JP4343233B2 - Roof planting equipment - Google Patents

Description

  The present invention relates to a roof greening device, and more particularly to a greening device suitable for greening a roof of a general house or factory.

  In recent years, rooftop greening is one of the effective means to cope with global warming problem, to suppress heat island in the city center, environmental measures such as air purification, or heat insulation of buildings and prevention of UV degradation. Conventionally, the present inventor has proposed a greening technique for greening the rooftop of an existing structure.

  For example, Patent Document 1 discloses a greening method in which a plurality of columns are set up on the roof of a building, a plurality of frames are bridged between the columns, and vegetation is allowed to grow using these frames as a support member. Has been.

It can be installed without being limited to facilities installed on the rooftop or reducing the rooftop space, and it is easy to manage irrigation and fertilization of vegetation. It is for greening the roof of the building.
JP 2006-20542 A

The present invention is an apparatus for greening a roof of a structure, and is provided on the roof of the structure, and a tubular body serving as a cultivation tank for the plant, and the plant that is proliferated by being attached along the surface of the roof. A supporting frame material or netting material or mat-like water retaining material, a liquid fertilizer tank for storing liquid fertilizer, a water supply pipe for supplying liquid fertilizer from the liquid fertilizer tank to the pipe body, and a liquid fertilizer discharged from the pipe body for the liquid fertilizer tank And a circulation device including a pump for feeding the liquid fertilizer in the liquid fertilizer tank to the water supply pipe, and the circulation device is configured to reversely flow the liquid manure from the drain pipe to the tubular body. an object of the present invention is to provide a roof greening device Ru equipped with.

In order to achieve the above object, the present invention provides :
A device for greening the roof of a structure,
A pipe body provided on the roof of the structure and serving as a plant cultivation tank,
A frame material or netting material or a mat-like water retaining material that is attached along the surface of the roof and supports the plant that has grown
A liquid fertilizer tank for storing liquid fertilizer, a water supply pipe for supplying liquid fertilizer from the liquid fertilizer tank to the pipe, a drain pipe for returning the liquid fertilizer discharged from the pipe to the liquid fertilizer tank, and liquid fertilizer in the liquid fertilizer tank A circulation device including a pump for feeding into the water supply pipe ,
The circulation system, and Rukoto characterized with backflow means for flowing back to the tube body the liquid fertilizer from the drainage pipe (first invention).
According to the roof tree planting apparatus of the present invention, since it is a simple and lightweight configuration in which a tube serving as a plant culture medium is directly installed on the roof without providing a heavy object such as a support, it is like a roof of a general house or factory. It can also be installed on roofs where load resistance is limited .
Moreover, according to the roof planting apparatus of this invention, the usage-amount of the liquid manure required for cultivation can be reduced by repeatedly circulating and using the liquid manure supplied in a pipe body by a circulation apparatus.
Furthermore, according to the roof greening device of the present invention, when clogging occurs near the drain outlet of the drain pipe drained from the pipe body, the clogging in the drain pipe can be easily performed by causing the water flow to flow backward from the drain pipe to the pipe body. Can be eliminated. As a result, repair work such as replacement of the drain pipe when clogging occurs can be avoided, which contributes to cost reduction.

The second invention is characterized in that, in the first invention, the tubular body has an opening formed only in a portion where the plant is planted.
According to the roof tree planting apparatus of the present invention, the tube forming the plant culture medium has an opening only in the part where the plant is to be planted. It can be kept to a minimum, the liquid fertilizer concentration can be maintained or the occurrence of blue-tailed canopy can be prevented, and the medium can be maintained as an environment suitable for plant growth.

According to a third invention, in the first or second invention, the tank includes a heater and a cooler capable of adjusting a temperature of liquid fertilizer stored in the tank.
According to the roof tree planting apparatus of the present invention, the temperature of liquid fertilizer replenished in the medium becomes excessively high for plants to grow in summer, etc., becomes low temperature unsuitable for use of liquid fertilizer in winter, or the like. Since the liquid fertilizer itself can be avoided from freezing, it contributes to the maintenance of an appropriate growth environment for the plant.

4th invention is the invention in any one of 1st- 3rd . WHEREIN: The said circulation device is a temperature sensor which measures the temperature of the liquid fertilizer in the said tank, The density | concentration sensor which measures the density | concentration of the liquid fertilizer in the said tank, The said tank When at least one of a water level sensor for measuring the liquid level of liquid fertilizer in the pipe or a water level sensor for measuring the water level of liquid fertilizer in the tubular body is provided, and the measurement value by the provided sensor is a value indicating abnormality And a monitoring recording device that has a function of warning the abnormality and that automatically records the measured value.
According to the roof planting apparatus of the present invention, it is possible to appropriately maintain and manage the temperature of liquid fertilizer, the concentration of liquid fertilizer, the water level of the tank of the circulation device, or the water level in the pipe, which are factors affecting the plant growth environment.

According to a fifth invention, in any one of the first to fourth inventions, a pair of propellers are rotated in opposite directions in the water supply pipe or the drain pipe by the flow of liquid manure in the pipe line. It is provided with an air mixing device in which an air hole penetrating the inside or outside of the water supply pipe or drain pipe is formed near the installation position of these propellers.
According to the roof greening device of the present invention, the air formed in the vicinity of the installation position of the propeller is caused by the flow of liquid fertilizer or air in the drain pipe, and the air pressure in the drain pipe becomes negative compared to the external pressure outside the pipe. Air can flow into the liquid fertilizer by mixing and mixing the liquid manure and air in the drain pipe by the two propellers that flow into the drain pipe from the hole and rotate in reverse to each other. By cultivating a plant using liquid fertilizer mixed with such air, the respiratory action of the root of the plant can be promoted, and the plant can be grown well.

A sixth invention is characterized in that, in any one of the first to fifth inventions, a sterilization apparatus for sterilizing bacteria that propagate in the liquid fertilizer is provided in the circulation system of the circulation device.
According to the roof tree planting apparatus of the present invention, by sterilizing the liquid manure circulating in the circulation system, it is possible to prevent the growth of the fungus in the medium, and it is possible to maintain the medium as a favorable growth environment for the plant.

According to a seventh aspect , in the sixth aspect , the sterilization apparatus performs sterilization by ultraviolet irradiation or heating.

An eighth invention is characterized in that, in any one of the first to seventh inventions, the tubular body is provided with a holder for holding the plant.
According to the roof tree planting apparatus of the present invention, the roots and stems of the plants are held by the holding tool, so that the roots growing in the roots are in a state where the roots are not held such as during hydroponics. The resulting stress can be reduced and the plant can grow well. It also prevents plants from falling off the tube.

A ninth invention is characterized in that, in any one of the first to eighth inventions, the tube is filled with zeolite, oyster shell or pumice.
According to the roof greening apparatus of the present invention, air permeability and water permeability in the medium can be maintained, and plants can be grown well.

According to a tenth aspect , in any one of the first to ninth aspects, the roof is made of slate .
According to the roof greening device of the present invention, for example, it is often used for the roof of a building such as a factory, and after aged use, the slate roof whose surface changes to black due to deterioration due to sunburn is greened. It can be aesthetically pleasing, and plants can block the direct sunlight from hitting the roof, so the temperature rise in the building in summer can be mitigated. As a result, the working environment in the factory can be improved, and power saving such as cooling can be saved, which contributes to energy saving. In addition, it contributes to the reduction of CO ₂ in urban areas and the suppression of the heat island phenomenon.

An eleventh invention is characterized in that, in any one of the first to ninth inventions, the roof is made of a steel plate .

In a twelfth aspect of the invention according to any one of the first to eleventh aspects, a water sprinkler capable of watering the plant is provided on the roof.
According to the roof tree planting apparatus of the present invention, water can be sprayed directly on the stem or leaf, the air temperature is maintained and the temperature of the leaf is lowered when the temperature is high in summer, etc., and the plant growth environment is improved. And aphids can be prevented. In addition, the temperature of the roof can be lowered, the temperature rise in the building in summer can be mitigated, and it contributes to the suppression of heat island formation.

In a thirteenth aspect of the invention according to any one of the first to twelfth aspects of the present invention, a substantially concave leaf receiver is provided above the rain gutter installed on the roof, and includes a screen that allows rain water to pass through. A scraping device provided with a scraping body capable of scraping off the fallen leaves of the plant accumulated in the leaf receptacle by moving the inside of the leaf receptacle in the longitudinal direction by pulling the wire inside the wire. It is provided.
According to the roof greening apparatus of the present invention, rainwater flowing through the roof passes through the screen and falls into the rain gutter below the screen, so that only the fallen leaves are captured without collecting water in the leaf tray. By pulling the wire scraper to which the wire is connected and moving the inside of the leaf receptacle, the fallen leaves accumulated in the leaf receptacle can be collected and the inside of the leaf receptacle can be cleaned. Thereby, it does not occur that the rain gutter is clogged with the fallen leaves falling from the plants growing on the roof.

According to the present invention, there is provided a device for greening a roof of a structure, which is provided on the roof of the structure, and is a tube serving as a plant cultivation tank, and is attached along the surface of the roof, and is prosperous. Frame material or netting material or mat-shaped water retaining material that supports plants, liquid fertilizer tank that stores liquid fertilizer, a water supply pipe that supplies liquid fertilizer from the liquid fertilizer tank to the tubular body, and liquid fertilizer discharged from the tubular body A drainage pipe that returns to the liquid fertilizer tank, and a circulation device that includes a pump that feeds the liquid fertilizer in the liquid fertilizer tank to the water supply pipe, and the circulation device is configured to cause the liquid fertilizer to flow backward from the drainage pipe to the tubular body. possible to provide a roof greening system according to Rukoto characterized equipped with a reflux means.

Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the drawings.
FIG. 1 is a perspective view showing an appearance when a roof tree planting apparatus 10 according to the present invention is applied to a slate roof 12 used in a building such as a factory.

  As shown in FIG. 1, a roof planting apparatus 10 is provided with a medium 14 attached to the top of a slate roof 12 for growing plants, and on the roof for extending the plants along the slate roof 12 from the medium 14. The frame 16 is provided and a circulation system 20 including a water supply pipe 22, a drain pipe 24, a liquid fertilizer tank 26, and the like for circulating the liquid manure 18 supplied to the culture medium 14. The roof greening device 10 may be a vine plant or a dwarf plant to be vegetated. In this embodiment, among the vine plants having drooping properties, Hedera helix 19 (hereinafter referred to as Hedera). 19).

FIG. 2 is a diagram in which a portion of the culture medium 14 is extracted from the roof greening device 10 of FIG.
As shown in FIG. 2, the culture medium 14 is formed, for example, by forming an opening 28 for implanting the hedera 19 on the upper side of a cylindrical hard polyvinyl chloride tube (hereinafter referred to as a PVC tube 30). In the vicinity of the opening 28, a fastener 32 is attached so as to hold the stem or root so that the hedera 19 does not fall off the medium 14 due to strong winds or its own weight. A water supply pipe 22 for supplying the liquid fertilizer 18 and a drain pipe 24 for draining are attached to the end of the culture medium 14.

  In the container forming the culture medium 14, a polyvinyl chloride tube 30 having a light-shielding property is used in order to prevent the occurrence of aquatic or the like that is generated when the culture medium 14 is irradiated with sunlight. The polyvinyl chloride tube 30 is not limited to a cylindrical shape, and may be, for example, a rectangular shape as long as it has a shape that has a sufficient capacity for the hedera 19.

  The opening 28 is preferably the minimum size necessary for planting the hedera 19 in order to prevent the liquid fertilizer concentration from diluting due to the inflow of rainwater and the occurrence of water-blooming caused by sunlight irradiation. These openings 28 are formed above the PVC pipe 30 at a predetermined interval.

  The fastener 32 can be deformed to follow the growth of the hedera 19 with a diameter that holds the stem, for example, a soft wire bent in one roll, or the holding portion of the stem can be made of plastic, rubber, What was produced with elastic bodies 32a, such as sponge, is used.

FIG. 3 is a longitudinal sectional view of FIG. 2 and b) AA ′ transverse sectional view.
As shown in FIG. 3, the water supply pipe 22 is installed so as to pass through the lower part in the PVC pipe 30, and the liquid manure 18 sent into the water supply pipe 22 in the PVC pipe 30 flows out evenly into the culture medium 14. Thus, a large number of outflow holes 34 are formed. These outflow holes 34 are formed in such a size that the roots of the hedera 19 cannot enter, and the liquid fertilizer 18 can flow out from the water supply pipe 22 without stagnation.

  The drainage pipe 24 is provided at a position of an appropriate water level for the growth of the roots of the hedera 19, and drains the excess liquid manure 18 of the culture medium 14. In addition, although the water supply pipe 22 and the drain pipe 24 are installed in the end surface of the same side of the culture medium 14 in the same figure, you may install separately in not only this but the opposing end surface.

  In addition, if it is Hedera 19, it can grow only with liquid fertilizer 18, but in order to relieve stress due to the floating state of the roots, for example, a sponge-like or mesh-like seedling culture medium 33 covers the roots of Hedera 19. The root is fixed by providing it. In addition, the bottom of the PVC pipe 30 is provided with a filler 36 such as zeolite, oyster shell or pumice that has good air permeability and water permeability, and a hedera protruding from the seedling culture medium 33. The 19 roots can be further extended into the filling 36. It is preferable to use those filled with a sufficiently neutralized treatment suitable for cultivation of Hedera 19. In addition, since the filling 36 is filled in the gabion 35, when it is desired to replace the filling 36 due to deterioration or the like, the filling 36 in the culture medium 14 can be easily replaced by replacing the gabion 35. Can do.

Further, in order to completely block the irradiation of sunlight from the opening 28 to the culture medium 14 inside the opening 28, a sunshade cover 37 is provided in the opening 28 inside the PVC pipe 30. .
In addition, as a water supply method for supplying the liquid fertilizer 18 to the culture medium 14, a configuration in which the water supply pipe 22 is dropped from the outside of the PVC pipe 30 to the opening 28 without being inserted into the PVC pipe 30 may be used.

4A and 4B are a longitudinal sectional view showing an example of a culture medium 90 adopting (a) a drip water supply method, and (b) AA ′ transverse sectional view.
As shown in FIG. 4, the culture medium 90 uses a culture medium container 92 instead of the PVC pipe 30, and a plurality of planting cases 94 in which the hedera 19 is planted are arranged in the culture medium container 92. Yes. When the liquid fertilizer 18 is replenished, an infusion hose 96 is provided so as to branch from the water supply pipe 22 arranged outside the medium container 92 to the planted position of the hedera 19. Further, two drain pipes 24 a and 24 b are provided above and below the end of the culture medium container 92, and the two drain pipes 24 are arranged so as to be gathered by a strainer 93 ahead of the two.

The medium container 92 is a rectangular parallelepiped container made of, for example, stainless steel or reinforced plastic, and the inside of the medium container 92 is separated into two layers by a partition beam 98.
For the partition beam 98, for example, a stainless steel plate with punching or meshing is used so that the liquid fertilizer 18 can pass between the upper and lower chambers. In addition, the lower room partitioned by the partition beam 98 is filled with the filling 36 such as oyster shell described above.
The planting case 94 can be placed on the partition beam 98 in the medium container 92.

  In addition, a sunshade cover 37 that is joined to the medium container 92 by a hinge and can be opened and closed is divided on the upper surface of the medium container 92 so as to correspond to the size of the planting case 94 disposed in the medium container 92. Has been provided. The sunshade cover 37 is formed with an opening 28 through which the stem of the hedera 19 can pass, and the stem and leaves can be removed from the opening 28 when the hedera 19 is opened and closed even when the hedera 19 is opened and closed. Furthermore, it is divided at the central portion 100. The tip of the drip hose 96 is installed at a position where the hedera 19 is planted from the opening 28 after the sunshade cover 37 is closed, and an appropriate amount of liquid fertilizer 18 is dropped.

  The planting case 94 is made of, for example, a container made of stainless steel or reinforced plastic, and the bottom surface thereof has a mesh structure so that the liquid fertilizer 18 supplied from the drip hose 96 and penetrated to the bottom of the planting case 94 can pass through. ing. In these planting cases 94, for example, two Hedera 19 are planted in one case.

  The drainage pipe 24 is provided with an upper drainage pipe 24a and a lower drainage pipe 24b so as to be connected to a room separated into upper and lower two layers by a partition beam 98 in the culture medium container 92, respectively. This is because the liquid fertilizer 18 replenished to the planting case 94 normally passes through the bottom of the planting case 94 and leaches into the lower layer room of the culture medium container 92 and is collected at the bottom of the culture medium container 92 to be lower. The liquid fertilizer 18 is drained through the drain pipe 24b. If the liquid fertilizer 18 in the medium container 92 increases due to an increase in the amount of water supply or due to rainwater contamination, etc. This is to forcibly drain. Thereby, root rot of Hedera 19 can be prevented.

  Further, in the strainer 93 in which the upper drain pipe 24a and the lower drain pipe 24b are gathered, for example, a filter for removing dust or the like that becomes clogged with the pipe is provided.

  In the culture medium 90, one long case corresponding to the roof length is used for the culture medium container 92, but the present invention is not limited to this, and the medium container 92 may be divided into a plurality of cases. In this case, for example, the medium containers 92 are connected with a connecting pipe or the like so that the water level of the liquid manure 18 in each medium container 92 is the same.

FIG. 5 is an enlarged perspective view of the roof greening device 10 in FIG.
As shown in FIG. 5, the frame material 16 is made of, for example, a light and highly rigid material such as aluminum, iron, or stainless steel, and is cut out over the entire upper surface along the longitudinal direction of a C channel or a hollow rectangular material. Is used. Then, in order to allow the hedera 19 to proliferate on the slate roof 12 as planned, the frame 16 is slate from the vicinity of the opening 28 where the hedera 19 is planted, for example, with the C-shaped or notched opening surface facing upward. The vertical members 16a provided along the roof 12 and the horizontal members 16b provided in a direction orthogonal to the vertical members 16a are assembled and installed in a lattice shape.

  The frame material 16 is filled with a moisture-absorbing and water-retaining material 38 having moisture absorption and water retention properties such as sponge, jute, straw and rice husk so as not to fall out of the frame material 16. The roots can be properly lowered and held on their own.

  Further, for example, a drip hole 40 is provided in the PVC pipe 30 at a position where the vertical member 16a is installed so that the lowered root can absorb moisture, and the liquid fertilizer 18 in the PVC pipe 30 is dipped into the moisture-absorbing water retaining material 38. Alternatively, a plurality of water sprinklers 42 are provided on the top of the roof (see FIG. 1), and liquid fertilizer can be sprayed from the water sprinklers 42 to the entire roof so that the moisture absorbing water retaining material 38 can retain water.

  Instead of the frame material filled with water retention material, the mat-shaped medium with good water retention structure is fixed on the entire surface of the slate roof so that it does not scatter, and the root lowered in the medium can absorb moisture. In this case, the bottom of the medium is preferably made of a material that does not allow water or roots to enter.

FIG. 6 is a view showing the arrangement of the slate roof 12 and the frame member 16 when viewed from the direction C of FIG.
As shown in FIG. 6, the frame member 16 is installed at a predetermined interval from the slate roof 12. This is to prevent leaf burn by direct contact with the burnt roof in midsummer until Hedera 19 is fully grown, and to prevent overgrown leaves and stems from obstructing the flow of rainwater in the slate ditch. It is. In addition, depending on the type of vine plant to be planted, there is a thing that has a property of sticking a wall surface or the like with a sucker-like root called aerial root. Therefore, once this aerial root sticks to the slate roof 12 or the like, Hedera 19 When it is desired to replace the roof greening device 10 when the roof has withered, not only is it difficult to remove the roof greening device 10, but it also avoids the possibility that airway traces remain on the slate roof 12 and the roof surface may be soiled. Because.

  The frame member 16 is installed on the slate roof 12 by using, for example, an existing bolt 44 or the like that fixes the slate roof 12 to the building, and a spacer 46 is connected to the bolt 44 or the like so as to be spaced apart. Further, the spacer 46 and the frame member 16 of the longitudinal member 16a and the transverse member 16b are fixed again with bolts 44 or the like. Further, the holding member 50 may be connected to the end of the frame member 16 via the joint 48, and the holding member 50 may be fixed to the wall surface or the like with a bolt 44 or the like. Thereby, the frame material 16 can be firmly fixed so that it can sufficiently withstand wind pressure, load, and the like.

  It should be noted that any member that keeps a space between the frame material 16 and the slate roof 12 may be interposed, and the frame material 16 may be fastened to a wall surface or the like so as to suppress the frame material 16 with a wire or the like.

  In the unlikely event that Hedera 19 reaches the slate roof 12, it flows over the surface of the slate roof 12 to stop the rainwater flow on the roof, and the rainwater enters the building from the joint of the slate roof 12. It is necessary to keep in mind that the roots extend at the joints between the slate, so it is preferable to close the joint between the slatees with the joint material 52.

  Further, a net member such as a wire net or a net may be used instead of the frame member 16 as a support member for extending the hedera 19.

FIG. 7 is a perspective view showing a configuration in which the frame material 16 of FIG.
As shown in FIG. 7, the mesh member 17 extends along the slate roof 12 and keeps the space from the roof, for example, using the spacers 46 described above, etc. To fix and install. In addition, when the mesh material 17 is used, the moisture absorbing water retaining material 38 cannot be installed, and therefore the hedera 19 cannot be fixed by itself. Therefore, the body of the hedera 19 is appropriately fastened to the mesh material 17 with a wire or a rope. It should be noted that instead of the netting material 17, a suitable grid may be configured with a rod or wire, and the hedera 19 may be extended while appropriately holding the body of the hedera 19 with a wire or rope or the like. .

  Moreover, you may make it the structure which combined the frame material 16, the net | network material 17, or a rod, a wire, etc. which demonstrated the member which extends a hedera.

  Although the roof greening apparatus 10 by this embodiment demonstrated the example of installation in case the roof of a factory is the slate roof 12, not only this but a roof may apply to the steel plate roof made from a steel plate.

FIG. 8 is a diagram showing an installation configuration of the frame material when the slate roof 12 of FIG. 6 is changed to a steel plate roof.
As shown in FIG. 8, the steel plate roof 15 generally has a larger unevenness on the roof surface than the slate roof 12, so that the frame member 16 can be installed without using the spacer 46 described above. That is, for example, when the existing bolt 44 that fixes the steel plate roof 15 protrudes from the convex portion of the steel plate roof 15, the frame material 16 is fixed using this bolt 44. Further, even when the convex portion of the steel plate roof 15 is not provided with the bolt 44, when the convex portion is flat, the frame member 16 and the steel plate roof 15 may be bonded and fixed using an adhesive or the like.

Next, the circulation system 20 will be described.
FIG. 9 is a system diagram showing the flow of liquid fertilizer and details of equipment in the circulation system 20.
As shown in FIG. 9, the circulation system 20 includes a liquid manure tank 26 for storing the liquid manure 18, a water supply pipe 22 and a pump P <b> 1 for supplying the liquid manure 18 from the liquid manure tank 26 to the medium 14, and an extra medium 14. A drain pipe 24 for draining the liquid manure 18 to the liquid fertilizer tank 26, a bypass pipe 54 connecting the water supply pipe 22 and the drain pipe 24, various valves (V1 to V4) for controlling the water flow, and a circulating liquid manure 18, a sterilizer 58 for sterilizing the liquid manure 18 supplied to the culture medium 14, a heater 60 and a cooler 62 for adjusting the temperature of the liquid fertilizer 18 in the tank, and the liquid fertilizer tank 26 or the culture medium 14. It comprises various sensors (S1 to S4) that monitor the liquid fertilizer 18 and a data logger 64 that displays, records, or warns of abnormal values measured by these sensors.

  The liquid fertilizer tank 26 has a capacity capable of supplying sufficient liquid fertilizer to the culture medium 14, and is preferably made of metal or plastic and having light shielding properties.

  The water supply pipe 22 and the drain pipe 24 are preferably made of a light-shielding material, for example, a general-purpose water pipe or hard PVC pipe. However, the present invention is not limited to this, and a flexible vinyl chloride pipe that can be bent easily may be used in consideration of easy handling of piping and the like.

  The pump P <b> 1 has a performance capable of sufficiently supplying the liquid fertilizer 18 stored in the liquid fertilizer tank 26 to the culture medium 14 provided on the top of the roof through the water supply pipe 22.

  Further, the water supply pipe 22, drain pipe 24 and bypass pipe 54 in the system are provided with valves V1 to V3, respectively, so that the flow of the liquid fertilizer 18 in the system can be controlled by opening and closing these valves as appropriate. It has become. For example, normally, the liquid fertilizer valves 18 are circulated between the culture medium 14 and the liquid fertilizer tank 26 by opening the liquid fertilizer valves V1 and V2 and closing the valve V3. On the other hand, when clogging or the like occurs in the drainage port of the culture medium 14 and it is desired to eliminate the clogging, the liquid fertilizer valves V1 and V2 are closed and the valve V3 is opened to reverse the liquid fertilizer 18 in the drainage pipe 24 and drain the water. What is clogged in the mouth can be discharged into the culture medium 14.

  The air mixer 56 is for mixing air into the liquid fertilizer 18, and is provided between the valve V <b> 2 in the drain pipe 24 and the liquid fertilizer tank 26, for example.

FIG. 10 is a cross-sectional view showing the internal structure of the air mixer 56.
As shown in FIG. 10, the air mixer 56 includes two propellers 66 that rotate in opposite directions with respect to the flow in one direction, and the pipe shaft of the drain pipe 24 in the pipe line of the drain pipe 24. And an air hole 68 penetrating the inside and outside of the drain pipe 24 is formed in the vicinity of the installation position of the propeller 66. With this structure, for example, when liquid flows from above, a flow of water and air occurs in the drain pipe 24, and the air pressure in the drain pipe 24 becomes negative compared to the external pressure outside the pipe. The air flows into the drainage pipe 24 through the air holes 68, and the water and air in the drainage pipe 24 are agitated and mixed by the two propellers 66 that are rotated in reverse directions by the flow. Is adopted. A runner storage case 67 made of a cylindrical frame is provided in the air mixer 56, and the rotating shaft 69 of the propeller 66 is supported by a bearing 71 provided in the runner storage case 67.

  The sterilizer 58 (see FIG. 9) is for suppressing the growth of bacteria such as Fusarium bacteria that cause withering disease and root rot caused by bacteria that become prominent when the water temperature rises. For example, the valve V1 in the water supply pipe 22 is used. And the medium 14. The sterilizer 58 includes, for example, one that sterilizes the liquid fertilizer 18 by heating and one that irradiates the liquid fertilizer 18 with ultraviolet light from a sterilization lamp, but any device that can be sterilized may be used. Further, as long as the liquid fertilizer tank 26 itself has a function such as heating or ultraviolet irradiation, the liquid fertilizer tank 26 need not be provided in the pipeline.

  To adjust the temperature of the liquid fertilizer 18, while preventing freezing in the winter, the heater 60 for keeping the temperature of the liquid fertilizer 18 properly (for example, minus 5 ° C. or more) and the liquid fertilizer 18 in the medium 14 rise abnormally in summer. A cooler 62 that cools the liquid fertilizer 18 is provided in the liquid fertilizer tank 26 so as not to occur (for example, 30 ° C. or less).

  The liquid fertilizer tank 26 is provided with a temperature sensor S1, a concentration sensor S2, and a water level sensor S3 for monitoring the temperature of the liquid fertilizer 18, the concentration of the liquid fertilizer 18, and the water level. It is monitored and recorded, and when an abnormal value is indicated, an alarm is given. The culture medium 14 is also provided with a water level sensor S4, which is monitored and recorded together with the sensors S1 to S3.

  In addition, you may provide the control apparatus 70 which controls the heater 60 and the cooler 62 according to the temperature measured with the temperature sensor S1.

  Moreover, the liquid fertilizer 18 sprinkled from the sprinkler 42 may be made into a system that branches from the water supply pipe 22, and a valve V4 may be provided in the middle of branching to control the water spray by opening and closing the valve V4.

  In order to save water, the water source used in the liquid fertilizer tank 26 may be configured to supply rainwater from a rainwater collecting mass 72 or the like provided outdoors. In this case, a pump P <b> 2 may be provided that starts according to a predetermined amount of collected water and supplies rainwater to the liquid fertilizer tank 26 and stops when water is sufficiently supplied to the liquid fertilizer tank 26.

  Further, the power supply of the circulation system 20 is preferably provided by power storage type solar power generation in consideration of energy saving and environmental measures.

  As shown in FIG. 1 again, in order to prevent fallen leaves falling on the slate roof 12 from accumulating in the gutter 13 and clogging the gutter 13, a leaf receiver 74 and a leaf A scraping device 76 for cleaning the fallen leaves and the like accumulated in the receptacle is provided.

FIG. 11 is an elevational view showing the components of the scraping device when viewed from the direction A in FIG. 1, and FIG. 12 is an internal structural diagram when viewed from the direction B in FIG.
As shown in FIGS. 11 and 12, for example, the leaf receiver 74 has a comb-shaped screen 78 attached to a peripheral end portion of a receiving portion 77 in which about a half of the circumference of a cylindrical pipe made of PVC is cut out. The tip of the screen 78 is installed along the rain gutter 13 while being inserted into the concavo-convex end of the slate roof 12, and spans the same length as the gutter 13 along the longitudinal direction of the rain gutter 13. Installed.

  Further, in the receiving portion 77 of the leaf receiver 74, for example, a scraper device 76 comprising a cylindrical scraper can 80 and a wire 82 connected to the scraper can 80 from the ground via the end of the gutter 13 is provided. It has been.

  As a result, the rainwater flowing through the slate roof 12 passes through the screen 78 and falls into the rain gutter 13 below the screen 78, so that only the fallen leaves are caught in the leaf receiver 74 without collecting water. The collected fallen leaves can be cleaned by pulling the wire 82 from the ground and moving the scraper can 80 in the longitudinal direction.

  As described above, according to the roof greening device 10 according to the present embodiment, the medium 14 is directly installed on the slate roof 12 and has a simple and lightweight configuration that does not provide heavy objects such as support columns. It can also be installed on the slate roof 12 used in the building.

  Further, the PVC pipe 30 forming the culture medium 14 can minimize the inflow of rainwater and the irradiation of sunlight into the culture medium 14 by forming the opening 28 only in the portion where the hedera 19 is implanted. The medium 14 can be maintained as an environment suitable for the growth of the hedera 19 in order to prevent the maintenance of the concentration of the liquid fertilizer 18 or the occurrence of blue-tailed fish.

  Moreover, according to the roof greening apparatus 10 of this embodiment, by providing the circulation system 20, the liquid fertilizer 18 supplied to the culture medium 14 can be repeatedly circulated and used, and the amount of liquid fertilizer 18 required for cultivation can be reduced. You can save.

  Further, according to the liquid fertilizer tank 26 of the circulation system 20 of the present embodiment, the heater 60 and the cooler 62 are provided so that the temperature of the liquid fertilizer 18 replenished to the culture medium 14 is excessive for the hedera 19 to grow in summer. Therefore, it can be avoided that the liquid fertilizer 18 is frozen at a low temperature that is not suitable for the use of the liquid fertilizer 18 in the winter or the liquid fertilizer 18 is frozen. This contributes to the maintenance of an appropriate growth environment of the hedera 19.

  Further, according to the circulation system 20 of the present embodiment, the temperature sensor S1 for monitoring the temperature of the liquid fertilizer tank 26, the concentration of the liquid fertilizer tank 26, the water level of the liquid fertilizer tank 26, and the water level of the liquid fertilizer tank 26 of the culture medium 14, the concentration The sensor S2 and the water level sensors S3 and S4 are provided, and the measured values by these sensors are monitored and recorded by the data logger 64. When an abnormal value is indicated, an alarm is given to affect the growth environment of the hedera 19. The liquid fertilizer tank temperature, concentration, water level, and water level of the culture medium 14 that are factors can be easily and appropriately maintained.

  Moreover, according to the circulation system 20 of this embodiment, it drains from the culture medium 14 by providing the drainage pipe 24 and the bypass pipe 54, and the valves V1-V3 which can control the flow of the liquid fertilizer 18 in the drainage pipe 24 in reverse flow. When clogging occurs near the drain outlet of the drain pipe 24, clogging in the drain pipe 24 can be easily eliminated by causing the water flow to flow backward from the drain pipe 24 to the culture medium 14. Therefore, repair work such as replacement of the drain pipe 24 when clogging occurs can be avoided, which contributes to cost reduction.

  Moreover, according to the circulation system 20 of this embodiment, air can be mixed with the liquid manure 18 which flows in the drain pipe 24 by providing the air mixer 56, and the liquid manure 18 mixed with this air is used. By cultivating Hedera 19, the respiratory action of the roots of Hedera 19 can be promoted, and Hedera 19 can be grown well.

  Moreover, since the polyvinyl chloride tube 30 forming the culture medium 14 of the present embodiment includes the seedling culture medium 33 and the fastener 32, the root part and the stem part of the Hedera 19 can be held. It is possible to reduce the stress generated when the state is not performed and to grow the Hedera 19 well. Further, the hedera 19 can be prevented from falling off the PVC pipe 30.

  Moreover, according to the roof greening apparatus 10 of this embodiment, the air permeability and water permeability in the culture medium 14 can be maintained by filling the culture medium 14 with a filler 36 such as zeolite or oyster shell, and the hedera 19 Can be grown well.

  Further, according to the roof tree planting apparatus 10 of the present embodiment, the frame member 16 or the net member 17 is provided at a predetermined distance from the slate roof 12, for example, near the surface of the slate roof 12 by sunshine such as summer. This increases the temperature of the hedera 19 so that the growth environment of the hedera 19 deteriorates or the hedera 19 itself contacts the heated slate roof 12 and suffers damage.

  Moreover, even when a vine plant having aerial roots is planted, it is possible to avoid the air roots from reaching the slate roof 12, so that it is easy to replace the planting device when the vine plant has withered, and It is possible to prevent airborne traces from remaining on the slate roof 12 and soiling the roof surface.

  Further, according to the roof greening device 10 of the present embodiment, the frame material 16 is a C channel or a hollow square material having a notch formed over the entire upper surface along the longitudinal direction, and absorbs moisture. Since the water-retaining material 38 is filled so as not to fall out of the frame material 16, the roots of the hedera 19 can be appropriately lowered to the moisture-absorbing water-retaining material 38 in the frame material 16. Can be held by itself without using a holding tool or the like. In addition, since moisture or liquid fertilizer 18 is supplied from the moisture-absorbing water retaining material 38, the growth of the hedera 19 can be promoted.

Moreover, according to the roof tree planting apparatus 10 of this embodiment, it is installed on the slate roof 12 of the factory building, so that after aging, the slate roof is deteriorated by sunburn and its surface changes to black. Can be greened and beautified, and because the Hedera 19 blocks direct sunlight from hitting the roof, the rise in indoor temperature accompanying the rise in roof temperature due to summer sunshine can be mitigated. As a result, the working environment in the factory can be improved, and the power used for cooling can be saved, contributing to energy saving. In addition, it contributes to the reduction of CO ₂ in urban areas and the suppression of the heat island phenomenon.

  Further, according to the roof greening device 10 of the present embodiment, the sterilizer 58 is provided in the path of the water supply pipe 22, so that the liquid manure 18 supplied to the medium 14 is sterilized and the bacteria in the medium 14 are propagated. Can be avoided, and the medium 14 can be maintained as a good growth environment for the plant. In hydroponics over a long period of time, the generation of bacteria that affect growth is an extremely important issue to be solved. In such a case, the sterilizer 58 exhibits its effect.

  In addition, when hydroponics is used for hydroponics, if the liquid fertilizer 18 is used for a long period of time, waste products and specific fertilizer components are left over, so that a part or all of the liquid fertilizer 18 is exchanged at regular intervals. However, according to the circulation system 20 of this embodiment, since the liquid fertilizer tank 26 is provided, the liquid fertilizer 18 in the liquid fertilizer tank 26 can be replaced to easily maintain the liquid fertilizer 18. it can.

  Further, according to the roof greening device 10 of the present embodiment, by providing a plurality of sprinklers 42 on the top of the roof of the slate roof 12, water can be sprayed directly on the stems or leaves of the Hedera 19, and the air humidity can be reduced. The temperature of the leaves can be lowered and the growth environment of the plant can be improved when the temperature is high in summer and the like, and the occurrence of spider mites and aphids can be prevented. In addition, the temperature of the slate roof 12 can be lowered, the temperature increase in the indoors in summer can be mitigated, and the heat island can be suppressed.

  Further, according to the roof greening device 10 of the present embodiment, the rain water flowing through the slate roof 12 passes through the screen 78 of the leaf receiver 74 by providing the slate roof 12 with the leaf receiver 74 and the scraper 76. Since it falls on the rain gutter 13 below, the leaf receiver 74 catches only the fallen leaves without collecting water, and pulls the wire can 82 to the scraper can 80. By moving the, the fallen leaves accumulated in the leaf receptacle 74 can be collected and the inside of the leaf receptacle 74 can be cleaned. As a result, the rain gutter 13 is not clogged with fallen leaves falling from the hedera 19 that grows on the slate roof 12.

  In addition, according to the culture medium 14 of the roof greening apparatus 10 by this embodiment, although the example installed one with respect to one roof was shown, not only this but multiple installation according to the length of the inclination direction of a roof is carried out. (Not shown). In this case, the culture medium 14 to be added is installed in the horizontal direction on the roof.

  Moreover, according to the roof greening apparatus 10 by this embodiment, although the air mixer 56 was provided between the valve | bulb V3 and the liquid fertilizer tank 26 in the drain pipe 24, it is not restricted to this, The pipe line of the water supply pipe 22 May be provided. Moreover, it is good also as a structure which does not use the air mixer 56, but provides the air outlet of an air pump in the liquid manure tank 26, and injects air directly into the liquid manure 18. FIG.

  Moreover, according to the roof greening apparatus 10 by this embodiment, although the frame material 16 and the net | network material 17 for extending the hedera 19 were installed in the slate roof 12, it is not restricted to this, These frame material 16 and the net | network material 17 May be omitted. In this case, the hedera grows while drooping along the slate roof, but it may be configured to cover the top of the hedera 19 with a net or the like at a certain interval so that the extending direction is not disturbed by the wind. .

It is a perspective view which shows the external appearance at the time of applying the roof planting apparatus which concerns on this invention to the slate roof used in buildings, such as a factory. It is the figure which extracted the part of the culture medium from the greening apparatus of FIG. FIG. 3 is a longitudinal sectional view of FIG. 2 and b) A-A ′ transverse sectional view. (A) The longitudinal cross-sectional view which shows an example of the culture medium which employ | adopted the dripping water supply system, and (b) A-A 'cross-sectional view. It is the expansion perspective view which expanded the part which concerns on a frame material, and its peripheral part among the roof greening apparatuses of FIG. It is a figure which shows arrangement | positioning of the slate roof and frame material when it sees from the C direction of FIG. It is a perspective view which shows the structure which changed the frame material of FIG. 5 into the net | network material. It is a figure which shows the installation structure of the frame material at the time of changing the slate roof of FIG. 6 into a steel plate roof. It is a systematic diagram showing the flow of liquid manure of the circulation system and details of the equipment. It is sectional drawing which shows the internal structure of an air mixer. FIG. 2 is an elevational view when viewed from the A direction showing the components of the scraping device of FIG. 1. It is an internal structure figure when it sees from the B direction which shows the component of the scraping apparatus of FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Greening device 12 Slate roof 13 Rain gutter 14, 90 Medium 15 Steel plate roof 16 Frame material 17 Mesh material 18 Liquid manure 19 Hedera 20 Circulation system 22 Water supply pipe 24 Drain pipe 26 Liquid fertilizer tank 28 Opening 30 PVC pipe 36 Filling 38 Moisture retention water Material 42 Sprinkler 50 Holding material 56 Air mixer 58 Sterilizer 60 Heater 62 Cooler 64 Data logger 66 Propeller 68 Air hole 74 Leaf holder 76 Scraper 78 Screen 80 Scraper 82 Wire V1, V2, V3 Valve P1, P2 Pump S1 Temperature sensor S2 Concentration sensor S3, S4 Water level sensor

Claims (13)

A device for greening the roof of a structure,
A pipe that is provided on the roof of the structure and serves as a plant cultivation tank;
A frame material or netting material or a mat-like water retaining material that is attached along the surface of the roof and supports the plant that has grown
A liquid fertilizer tank for storing liquid fertilizer, a water supply pipe for supplying liquid fertilizer from the liquid fertilizer tank to the pipe, a drain pipe for returning the liquid fertilizer discharged from the pipe to the liquid fertilizer tank, and liquid fertilizer in the liquid fertilizer tank A circulation device including a pump for feeding into the water supply pipe ,
The circulation system, roof greening system according to Rukoto characterized with backflow means for flowing back to the tube body the liquid fertilizer from the drain pipe.   The roof planting apparatus according to claim 1, wherein the tubular body has an opening formed only in a portion where the plant is planted. The tank roof greening system according to claim 1 or 2, characterized in that it comprises an adjustable heater and cooler the temperature of the liquid manure to be stored in the tank. The circulation device includes a temperature sensor that measures the temperature of liquid fertilizer in the tank, a concentration sensor that measures the concentration of liquid fertilizer in the tank, a water level sensor that measures the level of liquid fertilizer in the tank, or a liquid fertilizer in the tubular body Including at least one of water level sensors for measuring the water level of
2. A monitoring recording device having a function of warning an abnormality when a measured value by the sensor provided is an abnormal value, and automatically recording the measured value. The roof greening apparatus of any one of -3 . A pair of propellers are installed inside the water supply pipe or drain pipe so as to rotate in opposite directions by the flow of liquid fertilizer in the pipe line, and the water supply pipe or drainage is located near the installation position of these propellers. The roof greening device according to any one of claims 1 to 4 , further comprising an air mixing device in which an air hole penetrating the inside and outside of the tube is formed. The roof greening apparatus according to any one of claims 1 to 5 , wherein a sterilization apparatus for sterilizing bacteria that propagate in liquid fertilizer is provided in a circulation system of the circulation apparatus. The roof greening apparatus according to claim 6 , wherein the sterilization apparatus performs sterilization by ultraviolet irradiation or heating. The roof planting apparatus according to any one of claims 1 to 7 , wherein a holder for holding the plant is provided on the tubular body. The roof greening apparatus according to any one of claims 1 to 8 , wherein the pipe body is filled with zeolite, oyster shell, or pumice. The roof greening apparatus according to any one of claims 1 to 9 , wherein the roof is made of slate . The roof, roof greening system according to any one of claim 1 to 9, characterized in that it is made of steel. The roof greening apparatus according to any one of claims 1 to 11 , wherein a water sprinkler capable of spraying the plant is provided on the roof. Provided on the upper side of the rain gutter installed on the roof, provided with a substantially concave leaf receiver with a screen through which rain water passes,
A wire is connected to the inside of the leaf receptacle, and a scraper body capable of scraping the fallen leaves of the plants accumulated in the leaf receptacle by moving the inside of the leaf receptacle in the longitudinal direction by pulling the wire is provided. The roof planting apparatus according to any one of claims 1 to 12 , wherein a scraping device is provided.

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