JP6489647B2 - Split concrete pillar - Google Patents

Description

  The present invention relates to a divided concrete column in which an upper column and a lower column are connected to each other through a flange portion provided at each intermediate portion of the concrete column.

  As for the electric pole which is a concrete pole, what is called one thing which was generally formed by one concrete structure with a length of 7-17 m is the mainstream.

  In concrete columns such as these, the bending stress acting from the top of the utility pole toward the ground gradually increases due to the action of wind pressure load or the like on the overhead wire in the installed state.

  Therefore, it is common to select an electric pole having a bending performance corresponding to a bending stress caused by wind pressure load or the like as the concrete pillar.

  Specifically, in order to obtain prestressed concrete in which the occurrence of breakage such as cracks due to bending stress is suppressed, it corresponds to the tension steel material arranged over the entire length in the axial direction and bending stress that gradually increases from the top. Therefore, a non-tensile steel material arranged so as to improve the sectional force stepwise from the top is provided.

  In concrete pillars, the end of the tension steel material is embedded in the concrete in a cut state, and the end of the non-tensile steel material is generally embedded in the concrete without tip treatment. is there.

  Here, when transporting concrete pillars, there are restrictions depending on the load weight and the length of the load, so if you exceed the predetermined length you will receive a predetermined permission or before and after the loaded vehicle It is necessary to place a guided vehicle.

  For such problems in transportation, for example, as shown in Patent Document 1, the upper pole as the upper column and the middle pole as the lower column are installed in a state of being connected via the flange portion, A concrete pillar having a structure that can be transported in a divided state before installation is known.

  In the concrete column of Patent Document 1, an outer cylinder part as a reinforcing part that constitutes an outer peripheral surface of a concrete columnar part is provided in a flange part, and in order to improve the integrity of the outer cylinder part and the columnar part, The contact area with the columnar portion is increased by fixing the wire rod as the concavo-convex portion to the inner peripheral surface of the outer cylindrical portion.

  In addition to the configuration of Patent Document 1, in order to improve the integrity of the flange portion and the columnar portion, a reinforcing band as a reinforcing portion disposed so as to cover the outer peripheral surface of the end portion of the columnar portion is a flange. In the structure that is integrally provided by welding to the part, the structure that increases the contact area with the columnar part that welds the ring line to the inner peripheral surface of the reinforcing band, and the columnar part using a striped steel plate as the reinforcing band A configuration in which the contact area is increased, a configuration in which a deformed reinforcing bar is welded to a reinforcing band or a flange portion, and the deformed reinforcing bar is embedded in a columnar portion are known.

JP 2008-101325 A

  However, in the configuration of the above-mentioned Patent Document 1, it is necessary to provide a reinforcing member with a wire rod such as a ring wire or a deformed reinforcing bar, or to form the reinforcing portion itself with a striped steel plate. The connection strength between the parts has not been studied, the stress due to wind pressure load etc. is concentrated on the connection part of the upper column and the lower column, the connection part may be damaged and the connection strength may be reduced, There is a possibility that the connection strength may decrease due to the corrosion resistance of the connection portion.

  This invention is made | formed in view of such a point, and it aims at providing the division | segmentation concrete pillar which the connection intensity | strength of an upper pillar and a lower pillar is hard to fall.

The split concrete column described in claim 1 includes an upper column provided with a flange joint at a lower end which is at least one axial end of a cylindrical column, and at least an axial of a cylindrical column. A flange joint part is provided at the upper end part which is the other end part, and comprises a lower column connected to the lower side of the upper column via a mutual flange joint part, and the flange joint part includes: A flange portion disposed at an end portion in the axial direction of the columnar portion and an outer peripheral surface of the columnar portion that is provided integrally with the flange portion and extends from the end portion of the columnar portion in the axial direction. The upper column and the lower column are arranged with a tension material for introducing pre-stress into the columnar portion and a non-tensile material for reinforcing the columnar portion. Prestressed concrete columns installed, By the end of the fine the untensioned material is fixed to the flange portion, wherein a flange joint portion is fixed to the columnar portion, wherein the upper column and the lower column, the flange portions are molten zinc It is fixed and connected with a plated bolt.

  The divided concrete column described in claim 2 is the divided concrete column according to claim 1, wherein the upper column and the lower column having the same or different performance are combined and connected.

The split concrete pillar according to claim 3 is the split concrete pillar according to claim 1 or 2, wherein the bolt is a size that can be manually tightened using a tool, and the flange portion corresponds to the size of the bolt. and Ru der having a protruding length of the columnar portion.

The split concrete column according to claim 4 is the split concrete column according to any one of claims 1 to 3, wherein the tension material and the non-tension material are located at a line-shaped wire portion and an end portion of the wire portion. A rivet head portion having a diameter larger than the wire portion, the flange portion has a fixing hole capable of locking the rivet head portion, and the tension material and the non-tension material are the rivet head portion The wire is locked in a fixed hole, and the wire portion is drawn from the fixed hole toward the columnar portion and is embedded in the columnar portion.

According to the present invention, the galvanizing is performed on the flange portion in which the tension material and the non-tension material in the upper column are locked, and the flange portion in which the tension material and the non-tension material in the lower column are locked . Since it connects using a volt | bolt, the fall of the connection intensity | strength with an upper side pillar and a lower side pillar can be suppressed.

It is sectional drawing which shows the structure of the division | segmentation concrete pillar which concerns on one embodiment of this invention. It is a top view which shows the flange joint part of a split concrete pillar same as the above. It is an end elevation which shows the flange joint part of a division | segmentation concrete pillar same as the above. It is a side view which shows the edge part of the non-tensile material of a split concrete pillar same as the above.

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

  In FIG. 1, reference numeral 1 denotes a divided concrete column. The divided concrete column 1 is used as a concrete electric pole, a lighting pole, a ball-proof net pole, an antenna pole, and the like.

  The divided concrete column 1 has a so-called assembling-type configuration including an upper column 2 and a lower column 3 connected to the lower side of the upper column 2.

  The upper column 2 has a cylindrical prestressed concrete columnar portion 4 having a tapered shape with an outer peripheral surface gradually increasing in diameter downward. Further, a flange joint portion 5 made of metal (for example, steel) is integrally provided at a lower end portion which is one end portion in the axial direction of the columnar portion 4.

  The lower column 3 has a cylindrical columnar portion 6 whose outer peripheral surface is a tapered shape whose diameter gradually increases downward with the outer peripheral surface of the columnar portion 4 of the upper column 2. Further, a metal (for example, steel) flange joint portion 7 is integrally provided at an upper end portion which is the other end portion in the axial direction of the columnar portion 6.

  The upper column 2 and the lower column 3 are a bar-shaped tension steel material as a tension material (not shown) for prestressing the columnar portions 4 and 6 and a non-tensile material for reinforcing the columnar portions 4 and 6. The non-tensioned steel material 8 is arranged through the columnar parts 4 and 6 to the flange joint parts 5 and 7.

  As shown in FIGS. 2 and 3, the flange joint portion 5 includes a flange portion 11 disposed at an end portion of the columnar portion 4, and a reinforcing portion 12 provided integrally with the flange portion 11. Yes. The flange joint portion 7 has the same configuration as the flange joint portion 5.

  The flange portion 11 has a disk shape with an inner opening, that is, a ring shape having a predetermined thickness. The opened inner diameter is the same as that of the columnar portions 4 and 6, and the outer diameter is outside the columnar portions 4 and 6. Larger than the diameter.

  In the state where the flange joint portion 5 is attached to the columnar portion 4, the flange portion 11 is arranged so that the inner peripheral surface forms a continuous surface with the inner peripheral surface of the columnar portion 4, and the outer periphery It arrange | positions so that a surface may protrude on the outer side of radial direction from the outer peripheral surface of the columnar parts 4 and 6. FIG.

  A cylindrical reinforcing portion 12 is integrally provided by welding between the inner peripheral surface and the outer peripheral surface of the flange portion 11 so as to protrude from the end surface of the flange portion 11 to the columnar portion 4 side.

  The reinforcing portion 12 is disposed along the outer peripheral surface of the columnar portion 4 from the end portion on the flange portion 11 side of the columnar portion 4 to a part of the columnar portion 4 in the axial direction. That is, the inner diameter of the reinforcing portion 12 is substantially the same as the outer diameter of the columnar portions 4 and 6, and the outer peripheral surface of the end portion of the columnar portion 4 is covered by the reinforcing portion 12.

  A plurality (for example, 16 pieces) of bolts 13 for fixing the upper column 2 and the lower column 3 can be inserted into a portion outside the reinforcing portion 12 in the flange portion 11, that is, a protruding portion from the reinforcing portion 12. An insertion hole 14 is provided.

  These insertion holes 14 are arranged at equal intervals in the circumferential direction of the flange portion 11 and are formed so as to penetrate from the one end surface side of the flange portion 11 to the other end surface side.

  Further, a plurality of (for example, two) fittings capable of fitting guide pins (not shown) for positioning the flange joint portion 7 of the lower column 3 with respect to the flange joint portion 5 of the upper column 2 are fitted to the flange portion 11. A joint hole 15 is provided.

  These fitting holes 15 are arranged in a part between the insertion holes 14, and the depth from the end face of the flange portion 11 is shorter than the axial length of the guide pin. That is, in a state where the guide pin is fitted and attached to one fitting hole 15 of the flange joint portion 5 and the flange joint portion 7, a part of the guide pin protrudes from the end face of the flange portion 11, The flange joint portion 7 is positioned with respect to the flange joint portion 5 by fitting the protruding portion of the guide pin into the other fitting hole 15 of the flange joint portion 5 and the flange joint portion 7.

  The upper column 2 and the lower column 3 are fixed by the bolt 13 in a state where the end surfaces of the flange portions 11 of the flange joint portions 5 and 7 are abutted and positioned by the guide pins. More specifically, in a state where the flange portion 11 is positioned, the bolt 13 is inserted into the insertion hole 14 from the lower column 3 side of the insertion hole 14 and the washer 16 from the upper column 2 side as shown in FIG. By screwing the nut 17 through the screw, the nuts 17 are fixed and connected to each other.

  Here, the bolt 13, nut 17 and washer 16 which are connecting members are hot dip galvanized over the entire surface. In addition, not only the bolt 13, the nut 17, and the washer 16, but also the entire surface of the flange joint portions 5 and 7 is preferably subjected to hot dip galvanization.

  Bolts 13 and nuts 17 are preferably of a minimum size that can be tightened manually using a tool such as a torque wrench. The flange portion 11 has a protruding length of the flange portion 11 from the columnar portions 4 and 6 according to the size of the bolt 13. That is, the protruding width, which is the length from the columnar portions 4 and 6 to the outer end portion of the flange portion 11, is determined by the size of the bolt 13, and the protruding width of the flange portion 11 is preferably set as small as possible. Specifically, for example, by using bolts 13, nuts 17 and washers 16 having a maximum size of M16, the protruding width of the flange portion 11 can be set to 50 mm.

  A plurality of (for example, 20) fixing holes 18 for fixing the tension steel material and a non-tensile steel material 8 are fixed on the inner side of the reinforcing portion 12 in the flange portion 11, that is, on the extension of the columnar portions 4 and 6. A plurality of (for example, four) fixing holes 19 are provided.

  The fixing holes 18, 19 have a small diameter portion 21 disposed on the columnar portions 4, 6 side, and a large diameter portion 22 disposed on the opposite side of the columnar portions 4, 6 and having a larger diameter than the small diameter portion 21. Yes. That is, the fixing holes 18 and 19 are formed in a continuous step shape by the small-diameter portion 21 and the large-diameter portion 22 and penetrate from the one end surface side in the axial direction of the flange portion 11 to the other end surface side.

  Here, as shown in FIG. 4, the non-tensile steel material 8 includes a line-shaped wire portion 23 and a rivet head portion 24 located at an end of the wire portion 23 and having a larger diameter than the wire portion 23. Yes.

  The wire portion 23 has a smaller diameter than the small diameter portion 21 of the fixing hole 19 and can be inserted into the small diameter portion 21. The rivet head portion 24 is smaller in diameter than the large-diameter portion of the fixing hole 19 and larger in diameter than the small-diameter portion 21, and can be inserted into the large-diameter portion 22 of the fixing hole 19, but is not inserted into the small-diameter portion 21. It is locked to.

  In the non-tensioned steel material 8, the rivet head portion 24 is locked to the small diameter portion 21, and only the wire portion 23 is drawn through the small diameter portion 21 from the fixing hole 19 to the columnar portions 4 and 6 side. Are embedded in the columnar parts 4 and 6.

  A tension steel material (not shown) is configured in the same manner as the non-tensile steel material 8, the rivet head portion 24 is locked in the fixing hole 18, and the wire portion drawn from the fixing hole 18 toward the columnar portions 4 and 6 is the columnar portions 4 and 6. Buried inside.

  In addition, the non-tensile steel material 8 is arranged in the formwork before pouring the concrete which forms the columnar parts 4 and 6. That is, the wire portion 23 is inserted into the fixing hole 19 of the flange portion 11 set in the mold, and the end portion of the wire portion 23 is exposed from one side, which is the columnar portions 4 and 6 side, of the flange portion 11 to the other side. . A rivet head portion 24 is formed at the end of the wire portion 23 exposed from the flange portion 11, and the rivet head portion 24 is locked to the small diameter portion 21.

  The tension steel material is laid in the mold before pouring the concrete forming the columnar parts 4 and 6. That is, the wire portion is inserted into the fixing hole 18 of the flange portion 11 set in the mold frame, and the end portion of the wire portion 23 is exposed from one side which is the columnar portions 4 and 6 side of the flange portion 11 to the other side. A rivet head portion is formed at the end of the wire portion exposed from the flange portion 11, and the rivet head portion 24 is locked to the small diameter portion 21 and fixed to the flange portion 11. In addition, the concrete is poured into the mold with tension applied to the tension steel material fixed to the flange portion 11, and after forming by, for example, centrifugal molding, the tension force of the tension steel material is released to release the columnar portions 4, 6 Introducing prestress.

  Next, the construction method of the said divided concrete pillar 1 is demonstrated.

  When the divided concrete pillar 1 is constructed, it is transported to the construction site in a state where the upper pillar 2 and the lower pillar 3 are divided.

  At the construction site, the lower column 3 is embedded in the lower surface of the installation surface, and a guide pin is fitted into each fitting hole 15 of the flange 11 of the lower column 3 and attached. .

  Further, the upper column 2 is lifted so that the lower end surface of the flange portion 11 of the upper column 2 and the upper end surface of the flange portion 11 of the lower column 3 are brought into contact with each other, and the upper column 2 is moved upward from the flange portion 11 of the lower column 3. The guide pin protruding toward the top is fitted into the fitting hole 15 of the flange portion 11 of the upper column 2 to position the upper column 2 and the lower column 3.

  With the upper column 2 and the lower column 3 positioned as described above, bolts 13 are inserted into the respective insertion holes 14 of the flange portion 11, and nuts 17 are screwed through the washers 16, so that the flange joint portion 5. , 7 are fastened together.

  When the flanges 11 are fastened with the bolts 13 and the nuts 17, first, the nuts 17 are tightened twice every 100 N · m in diagonal order in a plan view shown in FIG. 2 using a torque wrench. Next tighten.

  After this primary tightening, a straight marking line is provided from the portion of the bolt 13 protruding from the nut 17 (extra-long screw portion) to the nut 17, the washer 16, and the flange portion 11.

  Further, the nuts 17 are finally tightened by a so-called angle tightening which is rotated within a range of 120 ° ± 30 ° with respect to the marking line using a torque wrench, and the flange joint portions 5 and 7 are fastened to each other. The column 2 and the lower column 3 are connected and fixed.

  In addition, when replacing the upper column 2 when the design change after installing the split concrete column 1 or when only the upper column 2 is damaged, the fastening with the bolt 13 is released, the upper column 2 is removed, and the above-mentioned Thus, the new upper column 2 is connected to the lower column 3.

  Next, effects and the like of the one embodiment will be described.

  According to the split concrete column 1, the flange portion 11 of the upper column 2 and the flange portion 11 of the lower column 3 are connected using the bolt 13 that has been subjected to hot dip galvanization. Corrosion resistance can be improved, and the fall of the connection strength of the upper column 2 and the lower column 3 can be suppressed. Therefore, the upper column 2 and the lower column 3 can be kept connected with a simple configuration.

  Further, by applying galvanizing to the nut 17 and the washer 16, which are connecting members other than the bolt 13, and the flange joint portions 5 and 7, it is possible to further prevent the connection strength from being lowered.

  Since the divided concrete column 1 is configured such that the upper column 2 and the lower column 3 are connected so as to be divided, for example, when the upper column 2 is broken or when the design is changed such as the ground height and the design load. It is economical because only the upper column 2 can be replaced, the workability is good, and the lower column 3 can be used as it is.

  Further, since the divided concrete column 1 can be transported in a state where the upper column 2 and the lower column 3 are divided, it is easy to cope with restrictions on the load weight and the length of the load when transporting, and it is easy to transport. Furthermore, since the mass per body is lighter and the length is shorter than a single concrete pillar, the workability can be improved. For example, existing overhead wires can be easily removed during construction, and the space is narrow. Easy to install.

  Furthermore, since the fitting hole 15 is provided in the flange part 11 and the upper pillar 2 and the lower pillar 3 can be positioned using a guide pin, for example, when the bolt 13 and the nut 17 are screwed together, the lower pillar Therefore, the upper column 2 and the lower column 3 can be easily and reliably connected to each other.

  In utility poles, etc., it is generally preferred that the flange 11 has a short protruding width, but by using bolts 13 of a size that can be tightened manually, the protruding width of the flange 11 can be minimized. Can be suppressed.

  Since both ends of the tension steel material and the non-tensile steel material 8 are fixed to the flange portion 11, the columnar portions 4 and 6 and the flange joint portions 5 and 7 can be firmly connected with a simple configuration, for example, a conventional configuration. In order to improve the integrity of the columnar parts 4 and 6 and the flange joint parts 5 and 7, the reinforcing part 12 is provided with a wire rod, deformed reinforcing bar, etc., or the reinforcing part 12 itself is formed of a striped steel plate. Therefore, the configuration of the reinforcing portion 12 can be simplified, the length of the reinforcing portion 12 from the flange portion 11 can be shortened, and the manufacturing cost and material cost can be suppressed.

  In particular, the tension steel material and the non-tensile steel material 8 have the rivet head portion 24, and the rivet head portion 24 is fixed to the fixing holes 18 and 19 of the flange portion 11, thereby ensuring the tension steel material with a simple configuration. And the non-tensile steel material 8 can be fixed to the flange portion 11.

  In the above embodiment, the lower column 3 has a lower end embedded in the ground. However, the present invention is not limited to such a configuration. For example, the lower column 3 has an intermediate structure, that is, The present invention can also be applied to a configuration in which the lower column 3 is connected to the upper side of the foundation body or the lower end column installed on the installation surface, and the upper column 2 is connected to the upper side of the lower column 3.

  Further, although both the upper column 2 and the lower column 3 are tapered, the present invention is not limited to such a configuration, and the shapes of the upper column 2 and the lower column 3 can be appropriately determined.

  That is, the divided concrete columns 1 can be adjusted in performance such as shape and strength so as to be suitable for use by combining and connecting the upper column 2 and the lower column 3 having the same or different performance. For example, by making the lower column 3 a cylindrical shape (no taper shape) that is not tapered, the ground can be made thinner than the tapered shape. Further, by increasing the strength of the lower column 3, it is possible to replace only the upper column 2 during design changes and maintenance. Furthermore, in general, there are few overhead lines when used as utility poles for electric power companies, and many overhead lines when used as utility poles for telecommunication companies, so that the performance and shape suitable for each strength are achieved. The upper column 2 and the lower column 3 can be combined.

DESCRIPTION OF SYMBOLS 1 Split concrete pillar 2 Upper pillar 3 Lower pillar 4 Column-shaped part 5 Flange joint part 6 Column-shaped part 7 Flange joint part 8 Non-tensile steel as a non-tensile material
11 Flange
12 Reinforcement
13 volts
18 fixing hole
19 Fixing hole
23 Wire part
24 Rivet head

Claims (4)

An upper column provided with a flange joint at the lower end which is at least one end in the axial direction of the cylindrical column;
A lower column which is provided with a flange joint portion at an upper end portion which is at least the other end portion in the axial direction of the cylindrical columnar portion and is detachably connected to the lower side of the upper column via each flange joint portion; Comprising
The flange joint portion includes a flange portion disposed at an end portion in the axial direction of the columnar portion, and the columnar portion provided integrally with the flange portion and extending from the end portion of the columnar portion in the axial direction. A reinforcing portion disposed along the outer peripheral surface of the portion,
The upper column and the lower column are prestressed concrete columns in which a tension material for introducing prestress into the columnar portion and a non-tensile material for reinforcing the columnar portion are disposed,
The flange joint portion is fixed to the columnar portion by fixing the end portions of the tension material and the non-tension material to the flange portion,
The divided concrete column, wherein the upper column and the lower column are connected to each other by fixing flange portions with bolts subjected to hot dip galvanization. The split concrete column according to claim 1, wherein an upper column and a lower column having the same or different performance are combined and connected. Bolts are sizes that can be tightened manually with tools,
The split concrete column according to claim 1 or 2, wherein the flange portion has a protruding length from the columnar portion corresponding to the size of the bolt. The tension material and the non-tension material have a line-shaped wire portion and a rivet head portion positioned at an end of the wire portion and having a larger diameter than the wire portion,
The flange portion has a fixing hole capable of locking the rivet head portion,
The tension material and the non-tension material are characterized in that the rivet head portion is locked in the fixing hole, and the wire portion is drawn from the fixing hole to the columnar portion side and embedded in the columnar portion. The split concrete pillar according to any one of claims 1 to 3 .

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