JP2013194384A - Vibrator for concrete compaction and concrete compaction method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a technique relating to a vibrator which can be used for compaction of concrete with a small unit water amount and can suppress movement at the time of concrete placing.SOLUTION: A vibrator for concrete compaction 101 that has a vibrating body that vibrates at a predetermined vibration frequency, includes a bar-shaped body part 103 incorporating the vibrating body, and a projection 104 that projects from the center of the body part in radial direction and suppresses movement of the body part in concrete form at the time of concrete compaction.

Description

  The present invention relates to a vibrator for concrete compaction and a technique of a concrete compaction method.

  As a concrete compaction technique in the conventional tunnel lining, there is a technique using a floating vibrator (see, for example, Patent Document 1).

Japanese Patent No. 2918384

  The existing rod-shaped vibrator moves in the mold when placing concrete and may come into contact with the mold. Since the conventional floating vibrator has a float, movement of the vibrator can be suppressed to some extent. However, depending on the concrete slump, even a conventional floating vibrator moves with the flow of the concrete when the concrete is placed. Therefore, conventionally, movement of the floating vibrator has been suppressed by attaching a predetermined weight to the floating vibrator. For example, if the concrete slump is 15 cm or more, the movement of the floating vibrator can be suppressed by attaching a weight of 6.3 kg to the floating vibrator.

  On the other hand, in concrete structures, technical development for reducing cracks has been performed. There is no exception in tunnels, and there is a need for the development of technology that can suppress cracks in lining concrete, especially long-term cracks. Development of a technique for placing concrete with a smaller unit water volume than before has been promoted as a technique that can further suppress cracks in lining concrete, particularly long-term cracks. In other words, the concrete having a smaller unit water volume than conventional is hard concrete, for example, concrete with slump 12 ± 2.5 cm.

  When a conventional floating vibrator is used for compacting such concrete with a small amount of unit water, it is necessary to attach a heavier weight to suppress the movement of the floating vibrator as described above. However, if a heavier weight is attached, the floating vibrator becomes heavier and difficult to handle.

  This invention makes it a subject to provide the technique regarding the vibrator which can be used for compaction of the concrete with few unit water amount in view of said problem, and can suppress the movement at the time of concrete placement.

  In the present invention, in order to solve the above-described problem, the vibrator is included in the vibrator-like rod-like main body portion, radially projecting radially from the center of the main body portion, and when the concrete is compacted, Protruding portions that suppress movement are provided.

Specifically, the present invention is a concrete compacting vibrator having a vibrating body that vibrates at a predetermined frequency, and a rod-shaped main body part that includes the vibrating body, and a radial direction from the center of the main body part. A projecting portion that projects radially and suppresses movement of the main body within the mold when the concrete is compacted.

  In the concrete compaction vibrator according to the present invention, the main body portion is provided with the projecting portions that project radially, thereby suppressing the movement of the main body portion within the formwork. For example, in the width direction of the mold frame, the protrusions are in contact with the inner surface of the mold frame provided in the width direction, so that the movement of the main body portion, particularly in the width direction of the mold frame, is suppressed. Further, when compacting concrete with a small amount of unit water, the conventional floating vibrator requires additional weight to suppress movement. On the other hand, in this invention, since the movement of a main-body part can be suppressed by a protrusion part, even when compacting the concrete with little unit water quantity, it is not necessary to provide a weight like the conventional floating vibrator. Therefore, it is possible to easily compact concrete with a small amount of water. In other words, the concrete having a small unit amount of water is hard concrete, for example, concrete having a slump of 12 ± 2.5 cm. For example, in the standard method of conventional tunnel lining, the concrete slump is mainly 15 ± 2.5 cm, and the concrete slump containing non-steel fibers is mainly 18 ± 2.5 cm in consideration of fluidity. It is. Therefore, the present invention can be suitably used as a vibrator when placing concrete that is harder than the concrete used in the standard method of conventional tunnel lining. The predetermined frequency is a frequency required for compaction of concrete, and is appropriately set depending on the blending of concrete and the like.

  Here, the protruding portion may have a plurality of rod-like arm portions extending radially from the center of the main body portion in the radial direction. It is preferable that the arm portions have the same angle formed between adjacent arm portions and are at least 3 or more. Thereby, regardless of the direction of the vibrator, the movement of the main body can be similarly suppressed. In addition, when there are too many arm parts, there exists a concern that the resistance at the time of winding up the vibrator for concrete compaction may increase. Therefore, it is preferable to design the number and shape of the arm portions so that the movement can be effectively suppressed and the concrete compacting vibrator can be wound up.

  Further, the projecting portion can be provided at at least two places, a lower portion of the main body portion and a predetermined position above the lower portion. Thereby, a movement can be effectively suppressed rather than the case where one protrusion part is provided. In addition, it is preferable that a protrusion part is detachably connected with respect to a main-body part. Thereby, the convenience of the vibrator for concrete compaction improves. It is also possible to use an existing rod-shaped vibrator. Furthermore, it is preferable that the protruding portion is rotatable about the main body portion as an axis. Thereby, the impact at the time of a protrusion part contacting a formwork can be relieved.

  In addition, the protruding portion may have a buffer portion that reduces an impact when contacting the mold at the end portion in the radial direction. Thereby, the impact at the time of a protrusion part contacting a formwork can be relieved.

  Here, the vibrator for concrete compaction according to the present invention is detachably connected to the main body, and is disposed along the longitudinal direction of the mold during concrete compaction, and the joint And a float part connected to the tip side of the part and having buoyancy.

By providing the joint part and the float part, the movement of the main body part in the longitudinal direction of the mold can be suppressed. The float portion only needs to have a specific gravity smaller than that of concrete, and the shape is not particularly limited. The length of the joint portion should be designed based on the length of the mold in the longitudinal direction (for example, the length from the placement hole for inserting the concrete compacting vibrator according to the present invention to the end of the mold). Can do. For example, when a concrete compacting vibrator is used at the position of the placement hole, the length of the joint portion is preferably the length from the end of the mold (the lap side, the wife side) to the placement hole. And two joint parts are prepared, and the movement to the longitudinal direction of the formwork of a main-body part can be suppressed reliably by connecting each to the float part of a lap side and a wife side.

  Here, this invention can also be specified as a concrete compaction method using the vibrator for concrete compaction mentioned above. For example, according to the present invention, the concrete compaction vibrator described above is placed in a mold, the concrete compaction vibrator is vibrated, and the concrete put into the mold is compacted while being gradually wound up. It is a concrete compaction method.

  The concrete compacting vibrator may be wound up by an existing mainspring reel that winds up the vibrator, and may be saved by human power. By using the concrete compaction vibrator according to the present invention, the concrete can be compacted so that the movement of the main body can be suppressed by the protruding portion. Therefore, even when compacting concrete with a small unit amount of water, the conventional floating vibrator Thus, it is possible to easily compact concrete with a small amount of water.

  The concrete compaction vibrator and concrete compaction method described above can be suitably used for tunnel lining construction, in particular, for compacting concrete on the side walls and arches of the tunnel. The side wall portion is a region below the spring line (horizontal line including the center of the arc of the upper half arch portion of the tunnel), and the arch portion is a region above the spring line. Of the arch portion, a region particularly near the top end is referred to as a top end portion (also referred to as a crown portion). The lower part of the arch part includes a lower part of the arch part and an upper part of, for example, a side wall part located below the arch part. Moreover, the lower part of the top end part includes the lower part of the top end part and the upper part of the arch part, for example, which is below the top end part.

  ADVANTAGE OF THE INVENTION According to this invention, the technique regarding the vibrator which can be used for compaction of concrete with little unit water amount and can suppress the movement at the time of concrete placement can be provided.

The structure of the vibrator which concerns on embodiment is shown. The structure of the connection part of the front end side which concerns on embodiment is shown. The structure of the fixing | fixed part which concerns on embodiment is shown. The structure of the connection part which concerns on embodiment is shown. The structure of the protrusion part which concerns on embodiment is shown. The other structure (1) of the protrusion part which concerns on embodiment is shown. The other structure (2) of the protrusion part which concerns on embodiment is shown. The construction sectional view of the tunnel lining which concerns on embodiment is shown. The top view of arrangement | positioning of piping in embodiment is shown. Sectional drawing of arrangement | positioning of piping in embodiment is shown. Sectional drawing of the fixed state of piping in embodiment is shown. The front view of the fixed state of piping in an embodiment is shown. The construction flow of tunnel lining is shown. Sectional drawing of the driving | running | working condition of the downward direction of a side wall part in embodiment is shown. The front view of the driving | running | working condition of the downward direction of a side wall part in embodiment is shown. Sectional drawing of the placement condition from the side wall part to the lower part of an arch part in embodiment is shown. Sectional drawing of the driving | running | working condition of the downward direction of an arch part in embodiment is shown. The top view of the placement situation of the top end part in an embodiment is shown. Sectional drawing of the placement condition of the top end part in embodiment is shown. The placement situation to the inspection window of a top end part in an embodiment is shown. The placement situation from the inspection window of a top end part to predetermined height in an embodiment is shown. The state which has inserted the rod-shaped vibrator from the vibrator insertion hole of a top end part in an embodiment is shown. The opening part of the wife part of a tunnel in embodiment is shown. The casting situation of the upper layer of a top end part in an embodiment is shown. An arrangement sectional view of an insertion hole for a drawing vibrator is shown.

  Next, embodiments of the present invention will be described with reference to the drawings. However, the embodiment described below is an example for carrying out the present invention, and the present invention is not limited to the mode described below. Moreover, although embodiment demonstrates the case where the concrete of slump 12 +/- 2.5cm is used as an example, it is not limited to this.

<Configuration of vibrator for compaction of concrete>
FIG. 1 shows a configuration of a concrete compaction vibrator 101 (hereinafter simply referred to as a vibrator) according to an embodiment. The vibrator 101 includes a cabtyre cable 102 (hereinafter simply referred to as a cable), a main body 103, and a protrusion 104. In FIG. 1, a joint portion 105 and a float portion 106 are further connected to the vibrator 101 according to the embodiment. However, the vibrator 101 may have a simpler configuration that does not include the joint portion 105 and the float portion 106. In FIG. 1, two protrusions 104 are connected, but only one of the protrusions 104 may be connected, or three or more may be connected.

  The cable 102 is connected to a power source (not shown) and supplies power to the vibrating body stored in the main body 103. The cable 102 can be wound up by a mainspring reel 107.

  The main body 103 has a rod shape as a whole and is connected to the tip of the cable 102. The main body 103 is connected to the tip-side connecting portion 108 and the tip-side connecting portion 108 to which the tip-side protrusion 104 is connected, and includes a vibrating portion 109 and a vibrating portion 109 containing a vibrating body (not shown). A deformable hose portion 110 connected to the hose portion 110, and a base end side connection portion 111 connected to the hose portion 110 and having an outer diameter larger than the outer diameter of the hose portion 110. The proximal end side protruding portion 104 is connected to the proximal end side connecting portion 111.

As shown in FIG. 2, the distal end side connecting portion 108 includes a nut 1081 connected to the distal end of the vibrating portion 109 and a bolt 1082 that is screwed into the nut 1081. The shaft portion of the bolt 1082 passes through the through hole of the ring portion 1041 of the protruding portion 104, and the bolt 1082 and the nut 1081 are screwed together with the ring portion 1041 being sandwiched between the nut 1081 and the bolt 1082. Yes. Thereby, the movement of the protrusion part 104 (ring part 1041) to the axial direction of the main-body part 103 is controlled. The inner diameter of the through hole of the ring portion 1041 is slightly larger than the outer diameter of the shaft portion of the bolt 1082. Therefore, the protrusion 104 is rotatable about the axis of the main body 103. The connecting portion 108 on the distal end side may be configured to be able to restrict the movement of the protruding portion 104 in the axial direction of the main body portion 103. For example, the connecting portion 108 on the distal end side may be a simple columnar shape and a fixing portion 112 described later may be used. The connecting portion 108 on the distal end side is provided with, for example, a shaft portion that penetrates the through hole of the ring portion 1041 of the projecting portion 104 on the distal end side of the main body portion 103, and the axial direction of the shaft portion on the distal end side of the shaft portion. You may make it provide the pin which penetrates a axial part in the orthogonal direction. Further, the distal end side connecting portion 108 may be constituted by an annular groove formed in the circumferential direction of the main body portion 103. In this case, the protrusion 104 to be connected needs to be a detachable protrusion 104.

  The vibration unit 109 includes a vibrating body (not shown) and vibrates with electric power supplied through the cable 102. The hose part 110 is made of a softer member than the vibration part 109 and has an outer diameter smaller than the outer diameter of the vibration part 109 and can be deformed. The proximal-side connecting portion 111 has a cylindrical portion 1111 having an outer diameter larger than the outer diameter of the hose portion 110 and a tapered portion 1112 whose diameter gradually decreases toward the cable 102. .

  On the proximal end side of the main body 103, the fixing portion 112 that connects the proximal-side protruding portion 104 includes a first member 1121 and a second member 1122, as shown in FIG. Each of the first member 1121 and the second member 1122 includes a semicircular portion 1123 having an inner diameter substantially the same as the outer diameter of the cylindrical portion 1111, and a plate portion provided at one end of the semicircular portion 1123 and extending in the radial direction. 1124 and a hinge 1125 provided at the other end of the semicircular portion 1123 and rotatably connecting the first member 1121 and the second member 1122. Near the center of the plate portion 1124, a through hole 1126 is provided through which the shaft portion of the fixing member C such as a bolt passes. The 1st member 1121 and the 2nd member 1122 are arrange | positioned in the predetermined | prescribed position around the cylinder part 1111, and it fixes with fixing members C, such as a volt | bolt and a nut, in the state which match | combined each plate part 1124. The predetermined position can be determined based on the concrete placement depth. By fixing the two fixing portions 112 so as to sandwich the protruding portion 104 on the proximal end side, the movement of the protruding portion 104 on the proximal end side in the axial direction of the main body portion 103 can be restricted. The distance between the two fixing portions 112 sandwiching the base-side protruding portion 104 is larger than the thickness of the base-side protruding portion 104 (the thickness of the ring portion 1041) so that the base-side protruding portion 104 can rotate. It is preferable to lengthen the length. An annular groove may be formed in the circumferential direction of the cylindrical portion 1111, and the protruding portion 104 may be provided in this groove. In this case, the protrusion 104 needs to be configured to be removable with respect to the groove.

  The joint portion 105 is configured by an approximately L-shaped member as a whole extending in the longitudinal direction of the mold, and is detachably connected to the column portion 1111 of the main body portion 103. A connection portion 113 is provided on the proximal end side of the joint portion 105. The connection part 113 can be configured to be close to the above-described fixing part 112. That is, the connection part 113 includes a first member 1131 and a second member 1132 as shown in FIG. Each of the first member 1131 and the second member 1132 includes a semicircular portion 1133 having an inner diameter substantially the same as the outer diameter of the cylindrical portion 1111 and a plate portion 1134 provided at one end of the semicircular portion 1123 and extending in the radial direction. And a hinge 1135 provided at the other end of the semicircular portion 1133 and rotatably connecting the first member 1131 and the second member 1132. The plate portion 1134 is provided with one through hole 1136 through which the shaft portion of the fixing member C such as a bolt or nut passes. Further, the joint portion 105 and the connection portion 113 are hinge-coupled by being connected by the fixing member C and the through hole 1136, and the joint portion 105 is connected to the connection portion 113 with the shaft portion of the fixing member C. It can freely rotate as an axis. On the other hand, a plate-like connected portion 1051 is also provided at the base end of the joint portion 105, and one through hole 1052 is provided at a position corresponding to the through hole 1136 of the plate portion 1134. The first member 1131 and the second member 1132 are arranged at predetermined positions around the cylindrical portion 1111, the connected portion 1051 is sandwiched by the plate portion 1134, and is fixed by a fixing member C such as a bolt or a nut. Thereby, the joint part 105 is connected to the vibrator 101. In the present embodiment, the fixing portion 112 described above is further provided on the further proximal side of the joint portion 105, and the connection portion 113 is also sandwiched between the fixing portions 112. Thereby, the movement of the joint part 105 is controlled.

The float part 106 has a specific gravity lighter than concrete and has buoyancy. The float 106 according to the present embodiment is spherical, but the shape is not particularly limited, such as a rugby ball type or a cylindrical type. The float portion 106 is provided with a through hole 1061 through which the tip portion 1053 (bent portion) of the joint portion 105 passes. The float portion 106 is sandwiched between two stoppers 114 having substantially the same configuration as the above-described fixing portion 112 and is fixed to the distal end portion 1053 of the joint portion 105. Note that the position of the float portion 106 can be changed as appropriate by changing the position of the stopper 114.

  The protrusion 104 suppresses the movement of the main body 103 in the mold, particularly the movement in the width direction, during concrete compaction. As shown in FIGS. 1 and 5, the protrusion 104 according to this embodiment includes a ring portion 1041 connected to the main body portion 103 of the vibrator 101, and four rod-shaped rods extending in the radial direction from the center of the ring portion 1041. It includes arm portions 1042 and spherical buffer portions 1043 that are provided at the tips of the respective arm portions 1042 and relieve impact when they come into contact with the formwork. The ring portion 1041 is formed so that its inner diameter is slightly larger than the outer diameter of the main body portion 103. The ring portion 1041 according to the present embodiment has a configuration close to the above-described fixing portion 112, and includes a first ring portion 1041a and a second member 1042b. Both the first ring portion 1041a and the second ring portion 1041b are a semicircular portion 1044 having an inner diameter substantially the same as the outer diameter of the cylindrical portion 1111 and a plate provided at one end of the semicircular portion 1044 and extending in the radial direction. Part 1045, and a hinge 1046 provided at the other end of semicircular part 1044 and rotatably connecting first member 1041 a and second member 1041 b. Thereby, the protrusion part 104 which concerns on this embodiment is freely attachable from the side surface of the vibrator 101. FIG. As shown in FIG. 6, the ring portion 1041 of the protruding portion 104 may be constituted by an annular member without a break. In this case, the protrusion 104 may be inserted from the axial direction (for example, the tip side) of the vibrator 101.

  The arm portion 1042 extends in the radial direction from the center of the ring portion 1041, and four arm portions 1042 are provided in this embodiment. The adjacent arm portions 1042 are arranged at equal intervals, and the angle formed between the arm portion 1042 and the arm portion 1042 in this embodiment is about 90 degrees. The lengths of the arm portions 1042 are the same and are designed based on the interval in the width direction of the mold. That is, the arm portion 1042 can be designed to have a length that allows the protruding portion 104 to be inserted into the mold and to suppress the movement of the protruding portion 104 in the width direction. The number of arm portions 1042 may be three as shown in FIG. 7, or may be five or more.

  A spherical buffer portion 1043 is provided at the tip of the arm portion 1042 to alleviate the impact when it comes into contact with the mold. Although the spherical buffer 1043 of this embodiment is fixed to the tip of the arm 1042, the buffer 1043 may be connected to the arm 1042 so as to be rotatable. Further, the buffer portion 1043 may be a cylindrical member that wraps the tip portion of the arm portion 1042. Further, the buffer portion 1043 may include a rotation shaft orthogonal to the longitudinal direction of the arm portion 1042 at the tip of the arm portion 1042 and a roller that rotates about the rotation shaft.

  In addition, the material of each part which comprises the vibrator 101 which concerns on embodiment mentioned above is not specifically limited. Any of them may have sufficient strength.

<Consolidation method using vibrator for concrete compaction>
Next, a concrete compaction method using the vibrator 101 according to the above-described embodiment will be described. In the following description, tunnel lining work will be described as an example.

(Summary of tunnel configuration)
FIG. 8 shows a construction cross-sectional view of the tunnel lining according to the embodiment. In tunnel lining work, first of all, primary lining is performed in which concrete is sprayed onto the excavation surface (inner wall surface) of a moat tunnel created by excavating natural ground. Thereafter, a secondary lining is performed in which the tunnel excavation surface after the primary lining is further covered with concrete. In this secondary lining, concrete is cast using a formwork called a so-called centle. FIG. 8 is a construction sectional view in the secondary lining according to the embodiment, and more specifically, a construction sectional view in the secondary lining of the concrete horizontal press-fitting method.

  The tunnel 1 in the embodiment has a semicircular cross section. The side wall portion is a region below the spring line (horizontal line including the center of the arc of the upper half arch portion of the tunnel), and the arch portion is a region above the spring line. Of the arch portion, a region particularly near the top end is referred to as a top end portion (also referred to as a crown portion). The tunnel 1 includes a stand 2 as a work table, a vent pipe 7 for ensuring ventilation during work, a pipe 5 through which concrete flows, a pipe switching device 8 for switching pipes, and a pump (not shown) for press-fitting concrete. is set up. In FIG. 8, the pipe 5 is shown only near the connection with each mold.

  On the inner wall surface of the tunnel 1, a mold 3 used for secondary lining is installed. The mold 3 is connected to the mold 31 on the side wall located on the side of the tunnel 1 and the upper part of the mold 31 on the side wall, and is formed on the curved arch located on the arch of the tunnel 1. It is configured by a formwork 33 of a top end portion (generally also referred to as a crown portion) that is connected to an upper portion of a part formwork 32 and is located on the ceiling of the tunnel 1.

  A press-fitting hole 41 in the side wall for press-fitting concrete is provided in the lower part of the mold 31 on the side wall. A hydraulic valve is provided in the press-fitting hole 41 in the side wall, and the pipe 5 can be connected freely. When the pipe 5 is connected to the press-fitting hole 41 in the side wall and the hydraulic valve is opened, concrete is press-fitted into the mold 31 in the side wall. From the press-fitting hole 41 in the side wall part, it is possible to press-fit not only the side wall part but also the concrete below the arch part. Further, a vibrator insertion hole is provided at a position higher than the press-fitting hole 41 in the side wall part, and the concrete inserted from the press-fitting hole 41 in the side wall part is compacted to suppress the occurrence of uneven color in the concrete around the press-fitting hole 41 in the side wall part 61 is provided. At a position higher than the vibrator insertion hole 61 (in the embodiment, the lowest part of the arch portion), an inspection window 62 for compacting the concrete or observing the concrete placement state is provided. Vibrator insertion hole 61 and inspection window 62 are provided with lids that can be freely opened and closed, and are open when compacted or observed, and closed otherwise. The vibrator 101 described above or the existing rod-like vibrator B1 can be inserted into the vibrator insertion hole 61 or the inspection window 62. The vibrator insertion hole 61 is formed to be larger than the diameter of the main body 103 of the vibrator 101, and the vibrator 101 according to the embodiment can be inserted as long as the protrusion 104 is removed. The inspection window 62 has a rectangular shape of about 55 cm × 45 cm, for example, so that the concrete can be compacted or the concrete placement condition can be observed. The vibrator 101 according to the embodiment in which the joint portion 105 and the float portion 106 are removed can be inserted from the inspection window 62. In other words, the vibrator 101 according to the embodiment to which the protruding portion 104 is connected can be inserted as it is. In the embodiment, the vibrator insertion hole 61 and the inspection window 62 are configured separately, but a dual-purpose window portion may be provided. The same applies to the vibrator insertion hole 61 and the inspection window 62 provided in other molds. The press-fitting height from the press-fitting hole 41 in the side wall portion can be set to, for example, 2 m50 cm or more based on the ground surface. In addition, when filling is difficult only by press-fitting concrete from the press-fitting hole 41 in the side wall part, a second press-fitting hole in the side wall part may be provided on the upper part of the mold 31 in the side wall part.

A first press-fitting hole 42 of the arch portion is provided at a position below the arch portion and higher than the inspection window 62. The first press-fitting hole 42 in the arch portion is used for press-fitting concrete into the lower portion of the arch portion, which is difficult to be filled by pressing concrete into the press-fitting hole 41 in the side wall portion. At a position higher than the first press-fitting hole 42 of the arch part, a vibrator is inserted which compacts the concrete press-fitted from the first press-fitting hole 42 of the arch part and suppresses the occurrence of uneven color of the concrete around the first press-fitting hole 42. A hole 61 is provided. Further, an inspection window 62 is provided at a position higher than the vibrator insertion hole 61 for compacting the concrete and observing the concrete placement state. At a position higher than the inspection window, a second press-fitting hole 43 of an arch part for press-fitting concrete is provided. The second press-fitting hole 43 in the arch part is also provided with a hydraulic valve so that the pipe 5 can be connected. Concrete is press-fitted into the mold 32 of the arch part through the second press-fitting hole 43 in the arch part. The From the second press-fitting hole 43 in the arch part, not only the arch part but also a part of the concrete at the top end part can be press-fitted. The press-fitting height from the first press-fitting hole of the arch part can be set to, for example, 2 m50 cm or more with reference to the upper end of the mold 31 of the side wall part. In this case, the second press-fitting hole 43 of the arch part can be provided 30 cm below the height position press-fitted from the first press-fitting hole 42 of the arch part.

  In the upper part of the mold 33 at the top end, two press-in holes 44 at the top end for press-fitting concrete are provided, including a spare. The top end press-fitting hole 44 is also provided with a hydraulic valve so that the pipe 5 can be connected, and the concrete is press-fitted into the top end part mold 33 via the top end press-fitting hole 44. . An existing one can be used as the press-fit hole 44 at the top end, and an existing method can be used for placing from the press-fit hole 44 at the top end. Further, an inspection window 62 is provided in the vicinity of the press-fitting hole 44 at the top end portion to compact the concrete press-fitted from the second press-fitting hole 43 in the arch portion and at the same time observe the concrete placement condition. Note that a vibrator insertion hole 61 is provided in the inspection window 62 at the top end. Moreover, five earth pressure gauges 100 are installed in the mold 33 at the top end portion, and the concrete filling condition and the strength of the mold are managed.

  Here, FIG. 9 shows a plan view of the arrangement of the pipes in the embodiment. FIG. 10 is a cross-sectional view of the arrangement of pipes in the embodiment. As shown in FIGS. 9 and 10, in the embodiment, as the pipe switching device 8, a pipe switching device 4 </ b> P provided on the upstream side and capable of switching the concrete press-fitting destination to four, and downstream of the pipe switching device 4 </ b> P. There is provided a pipe switching device 3P provided on the side and capable of switching the concrete press-fitting destination to three. The pipe switching device 4P switches the press-fitting destination in the longitudinal direction of the tunnel 1. The pipe switching device 3P further switches the press-fitting destination switched by the pipe switching device 4P in the height direction of the tunnel 1. In the embodiment, the three pipes 5 connected to the pipe switching device 3P are connected to the press-fitting hole 41 in the side wall part, the first press-fitting hole 42 in the arch part, and the second press-fitting hole 43 in the arch part, respectively. Yes. A pipe 5 directly connected to a pump (not shown) is connected to the press-fit hole 44 at the top end. The pipe 5 is configured by appropriately combining a straight pipe and an L-shaped pipe. Here, FIG. 11 shows a sectional view of the fixed state of the pipe, and FIG. 12 shows a front view of the fixed state of the pipe. As shown in FIGS. 11 and 12, in the embodiment, the pipe 5 is fixed to the mold 31 on the side wall portion using a wire. The pipe 5 may have a length adjustable, for example, as a double pipe structure. The pipe 5 may be bendable using a bellows-like pipe. The number of switching of the pipe switching device 8 and the combination of the pipes 5 can be appropriately changed according to the shape and diameter of the tunnel 1.

(Tunnel lining method)
Next, the tunnel lining construction method described above will be described. FIG. 13 shows a construction flow of tunnel lining. In the excavation step (S01), a natural ground is excavated. Next, in the concrete spraying step (S02), concrete is sprayed on the excavation surface (inner wall surface) of the moat tunnel formed by excavating the natural ground. The concrete spraying process is a primary lining. When the primary lining is completed, the process proceeds from S03 to S08.

In the secondary lining, first, the mold 3 is assembled in the mold assembling step (S03). In the mold assembly process, the pipe 5 is connected together with the assembly of the mold 3. Next, in the vibrator installation step (S04), the vibrator 101 is installed. When the vibrator 101 according to the above-described embodiment is inserted from the inspection window 62 on the top end side surface portion, the vibrator 101 according to the embodiment to which the protruding portion 104 is connected is inserted. Then, the operator enters the formwork from the end portion of the tunnel and connects the joint portion 105 and the float portion 106 to the inserted vibrator 101. This completes the installation of the vibrator. When using an existing rod-shaped vibrator or the vibrator 10 in which only the protruding portion 104 is connected from the inspection window 62.
When using 1, these vibrators may be inserted after the start of the concrete placing process.

  Next, in the concrete placing step (S05), concrete is placed. Details of the concrete placing process will be described later. When the placement of the concrete is completed, the process proceeds to a vibrator removing step (S06), and the vibrator 101 according to the above-described embodiment or the existing bar-shaped vibrator is removed. In removing the vibrator 101 according to the embodiment, the operator separates the vibrator 101, the protruding portion 104, and the joint portion 105 through the inspection window 62 on the top end side surface portion, and takes them out from the inspection window 62 on the top end side surface portion. Thereafter, when the curing of the concrete is completed, the process proceeds to a mold form dismantling process (S07), and the mold form is dismantled in the mold form dismantling process. Next, it progresses to a concrete curing process (S08), and concrete is hardened for a fixed period. Curing of the concrete can be performed by suspending a lightweight framework on the formwork 33 at the top end, sealing the framework with a sheet to form a movable parasol, and filling the mist with the parasol. Further, in concrete curing, in order to suppress drying shrinkage cracking due to ventilation after passing through the tunnel, a balloon that partitions the inside of the tunnel may be installed at the center of the tunnel to maintain the humidity in the tunnel 1. The tunnel 1 is formed by sequentially repeating the above steps in the longitudinal direction of the tunnel 1.

(Details of concrete placing process)
When placing concrete, first, an installation process of the vibrator 101 is performed. That is, the vibrator 101 according to the embodiment is appropriately inserted into the side wall portion from the inspection window 62 on the top end side surface portion, and the existing rod-shaped vibrator is inserted from the inspection window 62 on the side wall portion. When the installation of the vibrator 101 or the existing rod-shaped vibrator is completed, concrete placement is started. Specifically, concrete is first press-fitted into the mold 31 of the side wall through the press-fitting hole 41 of the side wall. FIG. 14 shows a cross-sectional view of the side wall portion in the embodiment. FIG. 15: shows the side view of the placement condition of the side wall part in embodiment. FIG. 16 is a cross-sectional view of a driving situation from the side wall portion to the lower portion of the arch portion in the embodiment. The concrete is continuously press-fitted from the press-fitting hole 41 in the side wall, so that the filling of the concrete in the mold 31 in the side wall proceeds from the lower part to the upper part. Embodiment in which the concrete is press-fitted from the press-fitting hole 41 in the side wall portion, and the concrete inserted into the mold 31 in the side wall portion is inserted from the inspection window 62 in the top end side portion until the concrete reaches the inspection window 62 in the side wall portion. Concrete from the vicinity of the press-fitting hole 41 in the side wall portion to the vicinity of the inspection window 62 in the side wall portion is compacted by the vibrator 101 and the existing bar-shaped vibrator B1 inserted from the inspection window 62 in the side wall portion. The vibrator 101 according to the embodiment may be wound by the mainspring reel 107 or by human power. 14 and 15 show the operating status of the vibrator 101 according to the embodiment and the existing rod-shaped vibrator B1. As shown in FIGS. 14 and 15, the joint portion 105 and the float portion 106 suppress the movement of the main body portion 103 in the longitudinal direction of the mold. Thereby, for example, two vibrators can be operated by two people, for example, and labor-saving work is reduced by labor saving.

  When the concrete reaches the inspection window 62 on the side wall, the vibrator 101 according to the embodiment is continuously operated, the existing bar-shaped vibrator B1 is taken out from the inspection window 62, the inspection window 62 is closed, and then the side wall is continued. Concrete is press-fitted from the press-fitting hole 41. When the concrete is press-fitted, a vibrator installation process is performed as necessary. When the concrete reaches the vicinity of the first press-fitting hole 42 in the arch part, the pipe switching device 3P is switched, and then concrete is press-fitted from the first press-fitting hole 42 in the arch part. At this time, the periphery of the press-fitting hole 41 in the side wall portion is compacted by the rod-shaped vibrator B1 inserted into the vibrator insertion hole 61 in the side wall portion. The concrete placement time is preferably within 2 hours. If there is no color unevenness near the press-fitting hole 41 in the side wall, the compaction by the vibrator insertion hole 61 in the side wall may be omitted.

  Next, concrete in the arch part is placed. Specifically, as shown in FIG. 17, the concrete is press-fitted again from the first press-fitting hole 42 of the arch part, and the concrete is filled into the mold 32 of the arch part. The concrete is continuously press-fitted from the first press-fitting hole 42 of the arch part, so that the filling of the concrete in the mold 32 of the arch part proceeds from the lower part toward the upper part. When the concrete is press-fitted from the first press-fitting hole 42 of the arch part, the concrete press-fitted into the mold 32 of the arch part is inserted from the inspection window 62 of the top end side part until reaching the inspection window 62 of the arch part. Concrete from the vicinity of the first press-fitting hole 42 in the arch portion to the vicinity of the inspection window 62 in the arch portion is compacted by the vibrator 101 according to the embodiment or the existing rod-shaped vibrator B1.

  When the concrete reaches the inspection window 62 of the arch portion, the vibrator 101 according to the embodiment is continuously operated, the existing bar-shaped vibrator B1 is taken out, and the inspection window 62 is closed. Furthermore, concrete is press-fitted from the first press-fitting hole 42 of the arch portion. When the concrete reaches the vicinity of the second press-fit hole 43 in the arch portion, the pipe switching device 3P is switched, and the concrete is press-fit from the second press-fit hole 43 in the arch portion. The second press-fitting hole 43 of the arch part is provided 30 cm below the upper end of the mold 32 of the arch part, and the concrete is press-fitted from the second press-fitting hole 43 of the arch part. This is performed until the inspection window 62 (see FIG. 18) on the side surface of the top end located at the position is reached. At this time, the vibrator 101 according to the embodiment is taken out. The existing bar-shaped vibrator B1 inserted through the vibrator insertion hole 61 in the arch portion compacts the periphery of the first press-fit hole 42 in the arch portion. If there is no color unevenness in the vicinity of the first press-fitting hole 42 in the arch part, compaction by the vibrator insertion hole 61 in the arch part may be omitted.

  Next, the top concrete is cast. FIG. 18 shows a plan view of a top end placing condition in the embodiment. FIG. 19 shows a cross-sectional view of the top end placement state in the embodiment. Moreover, FIG. 20 shows the driving | running | working condition to the inspection window of a top edge part in embodiment. FIG. 20A is a perspective view of a placement situation up to the inspection window at the top end portion, and FIG. 20B is a cross-sectional view of a placement situation up to the inspection window 62 at the top end portion. Concrete is pressed again from the second press-fitting hole 43 in the arch portion, and the filling of the concrete in the mold 33 at the top end portion proceeds from the lower portion toward the upper portion. When the concrete is press-fitted from the second press-fitting hole 43 of the arch, the concrete press-fitted into the mold 33 at the top end reaches the press-in hole 44 at the top end and the inspection window 62 at the top end. The concrete is compacted by the existing rod-shaped vibrator B1 inserted from the inspection window 62 at the end. Specifically, the inspection window 62 at the top end is opened, and concrete is compacted from the inspection window 62 by the existing bar-shaped vibrator B1. Hereinafter, the layer up to the inspection window at the top end is also referred to as a lower layer.

Next, the inspection window 62 at the top end of the existing bar-shaped vibrator B1 is taken out, and the inspection window 62 is closed. Furthermore, concrete is press-fitted from the second press-fitting hole 43 in the arch portion. FIG. 21 shows a driving situation from the inspection window 62 at the top end to a predetermined height in the embodiment. FIG. 21A is a perspective view of a placement situation from the inspection window at the top end to a predetermined height, and FIG. 21B is a cross-sectional view of the placement situation from the inspection window at the ceiling end to a predetermined height. Indicates. In the embodiment, by pressing the concrete through the second press-fitting hole 43 in the arch portion, the concrete is further placed from the inspection window 62 at the top end portion to 20 cm. Hereinafter, a layer from the inspection window 62 at the top end to a predetermined height (20 cm) is also referred to as a middle layer. A layer above the middle layer is referred to as an upper layer. At that time, as shown in FIG. 22, the existing rod-like vibrator B1 is inserted from the vibrator insertion hole 61 at the top end portion, and the concrete placed in the middle layer is compacted. In addition, it is good to provide the opening part for confirming the placement condition in the wife part of the tunnel 1 by lowering the formwork 33 of the top end part near the apex of the top end part. FIG. 23 shows the opening 66 of the wife of the tunnel in the embodiment. As shown in FIG. 23, it is possible to confirm the placement situation by providing the opening 33 at the end of the tunnel. The opening 33 is provided with a detachable lid (face plate) or an openable / closable lid (face plate), and the opening 66 is closed after completion of placing the middle-layer concrete. Further, the valve of the second placement hole 43 in the arch portion is closed, and the periphery of the second placement hole 43 in the arch portion is compacted by the existing rod-like vibrator B1 inserted from the vibrator insertion hole 61 in the arch portion.

  Next, the pipe switching device 4P is switched, and concrete is press-fitted from the press-fit hole 44 at the top end. FIG. 24 shows a situation of placing the upper layer of the top end in the embodiment. FIG. 24 (a) is a perspective view of the upper layer placement situation of the top end portion, and FIG. 24 (b) is a cross-sectional view of the upper placement situation of the top end portion. In the embodiment, concrete is press-fitted from the press-fitting hole 44 at the top end, and the concrete is cast only in the upper layer of the top end (an area higher than the height of 20 cm from the inspection window). At that time, as shown in FIG. 24A, the concrete placed in the upper layer of the top end portion is compacted by the existing rod-shaped vibrator B1 inserted from the vibrator insertion hole 61 of the top end portion. Is called. When the filling pressure from the top end press-fitting hole 44 exceeds a limit value (for example, 120 kPa), concrete may be placed from the spare press-fitting hole 44. The filling pressure can be measured with a earth pressure gauge installed in the mold 33 at the top end.

  Next, compaction by the existing drawing vibrator B2 is performed. FIG. 25 is an arrangement cross-sectional view of the insertion hole 65 for the drawing vibrator. In the embodiment, two insertion holes 65 are provided at the boundary between the lower layer and the middle layer, and two at the boundary between the middle layer and the upper layer. The existing drawing vibrator B2 is inserted in the mold in advance, and after completion of placing concrete, compaction is performed while pulling out. Drawing is realized when a take-up reel (not shown) connected to the base end of the pull-out vibrator B2 winds the pull-out vibrator B2.

(effect)
According to the vibrator according to the embodiment described above, the main body 103 is provided with the protruding portion 104, thereby suppressing the movement of the main body 103 in the mold, particularly the movement of the mold in the width direction. Further, when compacting concrete with a small amount of unit water, the conventional floating vibrator requires additional weight to suppress movement. On the other hand, in the vibrator 101 according to the embodiment, since the movement of the main body portion 103 can be suppressed by the protruding portion 104, it is not necessary to provide a weight like a conventional floating vibrator even when concrete with a small amount of unit water is compacted. . Therefore, it is possible to easily compact concrete with a small amount of water. Moreover, since the protrusion part 104 is provided in two places, a movement can be suppressed more effectively than the case where the protrusion part 104 is provided in one place. Moreover, since the protrusion part 104 is detachably connected with respect to the main-body part 103, it is excellent also in convenience. Further, the protruding portion 104 is rotatable about the main body portion 103 as an axis, and can reduce an impact when the protruding portion 104 contacts the mold. Moreover, when the joint part 105 and the float part 106 are provided, the movement of the main-body part 103 to the longitudinal direction of a formwork can be suppressed.

<Modification of Embodiment>
In the embodiment, the concrete placement of the side wall portion, the arch portion, and the top end portion is performed by press fitting. However, at least any one of the side wall portion, the arch portion, and the top end concrete placement may be placed under natural flow according to a conventional standard construction method. Moreover, the vibrator 101 according to the embodiment can be used as appropriate for compacting concrete other than tunnel lining.

  As mentioned above, although preferred embodiment of this invention was described, the vibrator for concrete compaction and the concrete compaction method which concern on this invention are not restricted to these, These combinations can be included as much as possible.

DESCRIPTION OF SYMBOLS 1 ... Tunnel 2 ... Mount 3 ... Formwork 5 ... Pipe 31 ... Formwork 32 of side wall part ... Formwork 33 of arch part ... Formwork 41 of top end part , 42, 43, 44 ... press-fitting hole 61 ... vibrator insertion hole 62 ... inspection window 101 ... vibrator 102 ... cable 103 ... main body 104 ... projection 105 ... Fitting part 106 ... Float part 107 ... Spring-type reel

Claims (6)

A concrete compacting vibrator having a vibrator that vibrates at a predetermined frequency,
A rod-shaped main body containing the vibrating body;
Protrusions projecting radially from the center of the main body, and suppressing the movement of the main body within the formwork during concrete compaction,
A concrete compaction vibrator comprising:   2. The concrete compacting vibrator according to claim 1, wherein the protruding portion has a plurality of rod-shaped arm portions extending radially from the center of the main body portion in the radial direction.   3. The concrete compaction vibrator according to claim 1, wherein the protrusions are provided at at least two locations, a lower portion of the main body portion and a predetermined position above the lower portion.   The vibrator for concrete compaction according to any one of claims 1 to 3, wherein the protruding portion has a buffer portion at a radial end portion that reduces a shock when the protruding portion comes into contact with the formwork. A rod-shaped joint portion that is detachably connected to the main body portion and is disposed along the longitudinal direction of the mold when compacting the concrete,
A float part connected to the distal end side of the joint part and having buoyancy;
The vibrator for concrete compaction according to any one of claims 1 to 4, further comprising: A concrete compaction method using the concrete compaction vibrator according to any one of claims 1 to 5,
A concrete compaction method in which the concrete compacting vibrator is disposed in a mold, the concrete compacting vibrator is vibrated, and the concrete put into the mold is compacted while being gradually wound up.

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