STUDY OF BEHAVIOR MECHANICALLY STABILIZED EARTH WALL (MSE-WALL) WITH SAND ON THE MODEL TEST IN THE LABORATORY

Different types of field conditions coupled with rapid technological developments gave birth to innovations in the construction of retaining walls. One type of landslide deterrence construction that began to be developed in Indonesia is the Mechanically Stabilized Earth Wall or often called the MSE wall. The main components of the MSE wall are backfill material, lateral reinforcement and facing panel. In this final project, research will be conducted to observe the behavior of MSE wall systems on a laboratory scale. The study was conducted by planning the innovation of the facing panel form and the variation in the number of reinforcement layers. The variations of reinforcement are 1 layer, 2 layers, 3 layers, 4 layers and without reinforcement. The reinforcement used is sack as a substitute for geotextile woven with selected pile material is sand. In testing the prototype of the MSE wall, a dial gauge is used to find out the deformation, while for loading it uses a jack-push tool. From these tests, the data obtained in the form of shifts, lateral stresses, and the maximum load of the results of the study showed that the application of reinforcement can affect the amount of lateral stress, shifting, and load. The minimum lateral stress is 0.023 kg/cm 2 and the maximum load that can be held by the MSE wall is 75 kg.


INTRODUCTION
The retaining wall is a type of civil construction that continues to experience development as infrastructure development advances. In general, the retaining wall is known as landslide prevention, building with the principle of supporting the landfill or unstable native land.
However, the different types of field conditions accompanied by rapid technological developments gave birth to innovations in the construction of retaining walls. Both in terms of geometry, materials, methods of implementation to change the retaining wall of the land into a multifunctional building.
One type of landslide deterrence construction that began to be developed in Indonesia is the Mechanically Stabilized Earth Wall or often called the MSE wall. This type of soil retaining wall carries the concept of a retaining wall that is mechanically stabilized using geotextile CERUCUK Volume 5 No. 2 2021 (87-104) reinforcement or metal. The main components of MSE walls are backfilled material, lateral reinforcement and facing panel elements (Jiang, Han, Parsons., & Cai, 2015). The main advantages of MSE walls compared to conventional retaining walls (concrete and masonry) are economical, easy, fast implementation and flexible structure so that it can withstand greater settlement differences. Plus facing panels that can be made of various shapes and textures for aesthetic considerations or arrangement of bricks, wood, and oval can also be used to display harmony with the environment (Berg, Design, and Construction of Mechanically Stabilized Earth Walls and Reinforced Soil Slopes -Volume I, 2009).
In this final project, research will be conducted to observe the behavior of MSE wall systems on a laboratory scale. The research was carried out by planning, innovation in the form of facing panels and variations in reinforcement according to the landslide field of the retaining wall. Testing will be carried out on soils without strength and with reinforcement. The reinforcement used is sack as a substitute for geotextile woven with selected pile material is sand. In testing the prototype of the MSE wall, a dial gauge is used to find out the deformation while for loading it uses a jack-push tool.

Retaining Wall
The retaining wall is a Geotechnical building that is used to prevent steep ground collapse and has the stability that cannot be held by the land itself (Sosrodarsono & Nakazawa, 2000).
According to (Pratama, 2014) the retaining wall serves to support the soil and prevent it from the danger of landslides. Both due to the burden of rainwater, the weight of the land itself and due to the burden of working on it.
Soil retaining walls are used to withstand lateral soil stress caused by poor soil or unstable soil. This building is widely used in projects: irrigation, highways, ports, and others. The foundation elements, such as basement buildings, abutments, besides functioning as the bottom of the structure, also function as a barrier to the surrounding land. (Hardiyatmo, 2011)

Mechanically Stabilized Earth Wall
Mechanically Stabilized Earth Wall or often called MSE wall is a structure of retaining wall in the form of a combination of facing panels and soil piles reinforced with geotextile or metal materials. Volume 5 No. 2 2021 (87-104) 89

CERUCUK
The reinforcement element functions as a layer of soil reinforcement which also holds the concrete panels on the outside so that a stable and strong structure is formed (Mitchell, 1987).
The facing panel section made of various types of materials with attractive designs will provide artistic beauty while protecting the danger of vandalism (Berg, 2009).
Based on SNI 8460: 2017 it is stated that the main advantages of MSE walls compared to conventional retaining walls are economical, easy, and fast implementation. This structure is flexible, can withstand greater settlement differences than conventional retaining walls.

Stability of MSE Wall
In the MSE wall, the structure must be stable both due to the influence of internal and external forces. External stability or external stability (external stability) MSE walls have the same criteria as in conventional soil retaining wall structures. Internal stability or internal stability (internal stability) requires that the structure must be integrated and can stand alone by the influence of external forces as well as due to its weight.

A. External Stability
The external stability of the MSE wall depends on the ability of the soil mass to withstand external loads without the risk of structural collapse. These loads include lateral pressure on the ground behind the structure and the loads acting on it.
The collapse of the MSE wall must be reviewed against several mechanisms, namely Because of the flexibility of MSE walls, the safety factor for the four potential external failures is generally smaller than the safety factor for concrete cantilever walls and gravity-type walls.

B. Internal Stability
The internal stability analysis includes an analysis of the MSE wall structure for the following risks (Hardiyatmo, 2011): 1. Breakdown of reinforcement 2. Unplugging of retaining zone (passive zone)

Landslide Field Location of MSE Wall
Landslide surfaces for vertical walls with soils reinforced with reinforcing reinforcement (such as geotextiles) are generally considered to coincide with Rankine landslide fields ( Figure   2.2), i.e. The collapse occurs in an angled plane (45 ° + φ / 2) to the plane horizontal. Therefore, for soils that are reinforced with geotextiles, the lateral earth pressure coefficient (Ka) is used in the calculation of lateral earth pressure. The latest research references in modeling this retaining wall are based on research conducted by (Gunanta, 2014) and (Pratama, 2014) with peat heaps and flexible reinforcement.
Flexible reinforcement in the form of tarpaulin and polypropylene which are used as an alternative reinforcement material for peat can increase the strength of the retaining wall. And from the research, it was found that the wider the flexible reinforcement of tarpaulin and polypropylene on the retaining wall, the smaller the shift and lateral stress. Whereas for a retaining soil without direct reinforcement, it collapses due to lateral stress before loading, as well as the manual calculation that has been obtained SF value (Safety Factor) from stability to shear and stability to rolling as well as stability to the carrying capacity of the soil far below the value SF permission.

Collapse Limit of MSE Wall
The limit of lateral deformation of permits for retaining walls and/or embedded walls is determined by the condition of the soil, the depth of excavation and the distance and condition of the closest building whose magnitude is determined with the formula as listed in Table 2 In this study the soil used was and sand soil as high as 50 cm with moderate to solid density so the maximum deformation permit limit (δw / H) was 0.7%. δw = 0.7% x 50 cm = 035 cm So the allowable deformation limit is 3.5 mm. Because in this study the state of the MSE wall was reviewed in a state of collapse (ultimate), the collapse limit was set to 7 mm. Volume 5 No. 2 2021 (87-104)

A. Sack
The reinforcement material used is of synthetic sheet type, namely rice sacks (Figure 3.1).

Figure 3. 1 Sack as reinforcement material (idwebdesainer.com)
This synthetic material has a thickness of about 0.1 mm. In this study, 75 cm x 105 cm sacks were used.

B. Sand
The embankment soil used in this study is loose sand (Figure 3.2). Before testing the MSE wall, the sand is tested for its physical and mechanical properties.

C. Plywood
The material used for the prototype facing panel and leveling pad is plywood 9 mm thick. This material is used to facilitate the manufacture of relatively small MSE wall components.
Plywood material is also able to survive so as not to shrink compared to ordinary wood.
The material used in vertical joints is nails. The facing panel with reinforced joints used steel elbows which are welded and then shaped as in Figure 3

Tools
The tools used in this study can be seen in the following figure:

A. Material Tensile Strength Test
Sacks of rice and banners are each cut 10 cm wide and 105 cm long, then spread with one end tied to the test equipment and the other end connected to the loading device. At both ends of the test, the object is given a bolt connection. Then the load is placed gradually until it reaches the tear strengthened material state.

Figure 3.11 Illustration of deformation measurements on test specimens
Data obtained from this test are the total load and deformation that occurs when the reinforcement is torn. Deformation is obtained by placing the thread transversely as in Figure   3.11. Before being given a load, the test object is first marked on an area parallel to the yarn.
When the load is placed, the deformation can be calculated, by measuring the distance of the mark on the test specimen to the thread using a ruler. The load used in this test is used for consolidation testing with a weight of 1 kg to 10 kg. The load and deformation are recorded until the test object is torn or broken at an ultimate state of ultimate strength.

B. Collapse Test of MSE Wall Prototype
The steps of testing the MSE prototype wall begin by positioning the leveling pad as the foundation wall of the MSE. Then mounted facing panel until it reaches a height of 50 cm. After that, the sand begins to be put into the test box as high as 1 facing panel and compacted using a pounding tool or hammer. Then the sack that has been cut according to the size of the box is spread on the sand. Reinforcement is installed each as high as 1 facing panel (10 cm) and varies from 1-5 layers.
test specimens are marked Figure 3. 12 3D modelings of MSE wall prototype If all components are installed as shown in Figure 3.12, the prototype is ready to be tested using a jack push tool (Figure 3.13). From the jack, it can be seen that the maximum load for each variation of reinforcement installed. And to find out the deformation that occurs, a dial gauge is mounted in 3 pieces, namely above the middle section reinforcement, in front of the facing panel the top and the middle part.

Material Test Results
This test is carried out to determine the tensile strength value of the reinforcement material used in testing the MSE prototype wall. The average tensile strength value obtained from 3 samples of test specimens is 0.039 kg/cm 2 .

Physical and Mechanical Properties Test Results
The test results obtained are presented in Table 4.1 and

Test Results of MSE Wall
After testing the loading with variations in the number of reinforcement 1, 2, 3, 4 and without the reinforcement results obtained maximum loading and maximum stress. The maximum load is obtained when the MSE wall has been deformed beyond the maximum deformation of 7 mm. This condition is considered an ultimate collapse or the MSE wall has collapsed.    Figure 4.5 it can be seen that the more layers of reinforcement that are given the greater the maximum load that can be carried by the MSE wall. As with the maximum load, the maximum stress that occurs is also getting greater as more and more layers of reinforcement are given as can be seen in Figure 4.6. While from Figure 4.7 it can be seen that the deformation is getting smaller according to the number of reinforcement layers given.
Then to see the difference in the MSE wall without reinforcement and using 1 -4 layers of reinforcement than an analysis of the increase and decrease in the value of the load, stress, and deformation of the MSE wall without reinforcement with each variation of the MSE wall using reinforcement. Calculation results can be seen in Table 4.3. Table 4. 3 The value of the difference in increase and decrease in load, stress, and deformation between variations in reinforcement

Increased Deformation
The calculation results in Table 4.3 are presented in the form of curves in Figure 4.8, From the results of the research conducted it can be concluded that the more layers of reinforcement, the greater the maximum load and maximum stress that can be withstood from the MSE wall with the sack strength. In inverse proportion to loading and stress, the more layers of reinforcement the smaller the deformation that occurs. So, the reinforcement of the sack given to the prototype can reduce the deformation of the MSE wall and reduce lateral stress, this results in the MSE wall becoming stronger.

Conclusion
From the results and discussion, the following conclusions can be drawn: 1. Based on the tensile strength test conducted on the reinforcement material, it is known that the tensile strength value of the sack used as a reinforcement is 0,039 kg/cm 2 .
2. Based on the test results of physical and mechanical properties of sand, soil used as a pile material has a water content of 7,88%, a volume weight of 1,96 gr/cm 3 and a friction angle of 37º.
3. The bearing capacity that occurs on the slope with reinforcement increases compared without using reinforcement. Where more and more reinforcement layers are used, the carrying capacity that can be resisted increases.
4. The maximum load and maximum stress that can be carried by the MSE wall is the largest in the 4 layers of reinforcement, 75 kg with the stress of 0,023 kg/cm 2 .
5. The more layers of reinforcement, the greater the maximum load and maximum stress that can be withstood from the MSE wall. In inverse proportion to loading and stress, the more layers of reinforcement the smaller the deformation that occurs.
6. Sacks used as an alternative soil strengthening material can increase the strength of the MSE wall prototype.