JP4536044B2 - Tunnel lining method - Google Patents

Description

  The present invention relates to a tunnel lining method performed using a centle.

  Conventionally, as a tunnel lining method, a centle (movable formwork made of steel that can be folded) that is movably installed in an excavated tunnel is used, and lining concrete is formed in the gap between the inner wall surface of the tunnel and the centle. , And after placing the lining concrete, move the centle to a location adjacent to the placement location of the lining concrete, and place the lining concrete in the gap between the tunnel inner wall surface and the centle. There is known a method of repeating the placement (see, for example, Patent Document 1).

  By the way, if the centle is moved in a state where curing curing of the laid concrete is insufficient, the lining concrete will be destroyed, so the movement of the centle has the required strength so that the lining concrete will not collapse. It is necessary to wait until the state is cured. Here, the time required for the placed lining concrete to harden to such a state (curing time) varies depending on the ambient temperature, the amount of moisture in the concrete at the time of placing, and the like. Therefore, conventionally, a time obtained by multiplying a normal curing time by a predetermined safety factor is set as a standby time, and when this standby time has elapsed since the laying concrete has been placed, the movement of the centle is started. ing.

The actual setting time of the laid concrete is usually shorter than the waiting time set as described above, and the start of movement of the centle is unnecessarily delayed by the time difference between the waiting time and the actual setting time. . The number of movements of the centle in the construction of the lining concrete over the entire length of the tunnel is great, and an unnecessary delay in the start of the movement of the centle becomes a serious problem for shortening the construction period.
JP 2001-123794 A

  In view of the above, the present invention starts a moving operation of the centle without delay when the placed lining concrete is cured to a state having a required strength, and can shorten the work period. The problem is to provide a lining method.

  In order to solve the above-mentioned problems, the present invention uses a centle that is movably installed in an excavated tunnel, and places lining concrete in a gap between the tunnel inner wall surface and the centle, At a predetermined time after placing concrete, move the centle to a place adjacent to the place where the lining concrete is placed, and place the lining concrete in the gap between the tunnel inner wall surface and the center. In the tunnel lining method that repeats the above, with the moving direction of the centle as the front, a projection that bulges forward is provided on the faceplate that closes the front end surface of the gap between the inner wall surface of the tunnel and the centle. A portion of the concrete cast in the gap between the tunnel inner wall surface and the centle is allowed to flow to form a judgment concrete part, and the strength of the judgment concrete part is measured. When the intensity is equal to or higher than a predetermined reference value, characterized in that to start moving work Sentoru as the predetermined timing.

  According to the present invention, the judgment concrete portion is projected forward from the front end of the centle by the convex portion bulging forward provided on the end plate closing the front end surface of the gap between the tunnel inner wall surface and the centle. Is formed. Therefore, the strength of the judgment concrete part can be measured without being disturbed by the centle. And since the judgment concrete part is integrally continued to the lining concrete cast in the gap between the inner wall surface of the tunnel and the centle, the strength of the judgment concrete part substantially matches the strength of the lining concrete. Therefore, by measuring the strength of the judgment concrete portion, it is possible to know the strength of the lining concrete that is disturbed by the centle and cannot be directly measured. And if the above standard value is set according to the required strength that does not cause collapse of the lining concrete, the movement of the centle starts without delay when the placed lining concrete is cured to have this strength. can do. This makes it possible to shorten the construction period of the lining work over the entire length of the tunnel as much as possible.

  By the way, it is conceivable to separate the judgment concrete part from the lining concrete and measure the strength of the judgment concrete part with a compression tester, but it is difficult to bring the compression tester into the tunnel, Not suitable for strength measurements at Further, even if a compression tester is brought in, a plurality of test pieces for compression test (in many cases, 3 × 3 to 5 sets) must be prepared, and labor is required for preparation and shaping. Therefore, it is desirable that the strength measurement of the judgment concrete part is performed in a nondestructive test without separating the judgment concrete part from the lining concrete.

  In the nondestructive test, an ultrasonic transmitter and a receiver are set on one and the other of the opposing surfaces of the judgment concrete part, and the ultrasonic transmission time between the ultrasonic transmitter and the receiver is determined. It is desirable to measure the elastic wave velocity of the judgment concrete part. There is a close correlation between the elastic wave velocity of concrete and its strength, and the elastic wave velocity is a parameter representing strength. Although it is possible to hit the judgment concrete part and measure the elastic wave velocity, this requires a special striking device, and if the strength of the concrete is low, the striking point is in the concrete. There is a possibility that accurate determination may be difficult due to intrusion, and it is advantageous in terms of cost and accuracy to measure the elastic wave velocity with ultrasonic waves.

  Referring to FIG. 1, reference numeral 1 denotes a centle installed in a tunnel T excavated. The center 1 is a foldable steel movable formwork, a frame 3 that runs on a rail 2 laid in the tunnel T, an upper panel 4 shaped along the upper half of the tunnel T, and an upper panel 4 is provided with a pair of lower panels 6 and 6 each having a shape along the lower half of the tunnel T, which are connected to both sides of the tunnel 4 via hinges 5. The upper panel 4 is supported on the mount 3 via a jack 7 so as to be movable up and down. Each lower panel 6 is swung in the lateral direction with a hinge portion 5 as a fulcrum by a jack 8 installed between the lower panel 6 and the gantry 3. Thus, the centle 1 can be deformed into the unfolded state shown in FIG. 1 and the folded state in which each lower panel 6 is swung inward in the lateral direction and the upper panel 4 is lowered.

  When lining the tunnel T, lining concrete for secondary lining is placed in the gap between the inner wall Ta of the tunnel T and the centle 1 that was primarily covered with steel support or mortar. To do. Thereafter, the centle 1 is moved to the next placement location adjacent to the placement location of the lining concrete this time, and the lining concrete C is placed in the gap between the tunnel inner wall surface Ta and the centle 1 at the location. To do. The lining concrete is constructed over the entire length of the tunnel T by repeating the above operations.

  In addition, when moving the centle 1, first, the centle 1 is folded and demolded from the lining concrete, the centle 1 is moved to the next placement site, and then the centle 1 is returned to the unfolded state. Further, with the direction of movement of the centle 1 as the front, the movement position of the centle 1, as shown in FIG. 2, is such that the rear end 1R of the centle 1 is located behind the front end of the lining concrete C ′ previously placed. It is set so that the rear end side portion of 1 and the front end side portion of the lining concrete C ′ previously placed overlap. In addition, after the movement of the center 1, the front end surface of the gap between the tunnel inner wall surface Ta and the center 1 is closed with the end plate 9, and the concrete conveying pipe is opened from the openable window hole formed at a proper position of the center 1 in the gap. Insert and lay concrete lining C. In FIG. 2, the gantry 3 is omitted.

Here, after placing the lining concrete C, in order to prevent the lining concrete C from collapsing when the centle 1 is demolded, the lining concrete C has a required strength (generally 2N). It is necessary to wait for the centle 1 at this placement site until it is cured to a state having a compressive strength of about / mm ² . However, the time (curing time) required for the placed lining concrete C to harden to a state having such strength varies depending on various conditions such as the ambient temperature and the amount of moisture in the concrete at the time of placing. . Accordingly, when the moving operation of the centle 1 is started when a predetermined waiting time has elapsed from the completion of the placement of the lining concrete C, the waiting time is set to a longer time obtained by multiplying the normal curing time by the safety factor. This makes it difficult to shorten the construction period.

Therefore, in the present embodiment, the strength of the lining concrete C can be measured, and when the strength becomes a predetermined strength reference value (for example, 2 N / mm ² ) or more, the movement operation of the centle 1 is started. I have to. Hereinafter, this point will be described in detail.

  As shown in FIGS. 2 and 3, a plurality (three in the illustrated example) of convex portions 10 bulging forward are provided on the top of the end plate 9. The inside of the convex portion 10 is a cavity that communicates with the gap between the tunnel inner wall surface Ta and the center 1. An air vent hole 10 a is formed on the upper surface of the convex portion 10. The air vent hole 10a also has a function of removing water (bleeding water) that separates from the concrete during placement. Accordingly, a part of the concrete cast in the gap between the tunnel inner wall surface Ta and the centle 1 flows into the convex portion 10, and the judgment concrete portion 11 integrally connected to the lining concrete C is in the convex portion 10. Formed.

  Then, when a predetermined waiting time set several hours shorter than the normal curing time has elapsed from the completion of placing the lining concrete C, the convex portion 10 is disassembled and the strength measurement of the judgment concrete portion 11 is started. Here, since the judgment concrete part 11 protrudes forward from the front end of the centle 1, the strength of the judgment concrete part 11 can be measured without being disturbed by the centle 1. Further, since the judgment concrete portion 11 is integrally continuous with the lining concrete C, the strength of the judgment concrete portion 11 substantially matches the strength of the lining concrete C. Therefore, by measuring the strength of the judgment concrete part 11, it is possible to indirectly know the strength of the lining concrete part C that is disturbed by the centle 1 and cannot be measured.

  The strength measurement of the judgment concrete part 11 is repeated in a nondestructive test without separating the judgment concrete part 11 from the lining concrete C. More specifically, as shown in FIG. 4, the ultrasonic transmitter 12 and the receiver 13 are set on one and the other of the opposing surfaces of the determination concrete portion 11. Then, the elastic wave velocity of the determination concrete portion 11 is obtained by dividing the width between the opposing surfaces of the determination concrete portion 11 by the ultrasonic transmission time between the ultrasonic transmitter 12 and the receiver 13.

  There is a correlation shown in FIG. 5 between the compressive strength of concrete and the elastic wave velocity. However, this correlation varies depending on the type of aggregate in the concrete, the blending ratio, etc., even at the same compressive strength. Therefore, a relational expression between the compressive strength and elastic wave velocity of concrete is obtained by a preliminary test with the kind of aggregate actually used in the field and the mixing ratio, and based on this relational expression, the above strength reference value is obtained. Determine the reference value for the corresponding elastic wave velocity. Then, the measurement is repeated until the elastic wave velocity reaches the reference value, and when the elastic wave velocity of all the judgment concrete parts 11 reaches the reference value, the fact is notified, and the movement work of the centle 1 is started. According to this, when the placed lining concrete C is hardened in a state having the above strength reference value, the moving operation of the centle 1 can be started without delay, and the construction period can be shortened as much as possible. It becomes possible.

  If the next lining concrete is placed with the judgment concrete portion 11 left, there is a possibility that a concrete filling failure may occur around the judgment concrete portion 11. Therefore, the judgment concrete portion 11 is cut and removed at the time of dismantling the end plate 9 prior to the movement of the centle 1.

  As mentioned above, although embodiment of this invention was described with reference to drawings, this invention is not limited to this. For example, in the above embodiment, the three projections 10 are provided on the top of the end plate 9, but the number and positions of the projections 10 are not limited thereto. However, the lining concrete C is sequentially placed upward from the lower part of the gap between the tunnel inner wall surface Ta and the centle 1, and it takes a considerable time from the start of placing the lower part to the completion of placing the upper part. Cost. Therefore, when the convex part 10 is provided in the lower part of the end plate 9, the strength of the judgment concrete part 11 formed in the convex part 10 and the strength of the upper part of the lining concrete C to be finally placed There is a considerable difference between them. On the other hand, if the convex part 10 is provided on the upper part of the end plate 9, the strength of the judgment concrete part 11 and the strength of the upper part of the lining concrete C become substantially equal, and the movement start time of the centle 1 can be grasped more accurately. Can do. In addition, it is better in accuracy to provide a plurality of convex portions 10. Therefore, it is desirable to provide a plurality of convex portions 10 on the top of the end plate 9 as in the above embodiment.

  Moreover, in the said embodiment, although the elastic wave velocity of the concrete part 11 for determination is measured using an ultrasonic wave, it is also possible to measure the elastic wave velocity by hit | damaging the concrete part 11 for determination. However, in this case, a special striking device is required, and if the strength of the judgment concrete portion 11 is low, the hitting portion may be sunk into the judgment concrete portion 11 and it may be difficult to make a precise judgment. There is. Therefore, the above embodiment using ultrasonic waves is more advantageous in terms of cost and accuracy.

The schematic front view of the centle used for implementation of this invention. The perspective view which shows the placement state of the lining concrete in embodiment of this invention. Sectional drawing of the convex part cut | disconnected by the III-III line of FIG. The perspective view which shows the set state of the ultrasonic transmitter and receiver with respect to the concrete part for determination. The graph which shows the relationship between the intensity | strength of concrete, and an elastic wave velocity.

Explanation of symbols

  T ... tunnel, Ta ... inner wall surface of tunnel, C ... lining concrete, 1 ... centle, 9 ... twill plate, 10 ... convex part, 11 ... concrete part for judgment, 12 ... ultrasonic transmitter, 13 ... receiver.

Claims (3)

Using a centle that is movably installed in the excavated tunnel, lining concrete is placed in the gap between the tunnel inner wall surface and the centle, and this covering is performed at a predetermined time after placing the lining concrete. In the tunnel lining method in which the centr is moved to a place adjacent to the place where the concrete is placed and the lining concrete is placed in the gap between the tunnel inner wall surface and the centle at the place,
Protruding parts that bulge forward are provided on the end plate that closes the front end face of the gap between the inner wall surface of the tunnel and the centle with the moving direction of the centle as the front, and the gap between the inner wall surface of the tunnel and the centle is provided in the protruding portion. A part of the concrete placed in is poured in to form a concrete part for judgment,
A tunnel lining method characterized in that the strength of the concrete part for judgment is measured, and the movement of the centle is started at the predetermined time when the strength exceeds a predetermined reference value.   The tunnel lining method according to claim 1, wherein the strength measurement of the judgment concrete part is performed in a nondestructive test without separating the judgment concrete part from the lining concrete.   In the non-destructive test, an ultrasonic transmitter and a receiver are set on one and the other of the opposing surfaces of the judgment concrete part, and the ultrasonic transmission time between the ultrasonic transmitter and the receiver is determined. The tunnel lining method according to claim 2, wherein the elastic wave velocity of the judgment concrete part is measured.

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