JP2019054758A - Emitter and drip irrigation tube - Google Patents

Abstract

To provide an emitter and a drip irrigation tube which can suppress clogging in a flow channel due to accumulation of foreign matters more effectively, and can quantitatively discharge irrigation liquid.SOLUTION: An emitter, when joined to a position of an inner wall face of a tube for allowing irrigation liquid to circulate, which corresponds to a discharge port communicating an outside/inside of the tube, quantitatively discharges the irrigation liquid in the tube outside the tube from the discharge port. The emitter has: an emitter body which takes in the irrigation liquid in the tube and quantitatively discharges the irrigation liquid from a discharge part; and a holding member which is equipped with a communication hole for communicating the discharge port of the tube and the discharge part of the emitter, and vibratably holds the emitter body when joined to the inner wall face of the tube.SELECTED DRAWING: Figure 2

Description

  The present invention relates to an emitter and a drip irrigation tube having the emitter.

  The drip irrigation method is known as one of the plant cultivation methods. The drip irrigation method is a method in which a drip irrigation tube is arranged on soil in which plants are planted, and irrigation liquid such as water or liquid fertilizer is dropped from the drip irrigation tube to the soil. In recent years, drip irrigation has attracted particular attention because it can minimize the consumption of irrigation liquid.

  A drip irrigation tube usually has a tube formed with a plurality of through holes through which irrigation liquid is discharged, and a plurality of emitters (also referred to as “drippers”) for discharging the irrigation liquid from each through hole. . As types of emitters, there are known an emitter (for example, see Patent Document 1) used by being joined to an inner wall surface of a tube, and an emitter used by being pierced from the outside into a tube.

  FIG. 1 is a diagram illustrating a configuration of an emitter 1 described in Patent Document 1 that is used by being joined to an inner wall surface of a tube. FIG. 1A is a perspective view showing the configuration of the emitter 1, and FIG. 1B is a partially enlarged bottom view of the flow path 2 in the emitter 1. The emitter 1 includes a water intake 3 for taking in the irrigation liquid, a discharge port 4 for discharging the irrigation liquid, and a flow path 2 having a control path 5 and a plurality of convex portions 6.

  The emitter 1 described in Patent Document 1 is used in a state where the surface on which the flow path 2 is formed is joined to the inner surface of the tube. The drip irrigation tube using the emitter 1 described in Patent Document 1 can supply irrigation liquid at a desired flow rate, and is clogged due to accumulation of foreign matters such as sand particles and sediment in the flow path 2. Can be suppressed. Patent Document 1 mentions that one of the reasons why clogging is suppressed is that a vortex is generated between adjacent convex portions 6.

JP-A-5-276841

  However, in the emitter described in Patent Document 1, the vortex flow is generated in a plane substantially parallel to a plane including the flow direction and the width direction of the flow path, so that the flow path can be stirred only two-dimensionally. Can not. For this reason, clogging due to the accumulation of foreign matter may not be sufficiently prevented. When clogging has occurred, it has been difficult to eliminate the clogging.

  Accordingly, an object of the present invention is to provide an emitter and a drip irrigation tube that can more effectively suppress clogging due to the accumulation of foreign matters in a flow path and can quantitatively discharge irrigation liquid.

  In order to solve the above-described problems, the emitter according to the present invention has a structure in which an inner wall of a tube through which an irrigation liquid is circulated is joined to a position corresponding to a discharge port that communicates the inside and outside of the tube. An emitter for quantitatively discharging the irrigation liquid from the discharge port to the outside of the tube, and taking the irrigation liquid in the tube and discharging the irrigation liquid quantitatively from the discharge unit A holding member having a communicating hole for communicating the emitter main body, the discharge port of the tube and the discharge portion of the emitter, and holding the emitter main body so as to vibrate when joined to the inner wall surface of the tube And having.

  In order to solve the above problems, a drip irrigation tube according to the present invention is joined to a tube having a discharge port for discharging irrigation liquid and a position corresponding to the discharge port on the inner wall surface of the tube. And an emitter according to the present invention.

  According to the present invention, clogging due to the accumulation of foreign matters in the flow path can be more effectively suppressed, and the irrigation liquid can be discharged quantitatively.

1A and 1B are diagrams showing the configuration of the emitter described in Patent Document 1. FIG. FIG. 2 is a cross-sectional view of the drip irrigation tube according to Embodiment 1 of the present invention. FIG. 3 is a diagram showing the configuration of the emitter body according to Embodiment 1 of the present invention. 4A and 4B are diagrams showing the configuration of the emitter body according to Embodiment 1 of the present invention. FIG. 5 is a diagram showing the configuration of the emitter body according to Embodiment 1 of the present invention. 6A to 6C are schematic diagrams for explaining the operation of the emitter body according to Embodiment 1 of the present invention. FIG. 7 is a cross-sectional view of a drip irrigation tube according to Modification 1. FIG. 8 is a cross-sectional view of a drip irrigation tube according to Modification 2.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

[Embodiment 1]
(Composition of drip irrigation tube)
FIG. 2 is a cross-sectional view in the direction along the central axis of the drip irrigation tube 100 according to Embodiment 1 of the present invention.

  As shown in FIG. 2, the drip irrigation tube 100 includes a tube 110 and an emitter 120.

  The tube 110 is a tube for flowing an irrigation liquid. The direction in which the irrigation liquid flows in the tube 110 is not particularly limited. Further, the material of the tube 110 is not particularly limited. In the present embodiment, the material of the tube 110 is polyethylene. The tube wall of the tube 110 is formed with a plurality of tube discharge ports 112 communicating with the inside and the outside of the tube 110 at a predetermined interval (for example, 200 to 500 mm) in the axial direction of the tube 110 to discharge the irrigation liquid. ing. The diameter of the opening of the tube discharge port 112 is not particularly limited as long as the irrigation liquid can be discharged. In the present embodiment, the diameter of the opening of the tube discharge port 112 is 1.5 mm. Emitters 120 are joined to positions on the inner wall surface of the tube 110 corresponding to the tube outlet 112. The cross-sectional shape and cross-sectional area perpendicular to the axial direction of the tube 110 are not particularly limited as long as the emitter 120 can be disposed inside the tube 110.

(Emitter configuration)
The emitter 120 has an emitter body 200 and a holding member 210. The emitter body 200 includes a flow path component 121 and a film 122. FIG. 3 is a plan view of the emitter body 200 before the flow path component 121 and the film 122 are joined. FIG. 4A is a plan view of the emitter body 200 after the flow path component 121 and the film 122 are joined, and FIG. 4B is a bottom view of the emitter body 200. However, in FIG. 4B, a bottom wall surface portion 190 (see FIG. 5) described later is omitted. FIG. 5 is a sectional view taken along line BB shown in FIG. 4A.

  As shown in FIG. 3, the emitter main body 200 includes a flow path component 121 and a film 122 joined to the flow path component 121. The flow path component 121 and the film 122 may be formed integrally or may be formed separately. In the present embodiment, the flow path component 121 and the film 122 are integrally formed via the hinge portion 123.

  In the present invention, the longitudinal direction of the emitter body 200 means the longitudinal direction when the emitter body 200 is viewed in plan, that is, the left-right direction in FIG. Similarly, the short direction of the emitter body 200 means the short direction when the emitter body 200 is viewed in plan, that is, the up and down direction in FIG.

  It is preferable that both the flow path component 121 and the film 122 are formed of one kind of flexible material. However, when the flow path component 121 and the film 122 are formed as separate bodies, the flow path component 121 may be formed of a material that does not have flexibility. Moreover, it is preferable that the diaphragm parts (the first diaphragm part 167 and the second diaphragm part 175) described later are also integrally formed as a part of the film 122. In this Embodiment, the flow-path structure part 121 and the film 122 containing a diaphragm part are integrally formed with one type of material which has flexibility.

  Examples of the material of the flow path component 121 and the film 122 include resin and rubber. Examples of the resin include polyethylene and silicone. The flexibility of the flow path component 121 and the film 122 can be adjusted by using an elastic resin material. Examples of methods for adjusting the flexibility of the flow path component 121 and the film 122 include selection of a resin having elasticity, adjustment of a mixing ratio of a resin material having elasticity with respect to a hard resin material, and the like. The integrally molded product of the flow path component 121 and the film 122 can be manufactured by injection molding, for example.

  As shown in FIGS. 3 to 5, the flow path component 121 according to the present embodiment includes a water intake section 150, a first connection groove 131 that becomes the first connection flow path 141, and a first decompression flow path 142. The first decompression groove 132 to be, the second connection groove 133 to be the second connection channel 143, the second decompression groove 134 to be the second decompression channel 144, and the third decompression to be the third decompression channel 145 It has a groove 135, a flow rate reducing portion 160, a flow path opening / closing portion 170, a discharge portion 180, and a bottom wall surface portion 190. The water intake unit 150, the flow rate reduction unit 160, and the flow channel opening / closing unit 170 are disposed on the surface 125 side of the flow channel configuration unit 121 (emitter body 200). The first connection groove 131, the first pressure reduction groove 132, the second connection groove 133, the second pressure reduction groove 134, the third pressure reduction groove 135, the discharge part 180, and the bottom wall surface part 190 are connected to the flow path component 121 (emitter body). 200) on the back surface 124 side.

  As shown in FIGS. 3 and 5, the bottom wall surface portion 190 is a member that covers the back surface 124 side of the flow path forming portion 121. The bottom wall surface portion 190 may be integrally molded with the same type of material as the flow path component 121, or may be molded as a separate body. In the present embodiment, the bottom wall surface portion 190 is integrally formed via the hinge portion 191, and the bottom wall surface portion 190 is folded back and joined to the back surface 124 of the emitter to cover the back surface 124 side. . Note that an emitter discharge port 192 is provided at a position corresponding to the discharge portion 180 of the emitter body 200 and the communication hole 213 of the holding member 210 in the bottom wall surface portion 190. The emitter discharge port 192 is an opening provided in the bottom wall surface portion 190 and discharges the irrigation liquid taken into the emitter main body 200 to the outside of the flow path component 121 (emitter main body 200).

  By covering the back surface 124 side of the flow path component 121 with the bottom wall surface portion 190, the first connection groove 131, the first decompression groove 132, the second connection groove 133, the second decompression groove 134, and the third decompression groove 135 are A first connection channel 141, a first decompression channel 142, a second connection channel 143, a second decompression channel 144, and a third decompression channel 145, respectively. As a result, the water intake unit 150, the first connection channel 141, the first pressure reduction channel 142, the second connection channel 143, the second pressure reduction channel 144, the flow rate reduction unit 160, and the discharge unit 180 are configured. And a first flow path connecting the discharge unit 180 is formed. Further, it is constituted by a water intake unit 150, a first connection channel 141, a first decompression channel 142, a second connection channel 143, a third decompression channel 145, a channel opening / closing unit 170, a flow rate reducing unit 160 and a discharge unit 180. Thus, a second flow path connecting the water intake unit 150 and the discharge unit 180 is formed. In both the first channel and the second channel, the irrigation liquid is circulated from the water intake unit 150 to the discharge unit 180. In the present embodiment, the first flow path and the second flow path overlap between the water intake section 150 and the second connection flow path 143. Further, the downstream side of the channel opening / closing part 170 in the second channel is connected to the flow rate reducing unit 160, and the first channel and the second channel are also connected from the flow rate reducing unit 160 to the discharge unit 180. Are duplicates.

  The water intake unit 150 is disposed in an approximately half region of the surface 125 of the flow path component 121 (see FIGS. 3 and 4A). In the region of the surface 125 where the water intake unit 150 is not arranged, a flow rate reducing unit 160 and a flow path opening / closing unit 170 (film 122) are arranged. The water intake unit 150 includes a water intake side screen unit 151 and a water intake through hole 152.

  The water intake side screen unit 151 prevents foreign matter in the irrigation liquid introduced into the flow path forming unit 121 from entering the water intake recess 153. The water intake side screen portion 151 is open to the inside of the tube 110 and has a water intake recess 153, a plurality of slits 154, and a plurality of ridges 155.

  The water intake recess 153 is a single recess formed on the entire surface 125 of the flow path component 121 where the film 122 is not joined. The depth of the water intake recess 153 is not particularly limited, and is appropriately set depending on the size of the flow path component 121. A plurality of slits 154 are formed on the outer peripheral wall of the water intake recess 153, and a plurality of ridges 155 are formed on the bottom surface of the water intake recess 153. In addition, a water intake through hole 152 is formed on the bottom surface of the water intake recess 153.

  The plurality of slits 154 connect the inner surface of the water intake recess 153 and the outer surface of the flow path component 121, while taking irrigation liquid into the water recess 153 from the side surface of the flow channel component 121, Foreign matter in the irrigation liquid is prevented to some extent from entering the water intake recess 153. The shape of the slit 154 is not particularly limited as long as the above function can be exhibited. In the present embodiment, the shape of the slit 154 is formed so that the width increases from the outer surface of the flow path component 121 toward the inner surface of the water intake recess 153 (see FIGS. 3 and 4A). . Thus, since the slit 154 is configured to have a so-called wedge wire structure, the pressure loss of the irrigation liquid flowing into the water intake recess 153 is suppressed.

  The plurality of ridges 155 are arranged on the bottom surface of the water intake recess 153. The arrangement and number of the ridges 155 are not particularly limited as long as the water intake unit 150 can take in the irrigation liquid from the opening side of the water intake recess 153 and can prevent foreign substances from entering the irrigation liquid to some extent. In the present embodiment, the plurality of ridges 155 are arranged so that the longitudinal direction of the ridges 155 is along the short direction of the flow path component 121. Further, the ridge 155 is formed so that the width decreases from the surface 125 of the flow path component 121 toward the bottom surface of the water intake recess 153. That is, in the arrangement direction of the ridges 155, the space between the adjacent ridges 155 has a so-called wedge wire structure. Moreover, the space | interval between the adjacent protruding item | lines 155 will not be specifically limited if the above-mentioned function can be exhibited. Thus, since the space between the adjacent ridges 155 is configured to have a so-called wedge wire structure, the pressure loss of the irrigation liquid flowing into the water intake recess 153 is suppressed.

  The water intake through hole 152 is formed on the bottom surface of the water intake recess 153. The shape and number of the water intake through-holes 152 are not particularly limited as long as the irrigation liquid taken into the water intake recess 153 can be taken into the flow path component 121. In the present embodiment, the water intake through hole 152 is a single long hole formed along the longitudinal direction of the flow path component 121 on the bottom surface of the water intake recess 153. Since the long holes are partially covered by the plurality of ridges 155, the water intake through holes 152 appear to be divided into a large number of through holes when viewed from the surface 125 side.

  The irrigation liquid that has flowed through the tube 110 is taken into the flow path component 121 while the intake screen portion 151 prevents foreign matter from entering the intake recess 153 to some extent.

  The first connection groove 131 (first connection flow path 141) connects the water intake through hole 152 (water intake part 150) and the first pressure reduction groove 132. The first connection groove 131 is formed linearly along the longitudinal direction of the flow path component 121 at the outer edge of the back surface 124. The opening on the back surface 124 side of the first connection groove 131 is covered with the bottom wall surface portion 190, whereby the first connection channel 141 is formed. The irrigation liquid taken in from the water intake unit 150 flows through the first connection channel 141 to the first decompression channel 142.

  The first pressure reducing groove 132 (first pressure reducing flow path 142) is disposed in the first flow path and the second flow path upstream of the flow rate reducing unit 160, and the first connection groove 131 (first connection flow path 141). ) And the second connection groove 133 (second connection flow path 143). The first decompression groove 132 (first decompression channel 142) reduces the pressure of the irrigation liquid introduced from the water intake 150 and guides it to the second connection groove 133 (second connection channel 143). The first decompression groove 132 is linearly arranged along the longitudinal direction of the flow path component 121 at the outer edge of the back surface 124. The upstream end of the first decompression groove 132 is connected to the first connection groove 131, and the downstream end of the first decompression groove 132 is connected to the upstream end of the second connection groove 133. The planar view shape of the first decompression groove 132 is a zigzag shape. The opening on the back surface 124 side of the first decompression groove 132 is covered with the bottom wall surface portion 190, whereby the first decompression channel 142 is formed. The irrigation liquid taken in from the water intake unit 150 is decompressed by the first decompression channel 142 and guided to the second connection groove 133 (second connection channel 143).

  The second connection groove 133 (second connection flow path 143) includes a first pressure reduction groove 132 (first pressure reduction flow path 142), a second pressure reduction groove 134 (second pressure reduction flow path 144), and a third pressure reduction groove 135 ( A third decompression channel 145) is connected. The second connection groove 133 is linearly formed along the short direction of the flow path component 121 at the outer edge of the back surface 124. The opening on the back surface 124 side of the second connection groove 133 is covered with the bottom wall surface portion 190, whereby the second connection channel 143 is formed. The irrigation liquid that has been taken in from the water intake unit 150, led to the first connection channel 141, and decompressed in the first decompression channel 142 passes through the second connection channel 143 and passes through the second decompression channel 144 and the second decompression channel 144. 3 Guided to the reduced pressure channel 145.

  The second decompression groove 134 (second decompression flow path 144) is disposed in the first flow path upstream of the flow rate reduction unit 160, and the second connection groove 133 (second connection flow path 143) and the flow rate reduction. The unit 160 is connected. The second decompression groove 134 (second decompression flow path 144) reduces the pressure of the irrigation liquid that has flowed in from the second connection groove 133 (second connection flow path 143) and guides it to the flow rate reduction unit 160. The second decompression groove 134 is disposed along the longitudinal direction of the flow path component 121 at the outer edge of the back surface 124. The upstream end of the second decompression groove 134 is connected to the downstream end of the second connection groove 133, and the downstream end of the second decompression groove 134 is connected to the first connection through-hole 165 communicating with the flow rate reducing portion 160. Yes. The shape of the second decompression groove 134 is not particularly limited as long as the above-described function can be exhibited. In the present embodiment, the plan view shape of the second decompression groove 134 is a zigzag shape similar to the shape of the first decompression groove 132. The opening on the back surface 124 side of the second decompression groove 134 is covered with the bottom wall surface portion 190, whereby the second decompression flow path 144 is formed. In the present embodiment, the second decompression groove 134 (second decompression channel 144) is longer than a third decompression groove 135 (third decompression channel 145) described later. Therefore, the irrigation liquid flowing through the second decompression groove 134 (second decompression flow path 144) is decompressed more than the irrigation liquid flowing through the third decompression groove 135 (third decompression flow path 145). A part of the irrigation liquid taken in from the water intake unit 150 and decompressed in the first decompression channel 142 is decompressed by the second decompression channel 144 and guided to the flow rate reduction unit 160.

  The third decompression groove 135 (third decompression flow path 145) is disposed in the second flow path upstream of the flow rate reduction unit 160, and the second connection groove 133 (second connection flow path 143) and the flow path The opening / closing part 170 is connected. The third decompression groove 135 (third decompression flow path 145) reduces the pressure of the irrigation liquid flowing in from the second connection groove 133 (second connection flow path 143) and guides it to the flow path opening / closing part 170. The third decompression groove 135 is disposed along the longitudinal direction of the flow path component 121 at the central portion of the back surface 124. The upstream end of the third decompression groove 135 is connected to the downstream end of the second connection channel 143, and the downstream end of the third decompression groove 135 is connected to the third connection through-hole 174 communicating with the channel opening / closing part 170. Has been. The shape of the third decompression groove 135 is not particularly limited as long as the above function can be exhibited. In the present embodiment, the plan view shape of the third decompression groove 135 is a zigzag shape similar to the shape of the first decompression groove 132. The opening on the back surface 124 side of the third decompression groove 135 is covered with the bottom wall surface portion 190, whereby the third decompression channel 145 is formed. The other part of the irrigation liquid taken in from the water intake unit 150 and decompressed in the first decompression channel 142 is decompressed by the third decompression channel 145 and guided to the channel opening / closing unit 170. Although the details will be described later, the second flow path functions only when the pressure of the irrigation liquid is low.

  The flow rate reduction unit 160 is disposed between the second decompression channel 144 (second decompression groove 134) and the discharge unit 180 in the first channel, and is disposed on the surface 125 side of the channel configuration unit 121. Has been. The flow rate reduction unit 160 sends the irrigation liquid to the discharge unit 180 while reducing the flow rate of the irrigation liquid according to the pressure of the irrigation liquid in the tube 110. The configuration of the flow rate reducing unit 160 is not particularly limited as long as the above-described function can be exhibited. In the present embodiment, the flow rate reducing portion 160 includes a flow rate reducing recess 161, a first valve seat portion 162, a communication groove 163, a flow rate reduction through hole 164 communicating with the discharge portion 180, and a second pressure reducing groove. 134 (second decompression flow path 144), the first connection through hole 165, the second connection through hole 166 communicated with the flow path opening / closing through hole 173 of the flow path opening / closing section 170, and one of the films 122. A first diaphragm portion 167 which is a portion. On the inner surface of the flow rate reducing recess 161, a flow rate reducing through hole 164 communicating with the discharge unit 180, a first connection through hole 165 communicating with the second decompression groove 134 (second decompression channel 144), A second connection through hole 166 communicating with the flow path opening / closing through hole 173 of the path opening / closing portion 170 is opened.

  As shown in FIG. 3, the planar view shape of the flow rate reducing recess 161 is substantially circular. On the bottom surface of the flow rate reducing recess 161, a flow rate reducing through hole 164 communicating with the discharge unit 180, a first connection through hole 165 communicating with the second pressure reducing groove 134 (second pressure reducing channel 144), A second connection through hole 166 communicating with the path opening / closing portion 170 and a first valve seat portion 162 are disposed. The depth of the flow rate reducing recess 161 is not particularly limited as long as it is equal to or greater than the depth of the communication groove 163.

  As shown in FIG. 5, the flow rate reducing through hole 164 is disposed at the center of the bottom surface of the flow rate reducing recess 161 and communicates with the discharge unit 180. The first valve seat portion 162 is disposed on the bottom surface of the flow rate reducing recess 161 so as to surround the flow rate reducing through hole 164. The first valve seat 162 is formed so that the first diaphragm 167 can be in close contact when the pressure of the irrigation liquid flowing through the tube 110 is equal to or higher than the second pressure. When the first diaphragm portion 167 comes into contact with the first valve seat portion 162, the flow rate of the irrigation liquid flowing from the flow rate reducing recess portion 161 into the discharge portion 180 is decreased. The shape of the 1st valve seat part 162 will not be specifically limited if the above-mentioned function can be exhibited. In the present embodiment, the shape of the first valve seat portion 162 is an annular convex portion. In the present embodiment, the end surface of the annular convex portion has a height from the bottom surface of the flow rate reducing concave portion 161 that decreases from the inside toward the outside. A communication groove 163 that communicates the inside of the flow rate reducing recess 161 and the flow rate reducing through hole 164 is formed in a part of the region where the first diaphragm portion 167 of the first valve seat 162 can be in close contact. The first connection through hole 165 communicated with the second decompression groove 134 (second decompression flow path 144) and the second connection through hole 166 communicated with the flow path opening / closing through hole 173 of the flow path opening / closing part 170 are: The bottom surface of the flow rate reducing recess 161 is formed in a region where the first valve seat 162 is not disposed. The first connection through-hole 165 communicating with the second decompression groove 134 (second decompression flow path 144) is disposed so as to be surrounded by the first valve seat 162, and is used for reducing the flow rate communicating with the discharge unit 180. The through hole 164 may be disposed outside the first valve seat portion 162.

  The first diaphragm portion 167 is a part of the film 122. The first diaphragm portion 167 is disposed so as to block communication between the inside of the flow rate reducing recess 161 and the inside of the tube 110. The first diaphragm portion 167 has flexibility and is deformed so as to contact the first valve seat portion 162 according to the pressure of the irrigation liquid in the tube 110. Specifically, the first diaphragm portion 167 deforms toward the first valve seat portion 162 as the pressure of the irrigation liquid increases, and eventually comes into contact with the first valve seat portion 162. Even when the first diaphragm portion 167 is in close contact with the first valve seat portion 162, the first diaphragm portion 167 blocks the first connection through hole 165, the flow rate reduction through hole 164, and the communication groove 163. Therefore, the irrigation liquid sent from the first connection through hole 165 can be sent to the discharge unit 180 through the communication groove 163 and the flow rate reduction through hole 164. Note that the first diaphragm portion 167 is disposed adjacent to a second diaphragm portion 175 described later.

  The channel opening / closing part 170 is disposed between the third decompression channel 145 (third decompression groove 135) and the discharge unit 180 in the second channel, and on the surface 125 side of the channel constituting unit 121. Has been placed. The channel opening / closing unit 170 opens the second channel according to the pressure in the tube 110 and sends the irrigation liquid to the discharge unit 180. In the present embodiment, the channel opening / closing part 170 is connected to the flow rate reducing unit 160 via the channel opening / closing through hole 173 and the second connection through hole 166, and the third decompression channel 145 (third The irrigation liquid from the decompression groove 135) reaches the discharge part 180 through the flow path opening / closing part 170 and the flow rate reducing part 160. The configuration of the flow path opening / closing portion 170 is not particularly limited as long as the above-described function can be exhibited. In the present embodiment, the channel opening / closing part 170 is a channel opening / closing through hole that communicates with the channel opening / closing recess 171, the second valve seat 172, and the second connection through hole 166 of the flow rate reducing unit 160. 173, a third connection through hole 174 communicating with the third decompression flow path 145 (third decompression groove 135), and a second diaphragm portion 175 that is a part of the film 122. On the inner surface of the channel opening / closing recess 171, a third connection through hole 174 communicating with the third decompression channel 145 (third decompression groove 135) and a channel opening / closing through hole 173 communicating with the flow rate reducing unit 160 are provided. And are open. The channel opening / closing recess 171 communicates with the flow rate reducing recess 161 of the flow rate reducing unit 160.

  As shown in FIG. 3, the planar view shape of the channel opening / closing recess 171 is substantially circular. On the bottom surface of the channel opening / closing recess 171, a third connection through hole 174 connected to the third pressure reducing groove 135, a channel opening / closing through hole 173 connected to the flow rate reducing unit 160, and a second valve seat The part 172 is arranged. The end surface of the second valve seat portion 172 is disposed closer to the surface 125 than the end surface of the first valve seat portion 162. That is, the second valve seat portion 172 is formed higher than the first valve seat portion 162. Accordingly, when the film 122 is deformed by the pressure of the irrigation liquid, the film 122 contacts the second valve seat portion 172 before the first valve seat portion 162.

  The third connection through-hole 174 communicating with the third decompression groove 135 is formed in a region where the second valve seat 172 is not disposed on the bottom surface of the flow path opening / closing recess 171. The second valve seat 172 is disposed on the bottom surface of the channel opening / closing recess 171 so as to surround the channel opening / closing through hole 173. Further, the second valve seat portion 172 is disposed in a non-contact manner facing the second diaphragm portion 175, and when the pressure of the irrigation liquid flowing through the tube 110 is equal to or higher than the first pressure, the second diaphragm portion 175 can be in close contact. It is formed as follows. When the pressure of the irrigation liquid flowing through the tube 110 is equal to or higher than the first pressure, the second diaphragm portion 175 is in close contact with the second valve seat portion 172 and closes the flow passage opening / closing through-hole 173, resulting in the second Block the flow path. The shape of the 2nd valve seat part 172 will not be specifically limited if the above-mentioned function can be exhibited. In the present embodiment, the second valve seat portion 172 is an annular convex portion arranged so as to surround the flow passage opening / closing through hole 173.

  The second diaphragm portion 175 is a part of the film 122 and is disposed adjacent to the first diaphragm portion 167. The second diaphragm portion 175 is disposed so as to block communication between the inside of the channel opening / closing recess 171 and the inside of the tube 110. The second diaphragm portion 175 has flexibility and deforms so as to contact the second valve seat portion 172 in accordance with the pressure of the irrigation liquid in the tube 110. Specifically, the second diaphragm portion 175 is deformed toward the second valve seat portion 172 as the pressure of the irrigation liquid increases, and when the pressure of the irrigation liquid reaches the first pressure, Contact the seat 172. As a result, the second flow path (flow path opening / closing through hole 173) is closed.

  The discharge unit 180 is disposed on the back surface 124 side of the flow path forming unit 121 so as to face a holding member 210 described later. The discharge unit 180 sends the irrigation liquid from the flow rate reducing through hole 164 to the tube discharge port 112 of the tube 110 through the holding member 210. Accordingly, the discharge unit 180 can discharge the irrigation liquid to the outside of the emitter 120. The structure of the discharge part 180 will not be specifically limited if the above-mentioned function can be exhibited. In the present embodiment, the discharge unit 180 includes a discharge recess 181 and an intrusion prevention unit 182.

  The discharge recess 181 is disposed on the back surface 124 side of the flow path component 121. The shape of the discharge recess 181 in plan view is substantially rectangular. On the bottom surface of the discharge recess 181, a flow rate reduction through hole 164 and an intrusion prevention unit 182 are disposed. The opening on the back surface 124 side of the discharge recess 181 is covered with a bottom wall surface portion 190, and an emitter discharge port 192 is provided in the bottom wall surface portion 190.

  The intrusion prevention unit 182 prevents foreign matter from entering from the outside of the tube 110 through the tube discharge port 112. The intrusion prevention unit 182 is not particularly limited as long as it can perform the above-described function. In the present embodiment, intrusion prevention unit 182 has two protruding strips 184 arranged adjacent to each other. The two ridges 184 are arranged so as to be positioned between the flow rate reducing through hole 164 and the emitter discharge port 192.

  The film 122 has a first diaphragm portion 167 and a second diaphragm portion 175 (see FIG. 3). The thickness of the film 122 is, for example, 0.3 mm.

  The hinge part 123 is connected to a part of the surface 125 of the flow path constituting part 121. In the present embodiment, the thickness of the hinge portion 123 is the same as that of the film 122 and is integrally formed with the flow path constituting portion 121 and the film 122. The film 122 may be prepared as a separate body from the flow path component 121 and bonded to the flow path component 121.

  The emitter body 200 is configured by rotating the film 122 around the hinge portion 123 and joining it to the surface 125 of the flow path constituting portion 121. The joining method of the flow path component 121 and the film 122 is not particularly limited. Examples of the method of joining the flow path constituting portion 121 and the film 122 include welding of a resin material constituting the film 122, adhesion with an adhesive, and the like. In addition, the hinge part 123 may be cut | disconnected after the flow-path structure part 121 and the film 122 are joined.

  The bottom wall surface portion 190 has an emitter discharge port 192 (see FIGS. 3 and 4B). The thickness of the bottom wall surface portion 190 is, for example, 0.7 mm.

  The hinge portion 191 is connected to a part of the back surface 124 of the emitter body 200. In the present embodiment, the thickness of hinge portion 191 is the same as that of bottom wall surface portion 190 and is integrally formed with back surface 124 and bottom wall surface portion 190. The bottom wall surface portion 190 may be prepared as a separate body (for example, a film) from the emitter body 200 and bonded to the back surface 124.

  The emitter main body 200 is configured by rotating the bottom wall surface portion 190 around the hinge portion 191 and joining the back surface 124 of the emitter main body 200. The joining method of the back surface 124 and the bottom wall surface portion 190 is not particularly limited. Examples of the method of joining the back surface 124 and the bottom wall surface portion 190 include welding of a resin material constituting the bottom wall surface portion 190, adhesion with an adhesive, and the like. The hinge portion 191 may be cut after the back surface 124 and the bottom wall surface portion 190 are joined.

  The holding member 210 is joined to a position corresponding to the tube discharge port 112 on the inner wall surface of the tube 110, and holds the emitter body 200 so as to vibrate. The holding member 210 preferably has the following three characteristics in order to hold the emitter body 200 so as to vibrate.

  First, as a first feature, as shown in FIG. 2, the holding member 210 has a cross section along the longitudinal direction of the emitter body 200 with respect to the lower surface 212 of the holding member 210, that is, the surface joined to the tube 110. It is preferable to hold the emitter body 200 so that the emitter body 200 is inclined. As shown in FIG. 2, the holding member 210 has an upper surface 211 and a lower surface 212. The upper surface 211 is the upper surface of the holding member 210 in FIG. 2, that is, the surface bonded to the emitter body 200, and the lower surface 212 is bonded to the lower surface of the holding member 210 in FIG. Surface. Thereby, at least one of the front surface 125 and the back surface 124 of the emitter body 200 is inclined with respect to the flow of the irrigation liquid in the tube 110. For this reason, at least one of the front surface 125 and the rear surface 124 of the emitter body 200 hits the irrigation liquid flowing in the tube 110, and a pressure is thereby applied. The angle at which the emitter body 200 is inclined with respect to the axial direction of the tube 110 is not particularly limited. Further, as described above, the direction of the irrigation liquid flowing in the tube 110 is not particularly limited.

  Next, as a second feature, as illustrated in FIG. 2, the holding member 210 preferably holds the emitter body 200 so that the emitter body 200 does not contact the inner wall surface of the tube 110. As a result, it is possible to prevent the emitter main body 200 from coming into contact with the inner wall surface of the tube 110 so that the emitter main body 200 does not easily vibrate even when pressure is applied to the emitter main body 200 due to the flow of the irrigation liquid.

  As a third feature, the holding member 210 is preferably formed of a flexible material. The holding member 210 may be integrally formed of the same material as that of the emitter body 200 (the flow path component 121 and the film 122), or may be formed of a different material.

  When the holding member 210 and the emitter main body 200 are integrally formed, the upper surface 211 of the holding member 210 becomes the bottom wall surface portion 190 of the discharge unit 180, and the bottom wall surface portion 190 other than the discharge unit 180 is separated (for example, , Film, etc.).

  When the holding member 210 and the emitter main body 200 are formed separately, the joining method of the emitter main body 200 and the holding member 210 is not particularly limited. Further, the method for joining the holding member 210 and the tube 110 is not particularly limited. Examples of a method for joining the emitter body 200 and the holding member 210 and a method for joining the holding member 210 and the tube 110 include welding of a resin material constituting the holding member 210 and adhesion using an adhesive.

  The holding member 210 has a communication hole 213. The communication hole 213 has openings on the upper surface 211 and the lower surface 212 of the holding member 210 and is provided so as to penetrate the holding member 210. When the holding member 210 is joined to the emitter body 200 on the upper surface 211 and to the tube 110 on the lower surface 212, one of the communication holes 213 (the upper surface 211 side) is connected to the emitter discharge port 192, and the other (the lower surface 212 side). Is connected to the tube outlet 112. Accordingly, the discharge unit 180 and the tube discharge port 112 communicate with each other, and the irrigation liquid discharged from the emitter discharge port 192 is discharged from the tube discharge port 112 to the outside of the tube 110 through the communication hole 213.

  When the holding member 210 is integrally formed of the same material as that of the emitter body 200, the communication hole 213 may be provided simultaneously with the formation of the holding member 210, and the flow path component 121 is formed by the holding member 210 with the tube 110. It may be provided after being fixed to. That is, the communication hole 213 may be provided so that the discharge unit 180 and the tube discharge port 112 are communicated after the holding member 210 formed without providing the communication hole 213 is joined to the tube 110.

  Further, the holding member 210 is provided in advance at a position corresponding to the tube discharge port 112 when the tube 110 is manufactured, and the emitter main body 200 formed separately is bonded to the holding member 210 to hold the emitter main body 200. You may do it.

  When the cross-sectional shape perpendicular to the axial direction of the tube 110 is circular, the lower surface 212 side of the holding member 210 is convex toward the inner wall surface of the tube 110 along the inner wall surface of the tube 110. It is preferably formed in a substantially arc shape.

(Operation of drip irrigation tube and emitter)
Next, the operation of the drip irrigation tube 100 according to the present embodiment will be described. First, irrigation liquid is fed into the tube 110. Examples of irrigation liquids include water, liquid fertilizers, pesticides and mixtures thereof. The pressure of the irrigation liquid fed to the drip irrigation tube 100 is preferably 0.1 MPa or less so that the drip irrigation method can be easily introduced and the tube 110 and the emitter 120 are prevented from being damaged. . The irrigation liquid in the tube 110 is taken into the emitter body 200 from the water intake unit 150. Specifically, the irrigation liquid in the tube 110 enters the water intake recess 153 through the slit 154 or the gap between the protrusions 155 and passes through the water intake through hole 152. At this time, since the water intake part 150 has the water intake side screen part 151 (gap between the slit 154 and the protrusion 155), it is possible to prevent foreign substances from entering the irrigation liquid to some extent. Moreover, since the so-called wedge wire structure is formed in the water intake part 150, the pressure loss of the irrigation liquid flowing into the water intake part 150 is suppressed.

  The irrigation liquid taken from the water intake unit 150 reaches the first connection channel 141. The irrigation liquid that has reached the first connection channel 141 reaches the second connection channel 143 while being decompressed by the first decompression channel 142. The irrigation liquid that has reached the second connection channel 143 flows into the second decompression channel 144 and the third decompression channel 145 and is decompressed. At this time, the irrigation liquid advances in advance through the third decompression channel 145 having a shorter channel length and less pressure loss than the second decompression channel 144. The irrigation liquid that has flowed into the third decompression flow path 145 flows into the flow path opening / closing part 170 through the third connection through hole 174.

  The irrigation liquid that has flowed into the channel opening / closing unit 170 flows into the flow rate reducing unit 160 through the channel opening / closing through hole 173 and the second connection through hole 166. Next, the irrigation liquid that has flowed into the flow rate reduction unit 160 flows into the discharge unit 180 through the flow rate reduction through hole 164. Finally, the irrigation liquid that has flowed into the discharge unit 180 is discharged out of the tube 110 through the emitter discharge port 192, the communication hole 213 of the holding member 210, and the tube discharge port 112 of the tube 110.

  On the other hand, the irrigation liquid that has flowed into the second decompression flow path 144 flows into the flow rate reduction unit 160 through the first connection through hole 165. The irrigation liquid that has flowed into the flow rate reduction unit 160 flows into the discharge unit 180 through the flow rate reduction through hole 164. The irrigation liquid that has flowed into the discharge unit 180 is discharged outside the tube 110 through the emitter discharge port 192, the communication hole 213 of the holding member 210, and the tube discharge port 112 of the tube 110.

  As described above, the flow channel opening / closing part 170 and the flow rate reducing unit 160 communicate with each other via the flow path opening / closing through hole 173 and the second connection through hole 166. The flow rate reducing unit 160 controls the flow rate of the irrigation liquid by deforming the first diaphragm unit 167 according to the pressure of the irrigation liquid in the tube 110, and the flow path opening / closing unit 170 controls the flow rate in the tube 110. The flow rate of the irrigation liquid is controlled by deforming the second diaphragm portion 175 according to the pressure of the irrigation liquid. Therefore, the operation of the flow rate reducing unit 160 and the flow path opening / closing unit 170 according to the pressure of the irrigation liquid in the tube 110 will be described.

  FIGS. 6A to 6C are schematic diagrams illustrating the operational relationship between the flow rate reducing unit 160 and the flow path opening / closing unit 170. FIG. 6A to 6C are schematic sectional views taken along line BB shown in FIG. 4A. 6A is a cross-sectional view when the irrigation liquid is not supplied to the tube 110, and FIG. 6B is a cross-sectional view when the pressure of the irrigation liquid in the tube 110 is the first pressure. FIG. 6C is a cross-sectional view when the pressure of the irrigation liquid in the tube 110 is the second pressure exceeding the first pressure.

  Before the irrigation liquid is fed into the tube 110, the pressure of the irrigation liquid is not applied to the film 122, so the first diaphragm portion 167 and the second diaphragm portion 175 are not deformed (see FIG. 6A). .

  When the irrigation liquid starts to be fed into the tube 110, the first diaphragm portion 167 of the flow rate reducing portion 160 starts to deform toward the first valve seat portion 162. Further, the second diaphragm part 175 of the flow path opening / closing part 170 starts to deform toward the second valve seat part 172. However, in this state, the first diaphragm portion 167 is not in close contact with the first valve seat portion 162, and the second diaphragm portion 175 is not in close contact with the second valve seat portion 172. The irrigation liquid thus obtained includes a first flow path (a first connection flow path 141, a first pressure reduction flow path 142, a second connection flow path 143, a second pressure reduction flow path 144, a flow rate reduction unit 160, and a discharge unit 180) and Both of the second flow paths (the first connection flow path 141, the first pressure reduction flow path 142, the second connection flow path 143, the third pressure reduction flow path 145, the flow path opening / closing section 170, the flow rate reduction section 160, and the discharge section 180) It passes through and is discharged to the outside of the flow path component 121. As described above, when the irrigation liquid is started to be fed into the tube 110 or when the pressure of the irrigation liquid in the tube 110 is lower than a predetermined pressure, the irrigation liquid taken from the water intake unit 150 is It discharges through both the 1st channel and the 2nd channel.

  Next, when the pressure of the irrigation liquid in the tube 110 becomes higher, the first diaphragm portion 167 and the second diaphragm portion 175 are further deformed. And the 2nd diaphragm part 175 contacts the 2nd valve seat part 172, and obstruct | occludes a 2nd flow path (refer FIG. 6B). At this time, since the end surface of the second valve seat portion 172 is disposed closer to the surface 125 than the end surface of the first valve seat portion 162, the second diaphragm portion 175 has the first diaphragm portion 167 as the first valve seat portion. The second valve seat 172 is brought into contact with the second valve seat 172 before it comes into contact with the 162. At this time, the first diaphragm portion 167 is not in contact with the first valve seat portion 162. Thus, when the pressure of the irrigation liquid in the tube 110 becomes so high that the film 122 is deformed, the second diaphragm portion 175 is close to the second valve seat portion 172, and thus is discharged through the second flow path. The amount of irrigation liquid is reduced. When the pressure of the irrigation liquid in the tube 110 reaches the first pressure, the irrigation liquid in the second flow path is not discharged to the outside of the flow path constituting unit 121. As a result, the irrigation liquid introduced from the water intake unit 150 passes through only the first channel and is discharged to the outside of the channel configuration unit 121.

  When the pressure of the irrigation liquid in the tube 110 is further increased, the first diaphragm portion 167 is further deformed toward the first valve seat portion 162. Normally, as the pressure of the irrigation liquid increases, the amount of the irrigation liquid flowing through the first flow path should increase. However, in the emitter 120 according to the present embodiment, the first decompression flow path 142 and the first flow path are increased. (2) The pressure of the irrigation liquid is reduced in the decompression flow path 144, and the distance between the first diaphragm portion 167 and the first valve seat portion 162 is reduced, so that the amount of the irrigation liquid flowing in the first flow path is excessive. The increase is prevented. Then, when the pressure of the irrigation liquid in the tube 110 is equal to or higher than the second pressure exceeding the first pressure, the first diaphragm portion 167 contacts the first valve seat portion 162 (see FIG. 6C). Even in this case, since the first diaphragm portion 167 does not block the first connection through hole 165, the flow rate reduction through hole 164, and the communication groove 163, the irrigation liquid introduced from the water intake portion 150 is in communication. The liquid is discharged to the outside of the flow path component 121 through the groove 163. As described above, when the pressure of the irrigation liquid in the tube 110 is equal to or higher than the second pressure, the flow rate reducing unit 160 makes the first flow path when the first diaphragm portion 167 contacts the first valve seat portion 162. The increase in the amount of irrigation liquid flowing through

  As described above, the flow rate reducing unit 160 and the flow path opening / closing unit 170 function so that the amounts of liquid flowing through each of them are complemented in accordance with the pressure of the irrigation liquid in the tube 110. The drip irrigation tube according to the above can discharge a certain amount of irrigation liquid out of the tube 110 regardless of whether the pressure of the irrigation liquid is low or high.

  Further, when the irrigation liquid starts to be fed into the tube 110, the emitter main body 200 supports the holding member 210 by applying pressure of the irrigation liquid to at least one of the front surface 125 and the back surface 124 of the emitter main body 200. Vibrates as. The direction in which the emitter body 200 vibrates is not particularly limited. In the present embodiment, the emitter body 200 vibrates in the vertical direction in FIG.

  As described above, the emitter body 200 vibrates with the holding member 210 as a fulcrum, and the following effects are obtained. When foreign matter such as sand particles or sediment is present in the irrigation liquid, the foreign matter is unlikely to enter the emitter 200 due to vibration of the emitter 200. Further, even when foreign matter in the irrigation liquid enters the emitter body 200 beyond the intake screen portion 151, the entered foreign matter does not stay in the emitter body 200 due to vibration of the emitter body 200. Is suitably discharged to the outside (outside of the tube 110, etc.). Since the vibration of the emitter body 200 continues throughout the flow of the irrigation liquid, a situation (clogging) in which foreign matter accumulates in the flow path of the emitter body 200 can be suitably suppressed and eliminated.

  Although it has been described that the holding member 210 preferably has three characteristics for holding the emitter body 200 so as to be capable of vibrating, the present invention is not limited to this. That is, the holding member 210 does not necessarily have all the three features described above.

(effect)
As described above, the emitter 120 according to the present embodiment includes the emitter body 200 and the holding member 210 that holds the emitter body 200 so as to be able to vibrate. Here, the holding member 210 holds the emitter body 200 so that the emitter body 200 is inclined with respect to the lower surface 212 of the holding member 210, that is, the surface joined to the tube 110, in a cross section along the longitudinal direction of the emitter body 200. To do. Thereby, since the pressure of the irrigation liquid is suitably applied to at least one of the front surface 125 and the back surface 124 of the emitter main body 200, the emitter main body 200 preferably vibrates.

  The holding member 210 holds the emitter body 200 so that the emitter body 200 does not contact the inner wall surface of the tube 110. As a result, it is possible to prevent the emitter main body 200 from coming into contact with the inner wall surface of the tube 110 so that the emitter main body 200 does not easily vibrate even when pressure is applied to the emitter main body 200 due to the flow of the irrigation liquid.

  The holding member 210 is formed of a flexible material. Thereby, the emitter body 200 preferably vibrates with the holding member 210 as a fulcrum.

  As described above, in the emitter 120 according to the present embodiment, when the irrigation liquid is fed, the emitter body 200 vibrates with the holding member 210 as a fulcrum, so that the foreign matter in the irrigation liquid enters the emitter body 200. Hard to get in. Further, even if a foreign substance enters the emitter body 200, the foreign substance is discharged outside the emitter body 200 by this vibration. For this reason, the situation (clogging) that a foreign material accumulates in the flow path of the emitter main body 200 can be suitably suppressed and eliminated.

(Modification 1)
The holding member 210 described in the first embodiment is an example, and the emitter according to the present invention is not limited to this mode. For example, as shown in FIG. 7, the emitter body 200 may be held by a holding member 210A having a simpler configuration. (Modification 1).

  FIG. 7 is a view for explaining a holding member 210A according to the first modification of the present invention. Similarly to the first embodiment, the holding member 210A is configured such that the emitter body 200 is inclined with respect to the surface (lower surface) joined to the tube 110 of the holding member 210A in the cross section along the longitudinal direction of the emitter body 200. The emitter body 200 is held so that the emitter body 200 does not contact the inner wall surface of the tube 110.

  In the first modification, the holding member 210A is formed in a cylindrical shape (tubular) and has a communication hole 213A inside the cylinder. One end of the communication hole 213A is connected to the discharge part 180 of the emitter main body 200 (flow path component 121), and the other end is connected to the tube discharge port 112 of the tube 110, so that the emitter discharge port 192 and the tube discharge port 112 are connected. And communicate. Thus, the irrigation liquid discharged from the emitter discharge port 192 is discharged from the tube discharge port 112 to the outside of the tube 110 through the communication hole 213A.

  The holding member 210A is formed of a flexible material as in the above embodiment. As long as the holding member 210A is formed of a flexible material, the holding member 210A may be integrally formed of the same material as that of the emitter body 200 (the flow path component 121 and the film 122), or may be formed of a different material. It may be formed on the body. The method of joining the emitter body 200 and the holding member 210A when the holding member 210A and the emitter body 200 are formed separately is not particularly limited. Also, the method for joining the holding member 210A and the tube 110 is not particularly limited. Examples of a method for joining the holding member 210A and the emitter body 200 and a method for joining the holding member 210A and the tube 110 include welding of a resin material constituting the holding member 210A, adhesion by an adhesive, and the like.

  When the holding member 210A is integrally formed of the same material as that of the emitter body 200, the communication hole 213A may be formed simultaneously with the formation of the holding member 210A, or first, it is formed in a columnar shape, and both ends of the column are the emitters. After joining the main body 200 and the tube 110, the holding member 210A may be configured by opening the communication hole 213A. That is, after a cylindrical member provided at a position corresponding to the emitter discharge port 192 of the flow path component 121 is joined to the tube 110, the cylindrical discharge port 192 and the tube discharge port 112 are connected to each other. The cylindrical holding member 210A may be formed by opening the communication hole 213A along the central axis.

  Alternatively, the holding member 210A may be provided in advance at a position corresponding to the tube discharge port 112 when the tube 110 is manufactured, and the emitter body 200 manufactured separately may be joined to the holding member 210A.

  In Modification 1, as shown in FIG. 7, the holding member 210 </ b> A is formed in a cylindrical shape, so that the holding member 210 </ b> A holds the emitter body 200 compared to the holding member 210 </ b> A of the above embodiment. The bonding area is smaller than that of the first embodiment. For this reason, in the first modification, the emitter body 200 is more likely to vibrate compared to the first embodiment, and the entry of foreign matter into the emitter body 200 is preferably prevented, and the entered foreign matter is efficiently prevented. 200 can be discharged to the outside.

(Modification 2)
In order to further enhance the vibration of the emitter body 200 due to the pressure of the irrigation liquid, the emitter according to the present invention may adopt a mode in which a wing portion 220 is provided on the emitter body 200 as shown in FIG. Modification 2). In the second modification, the configuration other than the wing portion 220 is the same as that in the first modification.

  The wing part 220 is a member for receiving the flow of the irrigation liquid and receiving pressure, and is provided, for example, so as to protrude from the bottom wall surface part 190 of the emitter body 200 in a direction different from the longitudinal direction of the emitter body 200. The direction in which the wing portion 220 protrudes is not particularly limited. In FIG. 8, the wing portion 220 is provided so as to protrude from the back surface 124 side of the emitter main body 200 (flow path constituting portion 121), but the present invention is not limited to this. Furthermore, the length (distance protruding from the emitter body 200) and the width (width of the wing section 220 parallel to the short direction of the emitter body 200) of the wing section 220 are not particularly limited. The length of the wing portion 220 is preferably such that the tip of the wing portion 220 does not contact the inner wall surface of the tube 110 even when the emitter body 200 vibrates. In addition, the width of the wing portion 220 is preferably equal to or smaller than the width of the emitter body 200 in the short direction so that the irrigation liquid can be sufficiently received and the pressure can be sufficiently received.

  In FIG. 8, the operation of the emitter body 200 when the irrigation liquid flows from the right side to the left side of the drawing will be described. In the following description, a surface near the upstream side of the irrigation liquid in the wing portion 220 is referred to as a first surface 221, and a surface close to the downstream side is referred to as a second surface 222.

  In FIG. 8, when the irrigation liquid flows from the right side, the pressure of the irrigation liquid applied to the emitter body 200 is more applied to the back surface 124 side than the front surface 125 side of the emitter body 200. That is, an upward force in FIG. 8 is applied to the entire emitter body 200 by the irrigation liquid. On the other hand, the pressure of the irrigation liquid applied to the wing portion 220 is applied more on the first surface 221 side than on the second surface 222 side. That is, the downward force in FIG. 8 is applied to the whole wing part 220 by the irrigation liquid.

  As described above, in the second modification, the emitter body 200 is subjected to two forces, ie, an upward force and a downward force. Therefore, the emitter body 200 as a whole is based on the holding member 210A as a fulcrum. It becomes easy to vibrate.

  In the above description, the case where the irrigation liquid flows from the right side to the left side in FIG. 8 has been described. However, the same effect can be obtained when the irrigation liquid flows in the opposite direction.

  According to the present invention, it is possible to easily provide an emitter that can suitably prevent foreign matter from entering the emitter body 200 due to vibration and can suitably discharge the foreign matter that has entered. Therefore, the spread of the emitter to technical fields that require long-term dripping, such as drip irrigation and durability tests, and further development of the technical field are expected.

DESCRIPTION OF SYMBOLS 100 Drip irrigation tube 110 Tube 112 Tube discharge port 120 Emitter 121 Flow path structure part 122 Film 123,191 Hinge part 124 Back surface 125 Surface 131 1st connection groove 132 1st decompression groove 133 2nd connection groove 134 2nd decompression groove 135 Third decompression groove 141 First connection channel 142 First decompression channel 143 Second connection channel 144 Second decompression channel 145 Third decompression channel 150 Water intake portion 151 Water intake side screen portion 152 Water intake through-hole 153 Water intake Concave portion 154 Slit 155 Protrusion 160 Flow rate reducing portion 161 Flow rate reducing concave portion 162 First valve seat portion 163 Communication groove 164 Flow rate reducing through hole 165 First connection through hole 166 Second connection through hole 167 First diaphragm portion 170 Flow path opening / closing portion 171 Flow path opening / closing recess 172 Second valve seat portion 17 Through-hole for channel opening / closing 174 Third through-hole for connection 175 Second diaphragm portion 180 Discharge portion 181 Discharge recess portion 182 Intrusion prevention portion 184 Projection portion 190 Bottom wall surface portion 191 Hinge portion 192 Emitter discharge port 200 Emitter body 210, 210A Holding member 211 Upper surface 212 Lower surface 213, 213A Communication hole 220 Wing portion 221 First surface 222 Second surface

Claims (6)

When the inner wall surface of the tube through which the irrigation liquid is circulated is joined to a position corresponding to the discharge port communicating between the inside and the outside of the tube, the irrigation liquid in the tube is quantitatively measured from the discharge port. An emitter for discharging outside,
An emitter body that takes in the irrigation liquid in the tube and quantitatively discharges the irrigation liquid from a discharge unit;
A holding member for communicating the discharge port of the tube and the discharge portion of the emitter, and holding the emitter body so as to vibrate when joined to the inner wall surface of the tube;
Having an emitter.   The holding member holds the emitter body so that the emitter body is inclined with respect to a surface of the holding member joined to an inner wall surface of the tube in a cross section along the longitudinal direction of the emitter body. The emitter according to 1.   The emitter according to claim 1 or 2, wherein the holding member holds the emitter body so that the emitter body does not contact an inner wall surface of the tube.   The emitter according to any one of claims 1 to 3, wherein the holding member is formed of a flexible material.   The emitter according to any one of claims 1 to 4, wherein the emitter body includes a wing portion for receiving the irrigation liquid flowing in the tube. A tube having a discharge port for discharging irrigation liquid;
The emitter according to any one of claims 1 to 5, joined at a position corresponding to the discharge port of the inner wall surface of the tube;
Having a drip irrigation tube.

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