JP5923704B2 - Connection structure between antenna 竪 樋 and 竪 樋 and cover body used therefor - Google Patents

Description

  The present invention relates to a connection structure between an antenna rod and a rod and a cover body used therefor.

  Conventionally, an antenna attached to a bag is known (see, for example, Patent Document 1). The antenna described in Patent Document 1 is retrofitted to a bag. This retrofit antenna is attached so that an antenna portion that receives radio waves protrudes laterally from the side surface of the bag.

Japanese Patent Laid-Open No. 01-168101

  As described above, the antenna described in Patent Document 1 bulges greatly to the side of the bag when attached to the bag. For this reason, the antenna described in the cited document 1 is very conspicuous in appearance in the installed state, and there is a possibility of deteriorating the appearance of the building.

  Therefore, the present inventor has developed an antenna (hereinafter referred to as an antenna rod) having a drainage function and constituting a part of the rod (refer to FIG. 14). For example, the antenna rod 1 is attached to a portion where the portion of the rod 100 fixed along the outer wall of the building is cut out. The antenna 竪 樋 1 is connected to an electrical device via a cable. Thus, the antenna 竪 樋 1 functions not only as a part of the 竪 樋 100 but also as an antenna.

  The antenna rod 1 has an opening 101 at the upper end. The opening 101 is formed larger than the outer diameter of the collar 100. The antenna rod 1 and the rod 100 are fixed to each other with the lower end portion of the rod 100 positioned upstream of the antenna rod 1 being inserted into the opening 101 of the antenna rod 1. Yes.

  In this connected state, a gap 102 is formed between the opening 101 at the upper end of the antenna rod 1 and the outer surface of the rod 100. For this reason, there is a problem that dust, dust, sand and the like enter through the gap 102 as it is.

  The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a connection structure between an antenna fence and a fence so that dust, dust, sand, etc. are less likely to enter the fence, and to this. It is to provide a cover body to be used.

  The connection structure between the antenna rod and the rod according to the present invention includes an antenna rod having a drainage channel formed therein and an antenna, and a connection port provided at an upper end of the antenna rod and communicating with the drainage channel. The lower end portion of the connecting port includes a flange, a gap provided between the opening edge of the connecting port and the flange, and a cover body covering the gap. To do.

  Further, in the connection structure between the antenna rod and the rod, the cover body includes a closing plate larger than the connection port, and a through hole provided in the blocking plate for inserting the rod. Preferably it is.

  Further, in this connection structure between the antenna rod and the rod, the antenna rod has an upper connection body provided at an upper end portion of the antenna rod, and rain water is applied to the upper surface of the upper connection body. A water receiving part is formed, the connection port is provided in a part of the water receiving part, and a plurality of projecting parts protruding upward are spaced apart from an opening peripheral edge of the connection port, and the cover It is preferable that the body is placed on the protrusion.

  The cover body of the present invention is a cover body used for the connection structure between the antenna rod and the rod, and includes a closing plate larger than the connection port of the antenna rod, and the lid provided on the blocking plate. A through-hole for inserting the scissors, wherein the through-hole has a hole formed along the contour of the first-sized scissors, and a second size larger than the first size. It has the cuttable part formed in the outer side rather than the said hole part so that the external shape of a collar may be followed.

  According to the connection structure between the antenna rod and the rod of the present invention, the cover body is provided so as to cover the gap between the opening edge of the connection port of the antenna rod and the rod. Garbage, dust and sand can be prevented from entering.

  Further, according to the cover body of the present invention, since the shape of the through hole can be changed according to the outer shape of the basket, it is possible to make it difficult for dust, dust, sand and the like to enter the basket.

It is a perspective view which shows the connection structure of the antenna bag of this embodiment, and a bag. It is the whole schematic figure of the state where the antenna cage of this embodiment was attached to the cage. It is a perspective view of the antenna cage of this embodiment, and is partially broken. It is a disassembled perspective view of the antenna cage of this embodiment. It is a perspective view of the electric power feeding part of the antenna of this embodiment. It is the perspective view seen from the back of the antenna of this embodiment. It is a disassembled perspective view of the lower connection body of this embodiment. It is a disassembled perspective view of the upper connection body and water collection part of this embodiment. It is the perspective view which abbreviate | omitted the cover part of the upper connection body of this embodiment. It is sectional drawing which shows the upper end part of the antenna rod of this embodiment. It is a perspective view of the cover body of this embodiment, (a) is a figure before cut | disconnecting a cuttable part, (b) is a figure of the state which cut | disconnected the cuttable part. It is sectional drawing of the connection part of the antenna 竪 樋 and 竪 樋 of this embodiment. It is a perspective view of the connection part of the antenna rod of this embodiment, and the rod, and shows the case where the rod is a square rod. (A) and (b) are perspective views of a reference example.

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

  As shown in FIG. 2, the antenna rod 1 of this embodiment is incorporated in a part of the rod 8. The eaves 8 are arranged along the building outer wall 90. A part of the vertical direction of the ridge 8 is removed. Antenna 竪 樋 1 is attached to this removed location in 竪 樋 8.

  Hereinafter, as necessary, in a state where a part of the ridge 8 is removed, a cylindrical ridge located on the upstream side is defined as an “upstream ridge 91”. Further, in a state where a part of the ridge 8 is cut off, a cylindrical ridge located on the downstream side is defined as a “downstream ridge 92”.

  The antenna 竪 樋 1 is an antenna having a ridge shape that constitutes a part of the 竪 樋 8. In other words, the antenna 1 is an antenna having a drainage function. The antenna 竪 樋 1 constitutes an antenna for receiving radio waves. The antenna 竪 樋 1 is connected to, for example, an electric device. The electric device is, for example, a television or a radio. The antenna 竪 樋 1 is connected to an electrical device via a cable. As shown in FIG. 3 and the like, the antenna housing 1 includes a housing 10, an outer cylindrical body 19, an upper connection body 40, and a lower connection body 50.

  The main body of the casing 10 is constituted by a cylindrical body 11. As shown in FIG. 4, the housing 10 includes the cylindrical body 11, a drainage cylinder 12, a water collection unit 15, and the antenna 2. As for the housing 10, the drain cylinder 12 is arrange | positioned inside the cylindrical body 11. As shown in FIG. In other words, the housing 10 is a double cylinder.

  The cylindrical body 11 is configured by a round rod having a circular cross section. The cylindrical body 11 is made of a nonconductive synthetic resin. The cylindrical body 11 has a length in the vertical direction. The cylindrical body 11 is arrange | positioned so that a center axis may become parallel to an up-down direction. A substantially U-shaped upper positioning groove 13 is provided at the upper end of the cylindrical body 11. A lower positioning groove 14 having a substantially inverted U shape is provided at the lower end of the cylindrical body 11.

  The drain cylinder 12 is accommodated inside the cylindrical body 11. The drain cylinder 12 is made of non-conductive synthetic resin. The drain cylinder 12 has a length in the vertical direction. The drain cylinder 12 is disposed so that the central axis is parallel to the vertical direction. In other words, the central axis of the drain cylinder 12 substantially coincides with the central axis of the cylindrical body 11. The outer diameter of the drain cylinder 12 is formed smaller than the inner diameter of the cylindrical body 11. The drain cylinder 12 is formed in a substantially elliptical cross section. The drain tube 12 connects the upstream side hook 91 and the downstream side hook 92 in communication. In other words, the drain tube 12 is located between the upstream side hook 91 and the downstream side hook 92.

  In addition, the central axis of the drain cylinder 12 having a substantially elliptical cross section is defined as a straight line in a direction perpendicular to the cross section passing through the intersection of the short axis and the long axis in the cross section. Further, the drain tube 12 may be circular in cross section.

  A drainage channel 18 is formed in the drain tube 12. The drainage channel 18 communicates with the upstream side hook 91 and the downstream side hook 92. The drainage channel 18 has a length in the vertical direction. The longitudinal direction of the drainage channel 18 is substantially parallel to the longitudinal direction of the trough 8.

  The drain cylinder 12 is disposed from the inner surface of the cylindrical body 11 via a gap of a certain amount or more in the radial direction. In other words, the drainage channel 18 is disposed at a position away from the slot 21 of the antenna 2.

  The water collecting unit 15 receives rainwater discharged from the lower end of the upstream ridge 91. The water collecting unit 15 collects the received rainwater, and thereby causes the rainwater to flow into the drain tube 12. The water collecting unit 15 includes an upper end opening 155, a first fixing unit 150, and a second fixing unit 151. The upper end opening 155 is connected to the connection port 45 of the upper connection body 40 in communication. The first fixing part 150 is attached to the upper end of the cylindrical body 11. The second fixing portion 151 is attached to the upper end of the drain tube 12. In other words, the water collecting portion 15 fixes the tubular body 11 and the drain tube 12 to each other. The second fixing portion 151 has an opening. The opening of the second fixing portion 151 communicates with the upper end opening 155. As a result, the second fixing portion 151 and the drain tube 12 are connected, so that the upper end opening 155 of the water collecting portion 15 communicates with the inside of the drain tube 12.

  The water collecting portion 15 has an upper positioning recess 152. The upper positioning recess 152 is disposed at the same position as the upper positioning groove 13 of the cylindrical body 11.

  The antenna 2 is for receiving radio waves. The antenna 2 is attached to the outer peripheral portion 16 of the cylindrical body 11. The antenna 2 is provided between the cylindrical body 11 and the outer cylindrical body 19. As shown in FIG. 3, the antenna 2 is stacked from the outside along the outer peripheral portion 16 of the cylindrical body 11. In other words, the antenna 2 is stacked on the outer peripheral portion 16 of the cylindrical body 11. The antenna 2 may be embedded in the thickness of the outer peripheral portion 16 of the cylindrical body 11.

  The antenna 2 is made of a conductive metal plate material (including metal foil). As shown in FIG. 4, the antenna 2 has a substantially C-shaped cross section. The antenna 2 is formed by bending a vertically long rectangular metal plate material uniformly in the long side direction so that the short side direction is C-shaped.

  The antenna 2 is constituted by a slot antenna 20. The slot antenna 20 has a plurality of slots 21 formed in the vertical direction. The antenna 2 has directivity. A plurality of the slots 21 are arranged in the vertical direction (two in this embodiment). The slots 21 are connected by a slit-like narrow groove 22. The slot 21 is formed in a part of the circumferential direction of the slot antenna 20.

  Each slot 21 is formed by an opening hole penetrating the metal plate material. Each slot 21 is formed in a bow tie shape. The bow tie shape is defined as a shape in which the vertices of a pair of triangles face each other.

  The upper slot 21 has a power feeding unit 23. The power feeding unit 23 is provided at the approximate center in the vertical direction of the upper slot 21. The power feeding portion 23 is formed by the apex portion of the triangular piece 24 facing in the circumferential direction.

  As shown in FIG. 5, a coaxial cable 75 is electrically connected to the power feeding unit 23. The coaxial cable 75 has a central electric wire and an outer mesh wire. The coaxial cable 75 has a central electric wire connected to one triangular piece 24 and an outer mesh wire connected to the other triangular piece 24. The coaxial cable 75 is used to output radio waves received by the antenna 2 to an indoor electrical device. The coaxial cable 75 has a first end connected to the power supply unit 23 and a second end connected to a connector 422 provided on the upper connector 40 (see FIG. 9 and the like).

  As shown in FIG. 4, the antenna 2 of the present embodiment includes a first receiving unit 26 and a second receiving unit 27. The first receiving unit 26 receives radio waves in a first frequency band (for example, 473 to 600 MHz). The second receiving unit 27 receives radio waves in the second frequency band (for example, 600 to 720 MHz).

  The first receiving unit 26 includes a slot 21 and an opening peripheral edge of the slot 21. The second receiving unit 27 is made of a metal plate material that is continuous in the circumferential direction adjacent to the slot 21 in the vertical direction.

  The length in the vertical direction of the slot 21 constituting the first receiving unit 26 is determined according to the length of the electrical half wavelength of the radio wave in the first frequency band. The circumferential length of the second receiving unit 27 is determined according to the electrical half-wavelength of the radio wave in the second frequency band.

  As shown in FIG. 6, a gap 28 is formed between both ends of the antenna 2 in the circumferential direction. The gap 28 is formed over the entire length in the vertical direction. The gap 28 faces the slot 21. In other words, the gap 28 is arranged so as to be at a position opposite to the slot 21 across the arc center of the antenna 2.

  Further, the antenna 2 has a punched portion 29 on the back of the slot 21. The punched portion 29 is a portion where no metal plate material is present, and is provided at a position overlapping the slot 21 when viewed from the front. The punched portion 29 is formed such that the vertical length is longer than the vertical length of the slot 21, and the circumferential length is longer than the circumferential length of the slot 21.

  As shown in FIG. 4, the antenna 2 has a structure in which a protective sheet 25 is laminated on a metal plate material. The protective sheet 25 is non-conductive. As a result, the antenna 2 is suppressed from generating rust.

  The antenna 2 has a lower insertion groove 251 and an upper insertion groove 252. The lower insertion groove 251 is provided at the lower end of the antenna 2. The lower fitting groove 251 is disposed at a position overlapping the lower positioning recess 57 of the lower connecting body 50 and the lower positioning groove 14 of the tubular body 11. The upper insertion groove 252 is provided at the upper end portion of the antenna 2. The upper fitting groove 252 is disposed at a position overlapping the upper positioning recess 152 of the water collecting portion 15 and the upper positioning groove 13 of the tubular body 11.

  Note that the antenna 2 may not be provided with the protective sheet 25.

  As shown in FIG. 3, the antenna 2 having such a configuration is attached with the back surface in contact with the outer peripheral portion 16 of the cylindrical body 11. In a state where the antenna 2 is wound around the outer peripheral portion 16 of the cylindrical body 11, the antenna 2 is pressed and fixed by the mounting member 7 from the outside.

  As shown in FIG. 4, the attachment member 7 is formed in an annular shape in plan view. The attachment member 7 is divided into a first member 71 and a second member 72. The first member 71 and the second member 72 are detachably connected to each other. As illustrated in FIG. 5, the attachment member 7 includes a power feeding fixing portion 73 and a cable holding portion 74. The power feeding fixing unit 73 holds and fixes the end of the coaxial cable 75 in the power feeding unit 23. The cable holding unit 74 holds an intermediate portion of the coaxial cable 75. The cable holding portion 74 fixes the coaxial cable 75 at a position shifted in the circumferential direction with respect to the slot 21. As a result, the cable holding portion 74 prevents the coaxial cable 75 from overlapping the slot 21.

  The attachment member 7 includes an upper positioning protrusion (not shown) and a lower positioning protrusion (not shown). The upper positioning protrusion is inserted into the upper positioning recess 152 and the upper positioning groove 13 of the tubular body 11. The lower positioning protrusion is inserted into the lower positioning recess 57 of the lower connecting body 50 and the lower positioning groove 14 of the tubular body 11. Thereby, the attachment member 7 fixes the relative position of the cylindrical body 11 and the antenna 2. In other words, the attachment member 7 positions the antenna 2 in the circumferential direction with respect to the cylindrical body 11.

  As shown in FIG. 4, the outer cylinder 19 is formed in a circular cross section. The outer cylinder 19 is disposed outside the housing 10. The inner diameter of the outer cylinder 19 is formed larger than the outer diameter of the housing 10. The outer cylinder 19 is made of a nonconductive synthetic resin. The outer cylinder 19 has a length in the vertical direction. The outer cylinder 19 is disposed so that the central axis is parallel to the vertical direction. In other words, the central axis of the outer cylindrical body 19 substantially coincides with the central axis of the housing 10. Thus, the antenna rod 1 has a triple cylinder structure.

  As shown in FIGS. 3 and 4, the antenna rod 1 of the present embodiment is provided with a lower connection body 50 at the lower ends of the housing 10 and the outer cylindrical body 19. The antenna rod 1 is provided with an upper connection body 40 at the upper ends of the housing 10 and the outer cylinder body 19.

  The lower connection body 50 is fixed to the lower end of the housing 10. The lower connection body 50 is also fixed to the lower end of the outer cylinder body 19. The lower connection body 50 includes a rotating body 51 and a holding body 60. The rotating body 51 is fixed to the housing 10 and the outer cylinder body 19. The rotating body 51 is rotatably attached to the holding body 60. The holding body 60 supports the rotating body 51. The holding body 60 is fixed to the outer wall of a building via a saddle guard 80, for example.

  The rotating body 51 is supported by the holding body 60 so as to be rotatable around the central axis. The rotating body 51 fixes the drain cylinder 12, the cylindrical body 11, and the outer cylinder 19 to each other. Thereby, the rotating body 51 enables the drain cylinder 12, the cylindrical body 11, and the outer cylinder 19 to rotate integrally. As shown in FIG. 7, the rotating body 51 includes a fitting portion 54 and an outflow port 56. The fitting part 54 has an opening. The opening of the fitting portion 54 communicates with the outflow port 56 through the outflow passage 55.

  The holding body 60 rotatably supports the rotating body 51. In other words, the holding body 60 supports the housing 10 so as to be rotatable around the central axis. The holding body 60 has a self-weight receiving protrusion 62. The self-weight receiving protrusion 62 protrudes radially outward from the upper end of the holding body 60 in a flange shape. As shown in FIG. 3, the self-weight receiving protrusion 62 abuts on the upper end of the hook holder 80 when the holding body 60 is held by the hook holder 80. That is, the holding body 60 is held by the self-weight receiving protrusion 62 and the scissors holder 80 so as not to be displaced downward. The self-weight receiving protrusion 62 is formed over the entire length in the circumferential direction in the holding body 60.

  The lower connection body 50 is provided to connect the housing 10 to the downstream housing 92. In other words, the lower connection body 50 connects the downstream side collar 92 and the chassis 10 in communication. The holding body 60 of the lower connection body 50 is fixed so as not to rotate with respect to the flange 92 on the downstream side. Thereby, the rotating body 51 is freely rotatable with respect to the downstream side flange 92. In other words, the housing 10, the antenna 2, and the outer cylindrical body 19 are rotatable with respect to the downstream housing 92.

  The upper connection body 40 is provided at the upper end of the housing 10 as shown in FIG. 3. In other words, the upper connection body 40 is provided at the upper end portion of the antenna rod 1. As shown in FIG. 4, the upper connection body 40 includes a rotating portion 42 and a cover portion 43. The cover 43 has a connection port 45 and a water receiver 431. In other words, the upper connection body 40 further includes a connection port 45 and a water receiving portion 431. The connection port 45 is provided at the upper end of the antenna rod 1. The connection port 45 communicates with the drainage channel 18. The lower end of the upstream flange 91 is inserted through the connection port 45. The connection port 45 communicates with the outlet 56 of the lower connection body 50.

  The rotating part 42 is rotatable around the central axis of the housing 10. The rotating part 42 is rotatable with respect to the housing 10 and the outer cylinder 19. The rotating unit 42 rotates around the water collecting unit 15. As shown in FIG. 8, the rotating part 42 has a bulging part 420. The bulging portion 420 bulges sideward (horizontal direction) from the outer peripheral surface of the housing 10. Further, the bulging portion 420 bulges laterally (horizontal direction) from the outer peripheral surface of the outer cylindrical body 19. As shown in FIG. 9, a connecting tool 422 is attached to the bulging portion 420. Further, the rotating part 42 has an extraction hole 421. The extraction hole 421 is an arc-shaped long hole with the central axis of the housing 10 as the center. The extraction hole 421 penetrates in the vertical direction. In the bulging portion 420, the coaxial cable 75 connected to the antenna 2 is taken out onto the bulging portion 420 through the extraction hole 421.

  The bulging portion 421 is provided with a cable extraction portion 424. A connector 422 is attached to the cable outlet 424. More specifically, the connection tool 422 attached to the cable outlet 424 is exposed to the outside. The connection tool 422 is inserted from above the bulging portion 420 and protrudes downward from the lower surface of the bulging portion 420. The connection tool 422 is electrically connected to the second end of the coaxial cable 75 (that is, to the end opposite to the antenna 2 side).

  The cover part 43 covers the rotation part 42 as shown in FIG. The cover part 43 is detachably attached to the rotating part 42. The cover part 43 includes a water receiving part 431 and a side part 432. The water receiving portion 431 is provided with a standing piece 433. Further, the water receiving portion 431 is provided with a connection port 45. In other words, the connection port 45 is provided in a part of the water receiving portion 431. The water receiver 431 is configured by a substantially horizontal plane. The water receiving part 431 is located above the bulging part 420. The water receiving portion 431 covers the bulging portion 420 from above.

  The standing piece 433 protrudes upward from the outer edge of the water receiving portion 431. The standing piece 433 is formed in an annular shape. In other words, the standing piece 433 surrounds the outer edge of the water receiving portion 431 over the entire circumference. Thereby, the standing piece 433 prevents rainwater collected in the water receiving portion 431 from leaking outside.

  The side surface part 432 extends downward from the outer edge of the water receiving part 431. The side part 432 is formed larger than the rotating part 42. The side part 432 is configured to cover the side of the rotating part 42.

  As shown in FIG. 12, the connection port 45 is formed to be larger than the outer diameter of the upstream flange 91. In other words, when the antenna rod 1 is installed on the rod 8, a gap 84 is formed between the opening edge of the connection port 45 and the upstream rod 91. The connection port 45 has a hanging piece 451. The hanging piece 451 is extended downward from the inner periphery of the opening. The drooping piece 451 is positioned inside the upper end opening 155 of the water collecting portion 15 when the water receiving portion 431 contacts or approaches the upper end opening 155 of the water collecting portion 15. Thereby, the connection port 45 is connected to the upper end opening 155 of the water collecting portion 15.

  As shown in FIG. 8, the water receiving portion 431 has a stepped portion 49 provided on the peripheral edge portion of the connection port 45. The stepped portion 49 is provided over the entire periphery of the opening periphery of the connection port 45. The step portion 49 is formed by recessing the opening periphery of the connection port 45. The step portion 49 makes the upper surface of the lock member 44 and the upper surface of the water receiving portion 431 flush with each other when a lock member 44 described later enters.

  The upper connecting body 40 rotates around the central axis with respect to the housing 10. If it demonstrates in detail, if the upper connection body 40 will be lifted upwards with respect to the housing 10, it will be in a rotation permissible state. Further, the upper connection body 40 falls downward due to its own weight and enters a rotation restricted state when positioned at a predetermined position with respect to the housing 10. The rotation restriction state is defined as a state in which the rotation of the upper connection body 40 is restricted with respect to the housing 10. In other words, the upper connection body 49 is allowed to rotate when it is separated from the housing 10 upward. Further, the upper connection body 49 is in a rotation restricted state in the natural state. In addition, the natural state said here is defined as the state where the upper connection body 40 is not lifted.

  The water collection part 15 has the fitting convex part 153, as FIG. 8 shows. The fitting convex portion 153 is provided on the side surface of the water collecting portion 15. A plurality of fitting projections 153 are provided. The fitting convex part 153 is continuous in the circumferential direction. The fitting convex part 153 has a mountain shape protruding upward.

  The rotating portion 42 of the upper connection body 40 has a fitting recess 423 that fits into the fitting projection 153. The rotating part 42 has an insertion opening 425. The water collecting portion 15 is inserted into the insertion opening 425. The fitting recess 423 is provided on the inner peripheral surface of the insertion opening 425 (the surface facing the side surface of the water collecting portion 15). The fitting recess 423 has a concave shape downward, in other words, opens downward. A plurality of fitting recesses 423 are provided. The fitting recesses 423 are arranged in parallel over the half circumference of the insertion opening 425.

  When the water collecting portion 15 is inserted into the insertion opening 425 of the rotating portion 42, the fitting convex portion 153 is concavo-convexly fitted into the fitting concave portion 423. Thereby, the rotation part 42 will be in a rotation control state. Further, when the rotating portion 42 moves to the side away from the housing 10 (that is, upward), the fitting state between the fitting convex portion 153 and the fitting concave portion 423 is released, and the rotation is allowed.

  The antenna rod 1 further includes a lock member 44. The lock member 44 holds the rotating part 42 in the rotation restricted state. The lock member 44 selectively controls whether the relative rotation between the upper connecting body 4 and the housing 10 is restricted or the relative rotation is allowed. The lock member 44 restricts the rotation of the rotating portion 42 at an arbitrary position around the central axis of the housing 10.

  The lock member 44 has an annular shape in plan view. The lock member 44 is disposed so as to be rotatable along the opening of the connection port 45. The lock member 44 is disposed in the stepped portion 49 of the water receiving portion 431. As a result, the upper surface of the lock member 44 is flush with the upper surface of the water receiving portion 431.

  The lock member 44 includes a pressing portion 441, a holding portion 442, and a protruding portion 48. The pressing part 441 contacts the upper end of the cover part 43. The pressing part 441 is formed in an annular shape. The pressing part 441 is formed in a flange shape. The holding portion 442 protrudes downward from the inner peripheral edge of the pressing portion 441. The holding portion 442 is rotatably fitted in the connection port 45. The holding portion 442 has a protrusion 443. The protrusion 443 protrudes radially outward.

  The protruding portion 48 is provided on the upper surface of the pressing portion 441. The protrusion 48 protrudes upward. A plurality of protrusions 48 are provided. A plurality of protrusions 48 are provided on the upper surface of the pressing part 441. In other words, the projecting portion 48 is provided at the opening peripheral edge portion of the connection port 45. The protruding portion group including the pair of protruding portions 48 is spaced apart in the circumferential direction every 90 °. The protruding portion 48 also serves as a knob portion of the lock member 44.

  The water collecting unit 15 has a guide protrusion 154. The guide protrusion 154 is provided on the inner side surface of the water collecting portion 15. The guide protrusion 154 engages with the protrusion 443 of the holding portion 442 of the lock member 44. The guide protrusion 154 includes an inclined portion 156 and a horizontal portion 157. The inclined portion 156 is positioned downward as it goes from the first end to the second end side in the circumferential direction. Further, the inclined portion 156 is inclined so as to be gradually located below. The horizontal portion 157 is continuously provided in the circumferential direction from the first end of the inclined portion 156.

  As shown in FIG. 10, the protrusion 443 of the holding portion 442 of the lock member 44 is engaged with the guide protrusion 154 of the water collecting portion 15. As a result, the lock member 44 is guided by the guide protrusion 154 when rotating. More specifically, when the lock member 44 rotates, the protrusion 443 moves along the lower surface of the inclined portion 156 of the guide protrusion 154. As a result, the guide protrusion 154 pushes the lock member 44 downward. When the lock member 44 further rotates, the protrusion 443 moves to the horizontal portion 157. At this time, the holding portion 442 holds the pressing portion 441 in a state where the movement of the pressing portion 441 is restricted in the vertical direction with respect to the housing 10.

  When the lock member 44 is pushed down, the pressing portion 441 pushes the upper connection body 40 toward the housing 10 side. Thereby, the fitting convex part 153 and the fitting concave part 423 are unevenly fitted and held in this state. As a result, in the antenna rod 1, relative rotation between the upper connecting body 40 and the housing 10 is restricted at an arbitrary rotational position.

  When the lock member 44 rotates to the opposite side, the protrusion 443 of the holding portion 442 moves upward along the inclined portion 156. Then, the pressing portion 441 moves in a direction away from the housing 10. Thereby, the upper connection body 40 can be lifted relatively to the housing 10. As a result, the antenna rod 1 is in a state of allowing relative rotation between the upper connecting body 40 and the housing 10.

  As shown in FIG. 2, the antenna cage 1 configured as described above constitutes a part of the cage 8 installed along the building outer wall 90.

  竪 樋 8 is a round gourd. A round fold is defined as a fold having a circular cross section. The flange 8 has a length in the vertical direction. The eaves 8 have a flow path inside. The flow path of the eaves 8 is formed long in the vertical direction. The outer diameter of the round rod is smaller than that of the connection port 45. In other words, the round rod can be inserted into the connection port 45.

  The ridge 8 may be a square ridge. As shown in FIG. 13, the square ridge is a ridge having a corner in the cross-sectional shape. The square fold includes, for example, a fold having a triangular cross section, a fold having a square cross section, a fold having a pentagonal cross section, and the like. The square hook is smaller than the connection port 45 in the horizontal cross section. In other words, the square hook can be inserted into the connection port 45.

  The building outer wall 90 is provided with a trough structure for flowing rainwater. 2, the eaves structure includes an eave eave 94, a water collector 95, a first elbow 96, a call 97, a second elbow 98, and a eave 8. The eaves 94 is provided at the lower end of the roof of the building. The eaves 94 is arranged along the lower end of the roof. A water collector 95 is attached to the eaves 94. A first elbow 96 is connected to the water collector 95. A call 97 is connected to the first elbow 96. A second elbow 98 is connected to the call 97. An upstream flange 91 is connected to the second elbow 98. The upstream flange 91 is vertically separated from the downstream flange 92. The lower end of the downstream raft 92 is connected to a drainage groove (not shown).

  The antenna rod 1 is connected between the upstream rod 91 and the downstream rod 92. The antenna rod 1 is connected to the upper end of the downstream rod 92. Thereby, the flow path of the downstream raft 92 communicates with the drainage channel 18 of the antenna raft 1. The lower end of the upstream flange 91 is inserted into the connection port 45 of the antenna flange 1. Thereby, the flow path of the upstream raft 91 communicates with the drainage channel 18 of the antenna raft 1.

  As shown in FIG. 12, a gap 84 is generated between the connection port 45 of the antenna rod 1 and the outer surface of the rod 8. The connection structure between the antennas 竪 樋 1 and 竪 樋 8 includes a cover body 3. The cover body 3 covers the gap 84 from above.

  As shown in FIG. 11, the cover body 3 has a plate shape. The cover body 3 includes a closing plate 31 and a through hole 32. The closing plate 31 constitutes the main body of the cover body 3. The closing plate 31 has a disk shape. The closing plate 31 is plate-shaped. The outer diameter of the blocking plate 31 is formed larger than the inner diameter of the connection port 45. In other words, the closing plate 31 is formed larger than the connection port 45. The outer diameter of the closing plate 31 is smaller than the distance between the standing pieces 433.

  The through hole 32 penetrates the closing plate 31. A trough 8 is inserted into the through hole 32. The through hole 32 includes a hole 33, a cuttable part 34, and a cover piece 37. The hole 33 is formed along the outer shape of the first-sized ridge 82. The first size ridge 82 is a round ridge. In other words, the hole 33 is formed along the outer shape of the round rod. The inner diameter of the hole 33 is formed to be approximately the same as the outer diameter of the round rod (樋 8). The shape of the opening edge of the hole portion 33 is adapted to the outer shape of the round rod.

  The cuttable part 34 is a part formed so that it can be cut easily. The cutable portion 34 is formed between the closing plate 31 and the covering piece 37. The cutable portion 34 connects the closing plate 31 and the covering piece 37. The cutable portion 34 is formed along the outer shape of the second-sized ridge 83. The cutable part 34 is formed outside the hole 33. The second size ridge 83 is a square ridge. In other words, the cuttable portion 34 is formed along the outer shape of the square hook. The cutable part 34 is adapted to the outer shape of the square hook.

  The cuttable part 34 includes a slit 36 and a connecting part 35. The slit 36 is located between the connecting portions 35. Note that the cuttable portion 34 may not have the slit 36. The cutable portion 34 may be a thin connecting portion 35 provided over the entire length.

  The cover piece 37 covers a part of the gap 84 between the connection port 45 and the flange 8 until the cuttable portion 34 is cut. The inner edge of the cover piece 37 forms a part of the hole 33. The covering piece 37 is arranged at the corner of the square hook. The covering piece 37 is integrated with the closing plate 31.

  As shown in FIG. 1, the cover body 3 having such a configuration is attached to the upstream flange 91. The through hole 32 of the cover body 3 is inserted into the lower end of the upstream flange 91. The cover body 3 is placed on the protrusion 48 of the connection port 45 of the antenna rod 1. Thereby, the cover body 3 covers the gap 84 between the connection port 45 of the antenna rod 1 and the rod 8.

  When the ridge 8 is a square ridge, the builder cuts the cuttable portion 34 of the cover body 3 in advance before installing the ridge 8 (see FIG. 11B). Thereafter, the cover body 3 is attached to the upstream flange 91 as shown in FIG. Similarly, the cover body 3 is placed on the protrusion 48 of the connection port 45 of the antenna rod 1. Thereby, the cover body 3 covers the gap 84 between the connection port 45 of the antenna rod 1 and the rod 8.

  Note that the upstream side hook 91 and the downstream side hook 92 are fixed to the outer wall 90 via the hook retainer 99. Further, the antenna rod 1 of the present embodiment is fixed by a rod holder 80 formed of a nonconductive resin. Thus, when installed, the antenna cage 1 of this embodiment constitutes a part of the cage installed along the outer wall 90 of the building.

  To install the antenna cage 1 of the present embodiment, the installer first installs the cover body 3 on the cage 8. The installer inserts the lower end of the upstream flange 91 into the connection port 45 of the upper connection body 40. Thereafter, the installer connects the lower connection body 50 to the downstream flange 92. Then, the lower connection body 50 is fixed to the building outer wall 90 via the saddle guard 80.

  Next, the installer rotates the antenna rod 1 with respect to the upstream rod 91 and the downstream rod 92 so that the antenna 2 can receive the broadcast radio wave most strongly. At this time, the housing 10 is rotatable with respect to the holding body 60 of the fixed lower connection body 50 in the antenna housing 1. Further, a gap 84 of a certain level or more is provided between the flange 8 and the opening edge of the connection port 45. For this reason, the installer can rotate and finely adjust the direction of the antenna 2. After fine adjustment, the installer fixes the antenna rod 1 using another rod holder 80.

  Next, the installer rotates the upper connection body 40 of the antenna rod 1 so that the bulging portion 420 runs along the building outer wall 90. Then, the installer rotates the lock member 44 to lock the rotation of the upper connection body 40.

  The antenna rod 1 of the present embodiment is an antenna having drainage performance. That is, although the antenna was conventionally installed on the roof, according to the antenna fence 1 of this embodiment, it can be integrated with the fence 8 and the building exterior can be improved.

  The antenna rod 1 of the present embodiment is unitized as an antenna having drainage performance. Therefore, it can be easily attached to the building regardless of the workmanship. Thereby, the finish after construction can be made more than a certain level.

  Further, the connection structure between the antenna rod 1 and the rod 8 of the present embodiment includes the cover body 3 that covers the gap 84 between the opening edge of the connection port 45 and the rod 8. For this reason, it is possible to reduce dust, dust, sand and the like from entering through the gap 84 between the connection port 45 and the rod 8 as much as possible.

  Further, the cover body 3 of the present embodiment includes a closing plate 31 and a through hole 32. For this reason, it is formed with a simple structure. Therefore, the cover body 3 can be easily manufactured.

  Further, in the connection structure between the antennas 1 and 8 of the present embodiment, the cover body 3 is placed on the protruding portions 48 that are spaced apart. For this reason, even if the cover 84 covers the gap 84 between the connection port 45 and the flange 8, rainwater received on the water receiving portion 431 passes through the projections 48 and passes through the connection port 45. Can be drained inside. In other words, the space between the protrusions 48 is a flow path that connects the water receiving portion 431 and the connection port 45.

  Further, the through hole 32 of the cover body 3 of the present embodiment includes a hole 33 and a cuttable part 34. For this reason, the cover body 3 can be installed in various ridges only by cutting | disconnecting the cutable part 34. FIG.

  The antenna rod 1 of the present embodiment may be attached when a new rod 8 is constructed, or may be retrofitted by cutting off a part of the already installed rod 8. Good.

  Moreover, although the standing piece 433 was provided in the outer edge, the water receiving part 431 should just be a part which can receive only rain water in this invention. That is, the water receiving portion does not have to be provided with standing pieces on the outer edge.

DESCRIPTION OF SYMBOLS 1 Antenna rod 10 Housing 11 Tubular body 12 Drain tube 15 Water collecting part 16 Outer peripheral part 18 Drain channel 19 Outer cylindrical body 2 Antenna 20 Slot antenna 21 Slot 3 Cover body 31 Closing plate 32 Through-hole 33 Hole part 34 Cuttable Part 35 Connecting part 36 Slit 40 Upper connecting body 42 Rotating part 420 Swelling part 428 Swelling part 43 Cover part 431 Water receiving part 433 Standing piece 45 Connection port 46 Opposing part 48 Projection part 8 ８２ 82 First size竪 樋 83 Second size ８４ 84 Gap 90 Outer wall 91 Upstream 竪 樋 92 Downstream 竪 樋 x

Claims (3)

An antenna bowl with a drainage channel and an antenna inside;
A connection port provided at an upper end of the antenna rod and communicating with the drainage channel;
A trough whose lower end is inserted through the connection port;
A gap provided between an opening edge of the connection port and the flange;
A cover body covering the gap ,
The antenna rod has an upper connection body provided at the upper end of the antenna rod,
A water receiving portion for receiving rainwater is formed on the upper surface of the upper connection body,
The connection port is provided in a part of the water receiving portion,
A plurality of protrusions projecting upward are spaced from the peripheral edge of the opening of the connection port,
A connection structure between an antenna rod and a rod, wherein the cover body is placed on the protrusion . The cover body is
A closing plate larger than the connection port;
2. The connection structure between the antenna rod and the flange according to claim 1, further comprising a through hole provided in the closing plate and through which the flange is inserted.   An antenna bowl with a drainage channel and an antenna inside;
A connection port provided at an upper end of the antenna rod and communicating with the drainage channel;
A trough whose lower end is inserted through the connection port;
A gap provided between an opening edge of the connection port and the flange;
A cover body covering the gap;
A cover body used for a connection structure between an antenna 竪 樋 and 竪 樋 having
A closing plate larger than the connection port of the antenna rod;
A through hole provided in the closing plate for inserting the ridge;
With
The through hole is
A hole formed along the outer shape of the first-sized ridge;
A severable portion formed on the outer side of the hole so as to follow the outer shape of the ridge having a second size larger than the first size;
have
A cover body characterized by that.

Images