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Engineering, Technology & Applied Science Research Vol. 12, No. 6, 2022, 9665-9669 9665 
 

www.etasr.com Maralapalle & Hedge: An Experimental Study on the Socketed Pile in Soft Rock 

 

An Experimental Study on the Socketed Pile in Soft 

Rock 
 

Vedprakash C. Maralapalle  

Civil Engineering Department  

Mukesh Patel School of Technology Management & 

Engineering 

Mumbai, India 

civilved@gmail.com 

R. A. Hegde 

Civil Engineering Department  

Mukesh Patel School of Technology Management & 

Engineering 

Mumbai, India 

ramachandra.hegde@nmims.edu.
 

Received: 17 September 2022 | Revised: 26 September 2022 | Accepted: 27 September 2022 

 

Abstract-Pile foundation systems are used in India in many 

projects such as metro and railways, flyovers, and multi-story 

buildings. The pile transfers superstructure load to the 

substructure, i.e. to rock layers by means of skin resistance and 

end-bearing resistance. In this study, an attempt is made to 

observe the performance of socketed piles in soft rock. A series of 

socketed small-scale model pile load laboratory studies have been 

conducted using the loading frame. Load tests were performed on 

a model steel pile to calculate its axial load-bearing capability at 

various socket depths. An unconfined compression test was 

performed on pseudo-rock variations to find out the properties of 

the soft rock used. The results showed the ability of the drilled 

pile to enhance the strength of the pseudo rock. An attempt was 

also made to calculate the optimum depth for the socketed pile in 

soft rock. 

Keywords-pile foundation; socketed depth; settlement; axial 

load; model pile 

I. INTRODUCTION  

Utilization of socketed piles is one economical method 
which has been used to transfer heavy loads to the rock strata. 
Rock socketed piles are drilled into the rock and then filled 
with steel and concrete. These piles are designed to carry heavy 
loads by base resistance and side skin resistance. Broad 
diameter cast in situ piles are used to hold massive loads of 
super-structures. Almost in every construction project, 
1000mm to 1200mm diameter piles are used. As these piles are 
built for heavy loads, they are basically to be lowered to the 
rock surface and need to be inserted into the rock [1]. The 
socket in the rock layer is absolutely necessary when the piles 
rest just on a rock at shallow depths. Boring in rock would have 
almost no challenge, except for occasional water pipes and 
boulders [2-5]. Rock sockets will pose several functional 
issues, usually ranging from rock classification to socket depth 
and actual terminating standards. Authors in [6] carried out a 
field pile load test by using Osterberg-cell which measures the 
skin friction of the pile. Authors in [7] carried out experimental 
investigations on the shaft friction of rock socketed piles using 
direct shear tests. Authors in [8] conducted numerical and 
experimental tests on model piles with good agreement 
between them. The method of [9] was applied to the field load-

displacement curve to obtain the ultimate pile load. Authors in 
[10] presented a scale of strength and the corresponding N 
values for weak rock and soils. Authors in [11] introduced the 
chiseling energy criteria applicable for rocks of the Mumbai 
region. Authors in [12] suggested that almost every load, 
including its subsequent settlement and the corresponding 
magnitude, was also drawn towards the applied load. Authors 
in [13] investigated the case of piles in elasto-plastic rocks 
using finite element analysis.  

Author in [14] strongly advocated the use of axisymmetric 
values of loads to define failure. Authors in [15] reviewed 
some of the methods of socket design. In their review, they 
recommended a range of bond values for piles socketed in 
shale rock. The author in [16] applied neural network modeling 
to compute the maximum load for a driven pile in cohesionless 
soil. Authors in [17] developed analytical solutions for the 
calculation of load-displacement response for axially loaded 
piles in rock. Authors in [18] proposed a simple geomechanical 
model for calculating the settlements of foundations in soft 
rock masses which showed good agreement with the field data. 
Authors in [19] carried out experimental studies for bond 
strength in rock socketed piers and stated that sidewall shear 
resistance essentially behaved in a non-brittle manner, i.e. it did 
not decrease even after the pile-rock bond was broken. Authors 
in [20] presented charts for rock socket design based on finite 
element analysis of an elastic pile resting on the elastic socket. 
Roughness classification and specification are shown in Table 
I. Authors in [21] proposed a design process for socketed pile 
in a soft rock complying with the defined settlement 
requirements and providing an appropriate factor of safety. 
Authors in [22] proposed a design method, which used 
parameters based on a wide range of theoretical, laboratory, 
and field investigations. 

II. PILE SOCKETING 

If the diameter of the pile is 1.2m, the rock socket is to be 
completed by breaking the hard rock for a length of 1.2m. For 
chiseling in hard rock, whose crushing strength is 1000kg/cm

2
, 

more time is required. Each of these components may cause 
serious damage to a rock mass. The load is carried by the pile 

Corresponding author: Vedprakash C. Maralapalle 



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www.etasr.com Maralapalle & Hedge: An Experimental Study on the Socketed Pile in Soft Rock 

 

on the rock by point bearing. This makes necessary to socket 
the pile through the rock by breaking across the weak rock and 
by cutting down the hard rock for an appropriate depth 
generally to get the flat surface of the rock. This appropriate 
depth can vary between 200 and 400mm [23]. Also, if the soft 
or medium rocks precede the hard rock, each length of the 
socket can be considered from the level where soft rock has an 
N value higher than 50. There are variations in the form of the 
rock almost every time. It can be weathered rock, soft rock, or 
hard rock. Firstly, rock layer classification must be conducted. 
For this reason, we refer to field test reports such as RQD and 
SPT [24, 25]. For larger constructions like flyover and high-
rise buildings, soil study must be conducted beneath every pier 
position. Hence, the above-mentioned studies are crucial to be 
performed for every pier site. [26-28]. 

TABLE I.  ROUGHNESS CLASSIFICATION OF ROCK SOCKETS [18] 

Roughness 

classification 
Specification 

R1 Soft socket, grooves less than 1mm deep 

R2 
Depth of grooves 1 to 4mm, spacing 

50mm to 200mm, width > 2mm 

R3 
Depth of grooves 4 to 10mm, spacing 

50mm to 200mm , width > 5mm 

R4 
Depth of grooves > 10mm,  spacing 50mm 

to 200mm , width > 10mm 

 

III. TECHNIQUES FOR ASSESSING SOCKETED PILE LENGTH IN 
ROCK 

There are two different techniques used for the calculation 
of the socketed depth of piles in rock.  

A. On the basis of Uniaxial Compression Strength Method 

Rock socketed pile is primarily executed to make use of the 
complete structural strength of the pile. Sockets are built to 
hold the axial load through the side friction and the base 
resistance. It is important to gather all the information 
described above. In this regard, the elemental composition of 
the rock at the foundation stage should also be collected for the 
detection of chemical components influencing the capacity of 
the pile. The safe load-carrying capabilities of the socketed pile 
can be determined by the uniaxial compression strength of the 
rock.  

B. Determination by the Energy Criteria Method 

The configuration of the rock socket depth of the pile in the 
rock can be determined based on energy criteria. Rock 
socketing standards have a great deal of significance in 
weathered/soft rock. Core recovery ratio/rock content 
classification is the optimal measure to assess the rock type. It's 
hard to have the cores in the weathered/soft rock. The approach 
proposed in [10] is commonly used to determine the depth of 
the socket of the piles in soft-rock to obtain the ability of the 
pile and its structural strength. N values are used to describe the 
rock type and its shear strength. In fact, another technique uses 
a chisel to decide the form of the rock and the depth of the 
socket. The key points to be considered in the chisel energy 
system are the weight of the chisel, the number of blows, and 
the penetration into the rock for a predetermined number of 
blows. While this method appears to be more realistic and 

rational, it has many disadvantages, such as the strength of the 
chisel, the chisel dropping into the bentonite mixture, the mass 
of the chisel, and its type. Chisel energy is measured based on 
the findings of the load test carried out in those regions. 

C. Steps to Follow During Rock Socketing 

Other than drilling the rock up to the necessary depth in the 
rock socket, certain more important functional considerations 
need to be noticed. The heavy chiseling of high torque drilling 
can create vibrations during the rock socket operation. Such 
vibrations can allow the soil strata to destabilize the rock base 
and the pile would lose the resistance component of these 
levels. Therefore, better care must be taken to minimize 
disturbances. Rock socketing requires a longer time and often 
disturbs the layers by laying the rock strata. This disruption 
would allow the fine particles to break down and settle down at 
the bottom. In order to clear these small pieces and other 
boulders, the borehole must be thoroughly washed with a clean 
bentonite solution prior to the concreting process. 

IV. EXPERIMENTAL PROCEDURE 

Rock socketed pile load testing is an experiment to be 
performed in the lab with the intention of providing more data 
on the load transfer behavior in socketed piles with varying 
L/D ratios. The typical sub-surface profile of soft-rock socketed 
pile is shown in Figure 1. After the application of P downward 
axial load on the top of the pile, equal and opposite reaction is 
developed at the pile in the upward direction. Q base is the base 
resistance. The length of the weathered stratum and the length 
of the soft-rock stratum represent the skin friction in different 
layers.  

 

Fig. 1.  Typical sub-surface profile of the rock socketed pile. 

A. Model Pile Material and Tank 

A stainless steel hollow pipe was used, having two different 
diameters of 60mm and 80mm and a length 600mm. The steel 
tank is made up of mild steel material whose dimensions are 
1000×1000×1000mm and 6mm thickness. The front side of the 
tank is made up of a Perspex sheet to observe failure patterns 
during testing. The tank can be moved in the x and y directions 
under the load frame in order to apply centric and eccentric 
loading. 



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B. Devloping of Pseudo-rock Socket 

For pseudo-rock formation cement, sand, bentonite, and 
water were used. Model rock specimens were developed, 
although their strengths varied widely. Table II provides the 
description of the ingredient proportions for pseudo-rock. The 
percentage of sand and water were kept constant and the 
percentage of cement and bentonite increased and decreased 
simultaneously. Unconfined compressive strengths, as shown 
in Figure 2, were determined by the Compression Testing 
Machine (CTM) after 28 days of curing. 

 

 

Fig. 2.  Testing of mortar cube and cylinder in the CTM. 

TABLE II.  MORTAR CUBE TEST RESULTS FOR DIFFERENT 
BENTONITE PERCENTAGES 

Mix 
Cement 

(%) 

Bentonite 

(%) 

Sand 

(%) 

Water 

(%) 

Avg. UCS 

(MPa) 

M1 17.97 4.5 67.41 10.11 19.3 

M2 15.73 6.74 67.41 10.11 16.7 

M3 13.48 8.98 67.41 10.11 9.5 

M4 11.23 11.23 67.41 10.11 4.7 

M5 8.9 13.48 67.41 10.11 3.4 

M6 6.74 15.73 67.41 10.11 1.9 

M7 4.5 17.97 67.41 10.11 1.2 

 

V. EXPERIMENTAL SET-UP 

A hydraulic jack attached to the frame's bottom allowed the 
gradual application of axial load to the pile head throughout the 
experiment. A load cell was attached between the hydraulic 
jack and the loading frame. Therefore, two Linear Variable 
Differential Transformers (LVDTs) were installed on the wing 
plates, fastened to the opposing sides of the pile cap to measure 
the movement of the pile head. The whole assembly, including 
the hydraulic jack, has a capacity of 30kN. An initial load of 
0.2kN was applied before initiating any load increments. Loads 
were applied in increments of 0.25kN up to 1kN, thereafter at 
1kN increments until failure or 30kN whichever was earlier. A 
digital displacement monitor linked to the LVDTs recorded 
movement readings when each load was applied. We kept 
increasing the load until the rate of change in the pile 

movement was minimal. The schematic view of the 
experimental setup and the actual pile load test setup are 
presented in Figure 3 and 4 respectively. L/D ratios 1 to 7 were 
used for the testing program, where D is the diameter of the 
pile and L is the socketed length of the pile. Details of the 
testing program for 60mm diameter pile and 80mm diameter 
pile are given in Tables III and IV respectively. Different 
unconfined strengths of soft rock were used.  

 
Fig. 3.  Schematic view of the experimental setup (1= loading frame, 2= 
hydraulic jack, 3= LVDT, 4= load cell, 5= model pile, 6 = metal tank, 7 = 

pseudo rock, 8 = pressure indicator, 9 = hydraulic pump). 

 

Fig. 4.  Actual pile load test set-up with LVDT and load cell. 

VI. RESULTS AND DISCUSSION 

The behavior of load-settlement curves is discussed in this 
section. Based on the experimental results, the load-settlement 
response and the load transfer mechanism along the depth of 
the pile are discussed. All the piles were gradually loaded until 
failure to obtain their axial load-carrying capacities. Two 
different diameter piles were used in the testing program. The 
load vs displacement curves for the 60mm diameter piles are 
shown in Figure 5. A number of experimental model studies 
were carried out to determine the impact of the socket depth on 
the behavior of the in situ cast piles. Seven sets of experiments 
with different socket lengths of 1D, 2D, 3D, 4D, 5D, 6D, and 
7D, where D is the diameter of the pile in pseudo rock were 
used in the testing program. With the help of the load 
settlement curve, the ultimate pile capacity was calculated. 



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TABLE III.  DETAILS OF MODEL SOCKETED PILE LOAD TESTS ON 
SOFT ROCK FOR 60mm DIAMETER PILE 

Test no. Pile no L/D 
Socket 

length (mm) 

Avg. UCS 

(MPa) 

1 P1 1 60 9.45 

2 P2 2 120 9.43 

3 P3 3 180 9.36 

4 P4 4 240 9.40 

5 P5 5 300 9.21 

6 P6 6 360 9.64 

7 P7 7 420 9.33 

TABLE IV.  DETAILS OF MODEL SOCKETED PILE LOAD TESTS ON 
SOFT ROCK FOR 80mm DIAMETER PILE 

Test no. Pile no. L/D 
Socket 

length (mm) 

Avg. UCS 

(MPa) 

1 P1 1 80 9.30 

2 P2 2 160 9.45 

3 P3 3 240 9.46 

4 P4 4 320 9.40 

5 P5 5 400 9.31 

6 P6 6 480 9.54 

7 P7 7 560 9.43 

 

 

Fig. 5.  Comparison of load vs. settlement curves for 1D -7D socketed 
piles for 60mm pile diameter. 

 

Fig. 6.  Comparison of load vs. settlement curves for 1D -7D socketed 
piles for 80mm pile diameter. 

The load was applied incrementally up to 30kN and the 
corresponding vertical displacements were recorded. For 1D, 
2D, 3D, 4D, 5D, 6D, and 7D socketed depths, the observed 
axial pile capacities by the double tangent method were 6.2kN, 
9.1kN, 11.2kN, 12.8kN, 15.3kN, 16kN, and 16.6kN 
respectively. The load vs displacement curves for 80mm 
diameter piles are shown in Figure 6. The loads were applied 
and the corresponding vertical displacements were recorded. 

For 1D, 2D, 3D, 4D, 5D, 6D, and 7D socketed depths, the axial 
pile capacities were 10.8kN, 14.1kN, 17.25kN, 21.1kN, 
24.15kN, 26.1kN, and 27.9kN respectively. 

The compression measurements on the model piles 
demonstrate that the pile resistance increases as the depth of the 
socket increases, which is essentially due to the friction 
between the pile and the socketed rock. Up to a length of 4D to 
5D of socket depth, the capacity of the pile was observed to 
increase considerably, but after 5D socket length, the 
improvement in the pile capacity was marginal. This marginal 
increase in strength was caused by the decrease in strength of 
the material and low pile stiffness. So, it can be concluded that 
5D of the length of socket is the optimum depth of the socketed 
pile in soft-rock. This is consistent with the observations of [7, 
11]. 

VII. CONCLUSIONS 

In the present study, an effort has been made to analyze the 
minimum depth of the socketed pile in soft rocks. The behavior 
of piles in the soft rock was studied through an elaborate 
laboratory program, with varying socket lengths. A large 
number of pseudo rock samples using cement and bentonite 
were made by changing the proportions of cement and 
bentonite (7 mixes, termed as M1-M7, having UCS values of 
up to 19.3MPa were prepared and tested). The present study 
demonstrated that the behavior of socketed piles can be 
successfully modeled in a soft rock. The results of the present 
model study and the reported data in the literature are in 
accordance. The conclusions of the experimental program are: 

 UCS strengths were found to decrease as the proportion of 
bentonite increased in the pseudo-rock. 

 Pile capacity increases dramatically for socket length up to 
5D, but this is minimal above a length of 5D. 

 As the diameter of the pile increases, the ultimate load 
capability of the pile also increases. 

 The experimental results indicate that when the diameter of 
the pile increases by 35%, the loading capacity at the top of 
the pile increases by around 50%. 

It should be noted that the conclusions shown above are 
based on laboratory testing with a 1-g model. Because the 
behavior of piles in rock is stress-dependent, which is not 
properly simulated in 1-g model testing, full-scale/centrifuge 
test data under axial loading are necessary to verify the above-
mentioned conclusions. Therefore, these results may be very 
useful as both a firsthand description and as a resource for 
numerical verification. 

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