JP2011254784A - Photo-catalytic net and manufacturing method for the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a photo-catalytic net that, when used in a greenhouse, prevents invasion of insect pests, entering from the outside, into the greenhouse while allowing sunlight to pass therethrough as well as allowing bacteria-containing air in the greenhouse to be efficiently brought into contact with a photo-catalyst.SOLUTION: The photo-catalytic nets 5 are respectively placed at an entrance 4 and a skylight 1 of a greenhouse 100. The photo-catalytic nets 5 are substantially horizontally placed near a ceiling 38 at prescribed intervals. Preferably, an air blower 7 is installed near the ceiling 38. The photo-catalytic nets 5 of the entrance 4 and the skylight 1 prevent invasion of insect pests from the outside of the greenhouse 100. Air circulating in the greenhouse 100 passes through the photo-catalytic nets 5 near the ceiling 38 in order to sterilize bacteria floating in the greenhouse 100. The nets are used in order to allow sunlight to pass therethrough.

Description

  The present invention relates to a photocatalyst net that prevents invading pests and the like by a photocatalyst net and kills germs in a greenhouse, and a method for producing the same.

  Conventionally, there has been a problem of harmful insects that invade into the greenhouse and damage the crops, and germs that cause crop diseases. As a countermeasure against such pests and bacteria, a technique as described in Patent Document 1 is known.

  In the invention according to Patent Document 1, a non-woven fabric is coated with titanium dioxide as a photocatalyst, and pathogenic bacteria are removed by placing or suspending the nonwoven fabric in a greenhouse, thereby reducing the amount of agricultural chemicals used.

JP 2005-137351 A

  However, in the greenhouse described in Patent Document 1, since the nonwoven fabric is coated with titanium dioxide, air in the greenhouse containing various germs cannot be efficiently brought into contact with the photocatalyst, and pests entering from the outside are prevented. There was a problem that it was not possible. In addition, when used in a greenhouse, there is a problem of blocking sunlight. The present invention has been made to solve such problems.

Therefore, the photocatalyst net of the present invention is characterized in that the photocatalyst is attached to the surface of the net via an inorganic binder.

  The photocatalyst net of the present invention is characterized in that, in the above invention, the mesh of the net is 1 mm or more.

  The photocatalyst net of the present invention is characterized in that in the above invention, the amount of photocatalyst attached to the surface of the net is larger than that of the back surface.

  Further, the photocatalyst net manufacturing method of the present invention transports the net in one direction and reverses it with a roller and transports it in a substantially parallel direction, and further reverses it with a roller and transports it again in approximately one direction. A liquid inorganic binder containing fine particles of a photocatalyst is sprayed from above from an injection device.

  The method for producing a photocatalyst net according to the present invention is characterized in that, in the above invention, the photocatalyst net is further blown and dried with respect to the sprayed net.

  The photocatalyst net is suitable for greenhouses, tunnels and the like.

It is a perspective view which shows the greenhouse which concerns on embodiment of this invention. It is a front view of the greenhouse shown in FIG. It is a top view of the greenhouse shown in FIG. It is a top view of the greenhouse shown in FIG. It is explanatory drawing which shows the manufacturing process of the photocatalyst net | network 5. FIG. It is explanatory drawing which shows the function of this greenhouse. It is explanatory drawing which shows the function of this greenhouse.

  FIG. 1 is a perspective view showing a greenhouse according to an embodiment of the present invention. 2 is a front view of the greenhouse shown in FIG. 1, FIG. 3 and FIG. 4 are plan views. The greenhouse 100 has a structure in which a transparent vinyl sheet or glass is stretched on a steel frame. Specifically, as shown in FIGS. 1 and 2, a plurality of pillars 32 are set up with respect to a foundation 31 embedded in the ground, and a beam 33 constituting a gable roof is passed between the pillars 32. An internal reinforcing member 34 is horizontally provided between the pillars 32 and 32, and a land beam 35 is provided between the beams 33 and 33. A suspension wire 37 for suspending the curtain wire 36 is provided at the center of the land beam 35, and the curtain wire 36 passed between the columns 32 and 32 is suspended at the center.

  An openable skylight 1 is provided on the ceiling 38. An insect net 3 is provided between the skylight 1 and the opening 2. The insect net 3 is constituted by a photocatalyst net 5 described later. An entrance 4 is provided in front of the greenhouse 100, and the entrance 4 is composed of a photocatalyst net 5 having a predetermined scale.

A plurality of photocatalyst nets 5 are arranged substantially horizontally on the internal reinforcing material 34 of the greenhouse 100. The photocatalyst net 5 is stretched on the frame body 6, and the frame body 6 is fixed to the internal reinforcing material 34. In other words, the photocatalyst net 5 is provided in the upper part of the greenhouse 100 away from the ceiling 38. Note that the photocatalyst net 5 is not necessarily provided in the entire horizontal area of the ceiling 38. For example, about half the area of the ceiling 38 may be used. Thus, by arranging the photocatalyst net 5 in the upper part of the greenhouse 100, when the air in the greenhouse 100 circulates, it passes through the photocatalyst net 5 and effectively kills germs in the greenhouse 100. it can. Further, it is desirable that the photocatalyst net 5 is disposed under the curtain wire 36 so that the photocatalyst net 5 is positioned below the curtain even when the curtain in the greenhouse 100 is closed. In this embodiment, as shown in FIG. 4, the four photocatalyst nets 5 are installed at a predetermined interval with respect to the internal reinforcing material 34.

  A blower 7 that circulates the air inside the greenhouse 100 is installed. The blower 7 has a structure in which a rotating blade is provided inside a cylindrical main body (not shown), and is suspended from the internal reinforcing material 34 and installed. The blower 7 is positioned below the photocatalyst net 5. Further, the air blower 7 is set so that the air blowing direction is substantially horizontal with respect to the ground and the longitudinal direction of the greenhouse, and preferably the air blowing direction is slightly upward. This is because the wind easily hits the photocatalyst net 5. It can also be installed slightly in the left-right direction. In this embodiment, as shown in FIG. 4, two blowers 7 are installed between the photocatalyst net 5 and the photocatalyst net 5.

  Next, an air supply unit 8 is provided at the end in the greenhouse 100. As shown in FIG. 3, the air supply unit 8 is provided with a parent duct 9, and the parent duct 9 is disposed in the longitudinal direction along the lower part of the wall surface of the greenhouse 100. The parent duct 9 is provided with a small duct 10 in a comb shape. The small duct 10 is made of a soft material and is appropriately placed under or between the crops. The parent duct 9 and the small duct 10 can be simply connected and extended. A plurality of air jets 11 are provided on the surface of the small duct 10. The air supplied from the air supply unit 8 is supplied to each small duct 10 through the parent duct 9, and the air is ejected from the air outlet 11. Thereby, the germs under the leaf of a crop can be skipped.

It is desirable that the size of the entrance 4 and the photocatalyst net 5 of the skylight 1 satisfy the conditions of preventing the invasion of pests, good ventilation, and sufficient penetration of sunlight. The photocatalyst has an effect of repelling insects, but when a pest enters from the outside, it temporarily stops on the net and then enters from between the eyes, so if the photocatalyst is applied to the net, the pest dislikes the photocatalyst , It stays on the photocatalyst net 5 and leaves the photocatalyst net 5 without entering the inside. For this reason, if the pests are smaller than the pests that pass through without contacting the photocatalyst net 5 and enter the interior, they can satisfy all of the pest invasion prevention, ventilation, and sunlight permeability. it can. Specifically, the scale of the photocatalyst net 5 is 0.5 mm or more and 10 mm or less, preferably 1 mm or more and 5 mm or less. Even if the photocatalyst net 5 having a mesh size of less than 0.5 mm is used, there is a certain effect.

  By preventing the insects from trapping on the photocatalyst net 5, it is possible to prevent spawning on the photocatalyst net 5, and even if dead insect pests adhere, they are decomposed and disappear by the action of the photocatalyst, so that the net is not soiled.

  The photocatalyst net 5 has a structure in which a photocatalyst is coated on the surface of a net made of organic fibers via an inorganic binder. The reason why the inorganic binder is used is that when the photocatalyst is directly applied to the organic fiber, the organic fiber is decomposed. Titanium dioxide is used as the photocatalyst, but is not limited thereto. The photocatalyst net 5 used in the greenhouse 100 may be a metal net coated with a photocatalyst. In this case, an inorganic binder is unnecessary, and it is only necessary to directly coat the photocatalyst on a metal net.

  FIG. 5 is an explanatory view showing a manufacturing process of the photocatalyst net 5. The photocatalyst net 5 manufacturing apparatus 50 includes a pair of first rollers 51 that convey a net 59 made of organic fibers, a second roller 52 that is disposed at a predetermined interval from the first roller 51, and a second roller 52 and a predetermined roller. A third roller 53 arranged at an interval, a pair of fourth rollers 54 arranged at a predetermined interval from the third roller 53, an injection device 55 for injecting a liquid inorganic binder 56 mixed with a photocatalyst, and a dryer 60 It consists of.

The net 59 carried out from the first roller 51 is conveyed in one direction, is reversed by the second roller 52 and is conveyed substantially in the reverse direction, and is reversed again by the third roller 53 and is substantially parallel in one direction. It is conveyed and pulled out by the fourth roller 54 to be carried out. When the liquid inorganic binder 56 containing the photocatalyst fine powder is sprayed from above from the injection device 55, the surface 59 a of the net 59 is coated between the first roller 51 and the second roller 52.

Next, since the net 59 is reversed by the second roller 52, the back surface 59b is coated with a liquid inorganic binder 59 containing a photocatalyst that has passed through the upper net 59. Subsequently, since the net is reversed again by the third roller 53, the surface 59a is coated again with the liquid inorganic binder 56 containing the photocatalyst that has passed through the upper net 59. As described above, by spraying the liquid inorganic binder 56 containing the photocatalyst, the front surface 59a is coated approximately twice, and the back surface 59b is coated once. Then, the net 59 is conveyed by the fifth roller 61 and is dried by the relatively strong cold air of the dryer 60 during that time. The air blows away the inorganic binder 59 clogged by the net due to the surface tension, thereby eliminating clogging of the net. The dried net 59 is taken up by the take-up roller 62.

  It is necessary to increase the amount of the photocatalyst to be coated in order to manufacture the photocatalyst net 5 which is harmful to pests, but it is not efficient to increase the amount of the photocatalyst on both sides of the net 59. For this reason, the net 59 is sent in an S shape as described above, and a large number of photocatalysts can be coated on one surface (front surface 59a) by spraying from above. Then, the surface coated with a large amount of photocatalyst is attached to the outside of the window or the entrance 4. If it does in this way, the high insect-proof effect can be exhibited with respect to the pest which invades from the outside. It is preferable to mark the photocatalyst net 5 in advance so that the front surface 59a and the back surface 59b of the photocatalyst net 5 can be easily distinguished.

  FIG. 6 is an explanatory diagram showing the function of this greenhouse. What is required for the greenhouse 100 is insect repellent and sterilization. The entrance 4 and the photocatalytic net 5 of the skylight 1 prevent insects from entering from the outside of the greenhouse 100. In addition, pests may lay eggs on a general greenhouse net. However, since the photocatalyst net 5 coated with a photocatalyst is used in the greenhouse 100, the pests hate the photocatalyst and can prevent egg laying. Also, when the pests gather in a warm place near the ceiling 38, if the photocatalyst net 5 is installed under the ceiling 38, the pests dead near the ceiling 38 fall on the photocatalyst net 5 on the ceiling 38 side and the action of the photocatalyst. Decomposes and disappears.

  In addition, germs floating in the greenhouse 100 can be killed by the action of the photocatalyst. Although germs enter the greenhouse 100 together with air from the outside, the germs entering from the outside are first killed by the photocatalyst net 5 provided at the entrance 4 and the skylight 1. Moreover, since the air in the greenhouse 100 circulates by opening the skylight 1 of the greenhouse 100, the internal air then passes through the photocatalyst net 5 near the ceiling 38.

When the greenhouse 100 is closed and the air in the greenhouse is agitated by the blower 7, the wind of the blower 7 is sent in one direction in the longitudinal direction of the upper part of the greenhouse, and hits and turns back at the end as shown in FIG. , Sent in the opposite direction of the longitudinal direction of the lower part of the greenhouse, and as a result, circulates in the greenhouse 100. Since the wind of the blower 7 flows along the photocatalyst net 5, the air circulating in the greenhouse 100 always hits the photocatalyst net 5. Therefore, various germs floating in the greenhouse 100 are sterilized by the photocatalyst net 5. Moreover, when air circulates in the greenhouse 100, various germs touch the photocatalyst net 5 of the entrance 4 or the skylight 1 to be sterilized.

  Further, various germs floating under the leaves of the crop are blown upward together with the staying air by the air ejected from the air ejection port 11 of the small duct 10 as shown in FIG. As shown in FIG. 7, the air blown upward joins the circulating air by the blower 7 and is sterilized by the photocatalyst net 5.

  As described above, according to the greenhouse 100, the insecticide and sterilization can be performed by the photocatalyst net 5 coated with the photocatalyst, so that the agricultural chemicals used in the greenhouse 100 can be greatly reduced. In particular, when the photocatalyst net 5 is provided at the entrance 4 or the skylight 1, not only a bactericidal action but also an insecticidal action can be used. In addition, the use of a net instead of a non-woven fabric can prevent sunlight from being blocked, which is suitable for a greenhouse. Furthermore, germs floating around the crop can be killed.

  In the photocatalyst net 5, a pigment such as yellow, reflected color, red, green or purple may be mixed with an inorganic binder. The selection of this pigment should be a color that cannot be seen by insects to be repelled. In particular, red pigments are preferred because they appear dark to insects. Further, a predetermined color fiber may be woven into the net organic fiber itself.

100 Greenhouse 5 Photocatalyst net 38 Ceiling 1 Skylight 7 Blower

Claims (5)

A photocatalyst net, wherein a photocatalyst is attached to the surface of the net through an inorganic binder. The photocatalyst net according to claim 1, wherein the mesh of the net is 1 mm or more. The photocatalyst net according to claim 1 or 2, wherein the photocatalyst is attached to the surface of the net more than the back surface. The net is transported in one direction, reversed by a roller and transported in approximately parallel to the reverse direction, further reversed by a roller and transported in approximately one direction again in parallel, and a liquid inorganic containing photocatalyst fine powder from the injection device A method for producing a photocatalyst net, wherein a binder is sprayed from above. Furthermore, it blows with respect to the net | network which sprayed the photocatalyst net, and it dries, The manufacturing method of the photocatalyst net | network of Claim 4 characterized by the above-mentioned.