JPH0830345B2 - Underground beam displacement absorption structure and its construction method - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an underground beam displacement absorbing structure having a displacement absorbing measure and a vibration absorbing measure, and a construction method thereof.

[0002]

2. Description of the Related Art Conventionally, it has been known to provide a rigid urethane foam on a wall surface of a subway tunnel in order to prevent a subway vibration from spreading to the ground. Further, it is known to lay urethane elastomer under the track in order to prevent vibration of the railway track from being transmitted to the ground. It is known that urethane elastomer is suitable as a vibration-proof material (for example, JP-A-61-13631).
(See Japanese Patent Publication No. 5). However, regarding the underground girders that support the piers of expressways, the underground girders are displaced significantly as the traffic volume increases and decreases. In order to absorb the displacement, the underground beam has a flexible structure, but no measures to absorb the displacement have been taken.

[0003]

<I> Problems to be Solved by the Invention <B> In addition to minute vibrations caused by running of a vehicle on a highway, the underground beams are largely displaced as the traffic volume increases and decreases. If the displacement of the underground beam is, for example, 10 mm, the pavement surface on the underground beam may be damaged. <B> This displacement also affects the ground on the side surface of the underground beam.
A fault slip occurs on the ground above the underground beam and the adjacent ground, resulting in a step at the boundary between these grounds. <C> In the urethane injection method, the thickness that can be applied at one time is 20 times in the injection method in order to prevent heat storage ignition and scorching (burning, carbonization phenomenon) due to the urethane curing reaction.
It is 0 mm. For work requiring more thickness, it is necessary to wait for cooling or heat dissipation of the urethane reaction heat after the completion of one work, and then perform the second and third work. Therefore, it takes a long construction period.

[0004]

SUMMARY OF THE INVENTION It is an object of the present invention to provide an underground beam displacement absorbing structure and a construction method thereof, which reduce vibrations and reduce the influence of the displacement of the underground beam on the ground. Another object of the present invention is to provide a method capable of easily constructing a displacement absorber for an underground beam.

[0005]

DISCLOSURE OF THE INVENTION The present invention is capable of vertical displacement.
Underground girder displacement absorption structure
Urethane elastomer layer on the top, bottom and side of the middle part
Forming one of the rigid urethane foam layers
Of the underground beam displacement absorbing structure or the underground beam
A urethane elastomer layer is formed on the upper surface of the
It is special to form a rigid urethane foam layer on the surface and the side surface.
Underground beam displacement absorption structure or underground of the underground beam
Rigid urethane foam with a space on the bottom and side of the part
Place a slab of
Inject to form hard urethane foam layer,
Adhesion or injection of tan elastomer and urethane elastomer
Underground beam displacement absorption structure characterized by forming a mer layer
Construction method of the structure, or underground girder change
Under the underground portion of the underground beam in the construction method of
Rigid urethane foam with a space on the surface and part of the side surface
Place a slab of
Inject to form hard urethane foam layer, bottom and side
Hard by spraying hard urethane foam on the other part of the surface
A urethane foam layer is formed and urethane elastomer is applied on the top surface.
Adhesion or injection of mer to form urethane elastomer layer
Construction method of underground beam displacement absorption structure, characterized by
It is in.

[0006]

Embodiments will be described below with reference to the drawings. 1 and 2 are views showing the structure of an underground beam which is an embodiment of the present invention. <A> Underground beam 1 An underground beam 1 is provided in the ground to support a pier 5 such as an expressway. A body-wrapped concrete 6 and a foundation 7 for further fixing the underground beam 1 are constructed on both sides of the underground beam 1. A road 10 runs on the upper surface of the underground beam 1. Further, the underground beam 1 is provided so as to straddle underground structures such as the common ditch 8 and the subway 9. The distance between the underground girder 1 and the road surface varies depending on the purpose of use of the underground girder and site conditions, but is, for example, 400 mm to 8000 mm. 2 is a cross-sectional view taken along the alternate long and short dash line QQ in FIG. An underground beam 1 is provided at the upper end of the common groove 8 and about 400 mm above it.
There is a road surface, and a road 10 is running. Underground beam 1
Is vibrated by the traveling of the vehicle on the highway and is displaced by the degree of congestion of the vehicle on the highway. In addition, a vehicle on a road surface above the underground beam 1 also vibrates,
Subject to displacement. Furthermore, it is also affected by vibrations in the subway. FIG. 3 is another example of the underground beam.

<B> Displacement Absorbing Material 2 for Underside Beam of Underground Beam The displacement absorbing material 2 is provided on the underside of the underground beam 1. FIG. 4 shows the difference in ground displacement between the case where the displacement absorbing material 2 is provided on the lower surface of the underground beam and the case where it is not provided. When the displacement absorbing material is not provided (B), the ground in contact with the underground beam is also displaced. On the other hand, in the case where the displacement absorbing material is provided (C), the absorbing material absorbs the displacement of the underground beam and the ground is not displaced. As a result, the lower surface displacement absorbing material 2 prevents fluctuation of the ground below,
It is possible to prevent the formation of a gap between the underground beam and the ground below.
At the same time, various vibrations can be absorbed. Further, it is possible to absorb the slip / displacement between the underground beam 1 and the ground on the lower surface. A urethane elastomer or a hard urethane foam layer is used as the lower surface displacement absorbing material 2. The urethane elastomer layer has a thickness of about 95 mm as an example, and the hard urethane foam layer 2
Has a thickness of about 450 mm. As the lower surface displacement absorbing material 2, urethane elastomer has excellent impact resistance, but when the traffic impact does not directly occur, inexpensive rigid urethane foam is used.

<C> Side Displacement Absorbing Material 3 of Underground Beam The displacement absorbing material 3 is also provided on the side surface of the underground beam. FIG. 5 shows the difference in the ground displacement between the case where the displacement absorbing material is provided on the side surface of the underground beam and the case where it is not provided. In the case where the displacement absorbing material is not provided (B), fault slip occurs at the boundary between the underground beam and the displacement absorbing material. On the other hand, when a displacement absorbing material is provided (C)
In the case, the lateral displacement absorbing material 3 serves as a relaxation zone to prevent the fault slip at the boundary. At the same time, it absorbs displacement from and to the side surface. Also, vibration can be absorbed. A urethane elastomer or a hard urethane foam layer is used as the lateral displacement absorbing material 3. As an example, the urethane elastomer layer has a thickness of about 95 mm, and the rigid urethane foam layer has a thickness of about 450 mm. Further, if a urethane elastomer is used in the upper part of the hard urethane foam layer, a preferable structure is obtained in terms of impact resistance.

<D> Top Displacement Absorber 4 of Underground Beam The top displacement absorber 4 is also provided on the top surface of the underground beam. FIG. 4 shows the difference in ground displacement between the case where the displacement absorber 4 is provided on the upper surface of the underground beam and the case where it is not provided. When the displacement absorber is not provided (B), the upper ground of the underground beam and the road surface are also displaced. On the other hand, in the case where the displacement absorbing material is provided (C), the absorbing material absorbs the displacement of the underground beam and the ground is not displaced. As a result, the upward displacement absorbing material 4 can prevent the ground from changing and prevent the road surface from breaking. At the same time, it absorbs vibrations from and to the top surface. Also, the slip / displacement between the underground beam 1 and the ground on the upper surface can be absorbed. A urethane elastomer layer or a hard urethane foam layer is provided as the upper surface displacement absorbing material 4. As an example, the thickness of the urethane elastomer layer is about 95 mm, and the thickness of the rigid urethane foam layer is about 450 mm. On this top surface,
In the case of the depth to which the impact of wheel load is directly applied, the urethane elastomer layer is preferable from the viewpoint of impact resistance.

Table 1 shows the functions of urethane elastomer, hard urethane, rubber, polystyrene and polyethylene as the displacement absorbing / vibrating material. Here, it is known that the urethane elastomer and the rigid urethane foam are excellent. In particular, urethane elastomer has a displacement absorption capability,
Excellent impact resistance and heavy load resistance.

[Table 1]

The characteristics of the rigid urethane foam and the urethane elastomer will be described below. <A> Hard Urethane Foam As the hard urethane foam used in this example, for example, an apparent specific gravity of 0.03 is used.
The rigid urethane foam has the following main features. Apparent specific gravity is 0.02-0.15, preferably 0.03-0.10
Is. At the elastic limit, the compressive stress is 0.1 to 20 kgf /
cm ² , preferably 0.8 to 10 kgf / cm ² . The compression rate is 1 to 15%, preferably 3 to 10%.

<B> Compression Characteristics of Rigid Urethane Foam FIG. 6 shows rigid urethane foam (apparent specific gravity 0.03).
An example of the compression characteristics of is shown. The characteristic curve of stress and compressibility is
It has a proportional zone, the upper limit of which indicates the elastic limit, and the elastic limit value is that the stress is 1.1 kg / cm ² and the compressibility is 5.6%.
Is. Urethane elastomer is excellent as the lower surface and side surface displacement absorbing materials 2 and 3, but since the lower surface and the side surface of the underground beam 1 are not directly affected by traffic, inexpensive inexpensive urethane foam is suitable. The thickness is about 4 as an example.
50 mm.

<C> Urethane Elastomer The urethane elastomer used in this example is a foamed urethane elastomer having a specific gravity of 0.3 to 1.1, preferably 0.5 to 0.9. The urethane elastomer has the following features. (1) Good vibration absorption characteristics The surface has a dense structure and the inside has a three-layer structure with a bubble structure.
Since it is deformed in the bubble structure, the spring constant hardly changes and the vibration absorption is large. (2) Good durability Excellent in compression set, fatigue resistance, water resistance, alkali resistance, and weather resistance. (3) Good low temperature characteristics. Hardness change is small compared to rubber even at low temperature. (4) Good moldability Since the integral molding can be done easily and quickly, and the curing time is fast, the molding cycle is short from 30 minutes to 60 minutes and the productivity is good. (5) You can choose the density according to your application

<D> Compression Characteristics of Urethane Elastomer FIG. 7 shows an example of compression characteristics of the urethane elastomer (specific gravity 0.64). It was found that the characteristic curves of stress and compressibility have first-order proportional zone and second-order proportional zone, and the elastic limit is extremely large. The elastic limit is stress of 2.4 kg
The compression ratio is 20.3% at / cm ² . Further, it has an elastic limit stress that is three times more than the impact compression stress for a short time. Urethane elastomers have various properties but are more expensive than rigid urethane foam. The urethane elastomer recovers its original shape even when compressed by 20.3%. Therefore, even for large displacement of large vibration,
It has the advantage that it can be absorbed with a urethane elastomer. As the upper surface displacement absorbing material 4, in the case of an upper surface to which a large impact load such as a wheel load is applied, a urethane elastomer having more excellent impact resistance is optimal. or,
Excellent characteristics can be obtained even when the thickness is thin, so it is also suitable for use near the ground surface. The thickness thereof can be thinner than that of the rigid urethane foam, and is about 95 mm as an example.

A construction method for attaching the displacement absorbing material will be described below with reference to FIGS. <B> Construction method of displacement absorbing material on the lower surface of the underground beam The hard urethane slab 11 produced in the factory and cut is placed below the underground beam with a gap. The thickness of the hard urethane slab 11 is 350 mm, and the gap between the slab and the underground beam is 100 mm. The hard urethane foam liquid 12 is injected into this gap to fill the gap with the hard urethane foam. By this construction method, the rigid urethane foam adheres to the surface of the underground beam and the slab, the rigid urethane foam layer is integrated with the underground beam, and it becomes easy to accurately match the dimensions of the site. If the rigid urethane foam is injected at a thickness of 450 mm at a time, there is a risk of causing a fire due to reaction heat, but if the thickness is 100 mm, there is no risk of a fire due to reaction heat.

<B> Construction method of displacement absorbing material on the side surface of the underground beam Like the lower surface of the underground beam, a hard urethane slab 1 having a thickness of 350 mm with a gap of 100 mm opened from the side surface of the underground beam.
Place 1 up to the height of the underground beam like a formwork. Hard urethane foam liquid 12 is poured into the gap to make a total thickness of 4
A 50 mm rigid urethane foam layer is integrally formed with the underground beam. Or, regarding the formation of other rigid urethane foam, spray the gun for spraying 1.5 m from the surface of the underground beam and spray the rigid urethane foam on the underground beam to form a rigid urethane foam layer with a predetermined thickness. Is also possible. This spray method has the following advantages and disadvantages. Can be applied uniformly and efficiently over a wide area. Also, the unevenness can be easily flattened. Since it can be installed while observing the urethane reaction, it is easy to adjust the thickness and shape. However, it requires a large working space and cannot be installed under strong winds or light rain. The maximum thickness that can be applied at one time is 25 mm, and the maximum thickness per day is 85 mm.

<C> Construction Method of Displacement Absorbing Material on Upper Surface of Underground Beam A urethane elastomer plate 13 having a thickness of 95 mm, which is produced in a factory, is bonded to the upper surface of the underground beam with a urethane adhesive such as urethane sealant. Then, the seam of the urethane elastomer is filled with a urethane sealant or filled with a urethane liquid that forms a urethane elastomer of the same quality.
Or, as another construction method, a form is provided around the upper surface of the underground beam, and after the urethane elastomer liquid is injected into the form and foamed,
Remove the formwork. In this case, the urethane elastomer layer 4 having a size suitable for the site can be obtained.

[0018]

As described above, the present invention can obtain the following special effects. <B> By using urethane elastomer around the underground beam, displacement, displacement and vibration of the underground beam are absorbed. <B> Use urethane elastomer on the upper surface of the underground beam,
By using the rigid urethane foam on the lower surface and the side surface, it is possible to effectively utilize the respective characteristics and obtain the optimum effect. <C> By providing a displacement absorber at the boundary between the underground beam and the underground beam, it is possible to prevent the vibration source held by the underground beam, for example, the vibration from a highway from propagating into the ground. It is also possible to prevent the vibration source in the ground, for example, the vibration of the subway from vibrating the highway through the underground beam. <D> By using urethane as the material of the displacement absorber,
It has a special effect that it can be used even in a severe environment such as underground and has high workability.

[Brief description of drawings]

FIG. 1 is a structural diagram of an underground beam.

FIG. 2 is a cross-sectional view taken along the dashed line in FIG.

FIG. 3 is a diagram showing another example of an underground beam.

FIG. 4 is a functional diagram of the upper surface and lower surface displacement absorbers of the underground beam.

FIG. 5 is a functional diagram of a lateral displacement absorber of an underground beam.

FIG. 6 is a compression characteristic diagram of rigid urethane foam.

FIG. 7 is a compression characteristic diagram of urethane elastomer.

FIG. 8 is a construction drawing of a lower surface hard urethane foam layer.

FIG. 9 is a construction drawing of a side hard urethane foam layer and a top urethane elastomer.

 ─────────────────────────────────────────────────── ─── Continuation of the front page (56) Reference JP 58-23819 (JP, A) JP 52-64113 (JP, A) JP 61-36315 (JP, A) JP 56- 128830 (JP, A) Actual opening 52-32937 (JP, U) Actual opening 53-62704 (JP, U)

Claims (4)

[Claims] 1. An underground beam displacement absorbing structure for an underground beam which is vertically displaced.
In the structure, urethane elas is applied to the top, bottom and side of the underground part of the underground beam.
Form either the tomer layer or rigid urethane foam layer
Underground beam displacement absorption structure characterized by being formed. 2. An underground beam displacement absorbing structure for an underground beam which is vertically displaced.
In the structure, form a urethane elastomer layer on the upper surface of the underground part of the underground beam.
And form a hard urethane foam layer on the bottom and sides
An underground beam displacement absorbing structure characterized by the above . 3. An underground beam displacement absorbing structure for an underground beam which is vertically displaced.
In the construction method of the structure, the hard ureths are spaced at the bottom surface and the side surface of the underground part of the underground beam.
Place a slab of tan foam and place a hard urethane in the gap.
Inject foam liquid to form hard urethane foam layer
Then, adhere or inject urethane elastomer on the top surface and
A method for constructing an underground beam displacement absorbing structure , characterized by forming a retan elastomer layer . 4. An underground beam displacement absorbing structure for an underground beam which is vertically displaced.
In the construction method of the structure, leave a space on the lower surface and part of the side surface of the underground beam.
Place a slab of rigid urethane foam and make it rigid in the space.
Hard urethane foam layer by injecting urethane foam liquid
To form a hard urethane foam on the bottom and other parts of the side.
Spray the foam to form a rigid urethane foam layer and
Urethane elastomer is adhered or injected onto the surface
A method for constructing an underground beam displacement absorbing structure , characterized by forming an elastomer layer .