;
(B) The ratio of the raw material of the concrete which comprises a 2nd layer is 1-20 volume parts of said (d) far-infrared radiation materials with respect to said (h) cement and said (e) steel slag 100 volume parts. The (f) sand is 50 to 350 parts by volume with respect to the (h) cement and 100 parts by volume of the (e) steel slag, and the (h) cement and (e) 100 parts by volume of the steel slag. Said (g) gravel is 150-450 parts by volume ;
(C) The ratio of the raw material of the mortar constituting the third layer consists of (i) olivine sand, silica sand, zircon sand and chromite sand with respect to (l) cement and (k) 100 parts by weight of steel slag. 1 or 2 or more sand selected from the group is 100 to 200 parts by weight, and (j) far-infrared radiation material is 1 with respect to 100 parts by weight of (l) cement and (k) steel slag. ~ 20 parts by weight . The snow melting block according to claim 1, wherein the heat insulating material is a resin-based foam material . The snow melting block according to claim 1 or 2, wherein a suspended portion is formed on a surface layer of the third layer. The snow melting block according to any one of claims 1 to 3, wherein the mesh-shaped reinforcing material and the heating element are mesh heaters . The snow melting roadbed comprised from the snow melting block as described in any one of Claims 1-4.