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  Design of a cotter joint 
If the allowable stresses in tension, compression and shear for the socket, rod 
and cotter be 
t
s ,
c
s and t respectively, assuming that they are all made of the 
same material, we may write the following failure criteria: 
 
 
1. Tension failure of rod at diameter d  
 
           
2
t
dP
4
p
s=
  
 
  
      
   
4.2.2.1F- Tension failure of the rod (Ref.[6]). 
 
 
2. Tension failure of rod across slot 
 
2
11 t
ddt P
4
p??
-s=
??
??
 
 
 
 
 
         4.2.2.2F- Tension failure of rod across slot (Ref.[6]). 
 
 
 
 
 
 
t
Page 2


  Design of a cotter joint 
If the allowable stresses in tension, compression and shear for the socket, rod 
and cotter be 
t
s ,
c
s and t respectively, assuming that they are all made of the 
same material, we may write the following failure criteria: 
 
 
1. Tension failure of rod at diameter d  
 
           
2
t
dP
4
p
s=
  
 
  
      
   
4.2.2.1F- Tension failure of the rod (Ref.[6]). 
 
 
2. Tension failure of rod across slot 
 
2
11 t
ddt P
4
p??
-s=
??
??
 
 
 
 
 
         4.2.2.2F- Tension failure of rod across slot (Ref.[6]). 
 
 
 
 
 
 
t
3. Tensile failure of socket across slot 
22
21 2 1 t
(d d ) (d d )t P
4
p??
-- - s=
??
??
 
 
 
 
 
 
      
   4.2.2.3F- Tensile failure of socket across slot. 
 
4. Shear failure of cotter 
2bt P t= 
 
 
 
 
 
 
     4.2.2.4F- Shear failure of cotter. 
 
5. Shear failure of rod end 
11
2d P t= l 
 
 
 
 
     4.2.2.5F- Shear failure of rod end 
 
 
 
d
2
t
Page 3


  Design of a cotter joint 
If the allowable stresses in tension, compression and shear for the socket, rod 
and cotter be 
t
s ,
c
s and t respectively, assuming that they are all made of the 
same material, we may write the following failure criteria: 
 
 
1. Tension failure of rod at diameter d  
 
           
2
t
dP
4
p
s=
  
 
  
      
   
4.2.2.1F- Tension failure of the rod (Ref.[6]). 
 
 
2. Tension failure of rod across slot 
 
2
11 t
ddt P
4
p??
-s=
??
??
 
 
 
 
 
         4.2.2.2F- Tension failure of rod across slot (Ref.[6]). 
 
 
 
 
 
 
t
3. Tensile failure of socket across slot 
22
21 2 1 t
(d d ) (d d )t P
4
p??
-- - s=
??
??
 
 
 
 
 
 
      
   4.2.2.3F- Tensile failure of socket across slot. 
 
4. Shear failure of cotter 
2bt P t= 
 
 
 
 
 
 
     4.2.2.4F- Shear failure of cotter. 
 
5. Shear failure of rod end 
11
2d P t= l 
 
 
 
 
     4.2.2.5F- Shear failure of rod end 
 
 
 
d
2
t
6.  Shear failure of socket  end 
()
31
2d d P -t= l 
 
 
 
 
 
       
4.2.2.6F- Shear failure of socket end 
 
 
 
7. Crushing failure of rod or cotter 
1c
dt P s= 
 
 
 
 
    4.2.2.7F- Crushing failure of rod or cotter  
 
 
8. Crushing failure of socket or rod 
()
31 c
dd t P -s=
 
 
 
 
 
 
 
                      4.2.2.8F- Crushing failure of socket or rod 
d
Page 4


  Design of a cotter joint 
If the allowable stresses in tension, compression and shear for the socket, rod 
and cotter be 
t
s ,
c
s and t respectively, assuming that they are all made of the 
same material, we may write the following failure criteria: 
 
 
1. Tension failure of rod at diameter d  
 
           
2
t
dP
4
p
s=
  
 
  
      
   
4.2.2.1F- Tension failure of the rod (Ref.[6]). 
 
 
2. Tension failure of rod across slot 
 
2
11 t
ddt P
4
p??
-s=
??
??
 
 
 
 
 
         4.2.2.2F- Tension failure of rod across slot (Ref.[6]). 
 
 
 
 
 
 
t
3. Tensile failure of socket across slot 
22
21 2 1 t
(d d ) (d d )t P
4
p??
-- - s=
??
??
 
 
 
 
 
 
      
   4.2.2.3F- Tensile failure of socket across slot. 
 
4. Shear failure of cotter 
2bt P t= 
 
 
 
 
 
 
     4.2.2.4F- Shear failure of cotter. 
 
5. Shear failure of rod end 
11
2d P t= l 
 
 
 
 
     4.2.2.5F- Shear failure of rod end 
 
 
 
d
2
t
6.  Shear failure of socket  end 
()
31
2d d P -t= l 
 
 
 
 
 
       
4.2.2.6F- Shear failure of socket end 
 
 
 
7. Crushing failure of rod or cotter 
1c
dt P s= 
 
 
 
 
    4.2.2.7F- Crushing failure of rod or cotter  
 
 
8. Crushing failure of socket or rod 
()
31 c
dd t P -s=
 
 
 
 
 
 
 
                      4.2.2.8F- Crushing failure of socket or rod 
d
 
9. Crushing failure of collar 
22
41 c
(d d ) P
4
p??
-s=
??
??
 
 
 
 
 
 
  
     4.2.2.9F- Crushing failure of collar. 
 
10. Shear failure of collar  
11
dt P pt=
 
 
 
 
 
 
 
     4.2.2.10F- Shear failure of collar.   
 
Cotters may bend when driven into position. When this occurs, the bending 
moment cannot be correctly estimated since the pressure distribution is not 
known. However, if we assume a triangular pressure distribution over the rod, as 
shown in figure-4.2.2.11 (a), we may approximate the loading as shown in figure-
4.2.2.11 (b) 
 
 
 
 
 
Page 5


  Design of a cotter joint 
If the allowable stresses in tension, compression and shear for the socket, rod 
and cotter be 
t
s ,
c
s and t respectively, assuming that they are all made of the 
same material, we may write the following failure criteria: 
 
 
1. Tension failure of rod at diameter d  
 
           
2
t
dP
4
p
s=
  
 
  
      
   
4.2.2.1F- Tension failure of the rod (Ref.[6]). 
 
 
2. Tension failure of rod across slot 
 
2
11 t
ddt P
4
p??
-s=
??
??
 
 
 
 
 
         4.2.2.2F- Tension failure of rod across slot (Ref.[6]). 
 
 
 
 
 
 
t
3. Tensile failure of socket across slot 
22
21 2 1 t
(d d ) (d d )t P
4
p??
-- - s=
??
??
 
 
 
 
 
 
      
   4.2.2.3F- Tensile failure of socket across slot. 
 
4. Shear failure of cotter 
2bt P t= 
 
 
 
 
 
 
     4.2.2.4F- Shear failure of cotter. 
 
5. Shear failure of rod end 
11
2d P t= l 
 
 
 
 
     4.2.2.5F- Shear failure of rod end 
 
 
 
d
2
t
6.  Shear failure of socket  end 
()
31
2d d P -t= l 
 
 
 
 
 
       
4.2.2.6F- Shear failure of socket end 
 
 
 
7. Crushing failure of rod or cotter 
1c
dt P s= 
 
 
 
 
    4.2.2.7F- Crushing failure of rod or cotter  
 
 
8. Crushing failure of socket or rod 
()
31 c
dd t P -s=
 
 
 
 
 
 
 
                      4.2.2.8F- Crushing failure of socket or rod 
d
 
9. Crushing failure of collar 
22
41 c
(d d ) P
4
p??
-s=
??
??
 
 
 
 
 
 
  
     4.2.2.9F- Crushing failure of collar. 
 
10. Shear failure of collar  
11
dt P pt=
 
 
 
 
 
 
 
     4.2.2.10F- Shear failure of collar.   
 
Cotters may bend when driven into position. When this occurs, the bending 
moment cannot be correctly estimated since the pressure distribution is not 
known. However, if we assume a triangular pressure distribution over the rod, as 
shown in figure-4.2.2.11 (a), we may approximate the loading as shown in figure-
4.2.2.11 (b) 
 
 
 
 
 
 
 
 
 
 
 
 
   
  (a)        (b) 
         4.2.2.11F- Bending of the cotter 
 
This gives maximum bending moment = 
31 1
dd d P
26 4
-??
+
??
??
 and 
 
The bending stress, 
31 31 11
b 3 2
dd dd dd Pb
3P
26 42 6 4
tb tb
12
-- ?? ? ?
++
?? ? ?
?? ? ?
s= = 
 
Tightening of cotter introduces initial stresses which are again difficult to 
estimate. Sometimes therefore it is necessary to use empirical proportions to 
design the joint. Some typical proportions are given below: 
1
d 1.21.d = 
2
d 1.75.d = 
d
3
 = 2.4 d 
4
d1.5.d = 
t0.31d = 
b 1.6d = 
1
l l 0.75d == 
1
t0.45d = 
s= clearance 
d
3
b
d
1
P/2
P/2
P/2
P/2
-
+
31 1
dd d
64
31 1
dd d
64
-
+
1
d
4
1
4
d
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FAQs on Cotter & Knuckle Joint - 2 - Design of Machine Elements - Mechanical Engineering

1. What is a cotter joint?
Ans. A cotter joint is a mechanical joint used to connect two rods or bars together. It consists of a cylindrical hole through which a tapered cylindrical pin, called a cotter, is inserted. The cotter is then hammered or wedged into place, creating a secure and rigid connection between the two rods.
2. What is a knuckle joint?
Ans. A knuckle joint is a type of mechanical joint used to connect two rods or bars together, allowing them to rotate relative to each other. It consists of a cylindrical hole in one rod and a spherical or semi-spherical socket in the other rod. A pin is inserted into the hole and socket, creating a pivot point that allows for rotational movement.
3. What are the advantages of using a cotter joint?
Ans. Some advantages of using a cotter joint include: - High strength and rigidity: The cotter joint provides a strong and rigid connection between two rods, ensuring that they remain securely fastened together. - Easy assembly and disassembly: The cotter can be easily inserted and removed, making it convenient for assembly and disassembly purposes. - Cost-effective: Cotter joints are relatively simple and inexpensive to manufacture, making them a cost-effective choice for connecting rods or bars. - Versatility: Cotter joints can be used in various applications, such as connecting machine parts, structural components, or even in automotive and aerospace industries.
4. What are the limitations of using a knuckle joint?
Ans. Some limitations of using a knuckle joint include: - Limited angular movement: Knuckle joints can only provide limited angular movement, typically up to 90 degrees. If a greater range of motion is required, alternative joint designs may be more suitable. - Increased complexity and cost: Knuckle joints require more complex machining and assembly compared to simpler joint designs, which can increase manufacturing costs. - Potential stress concentrations: The presence of the pin and socket in the knuckle joint can create stress concentrations, which may reduce the overall strength and durability of the joint. - Limited load-bearing capacity: Knuckle joints may not be suitable for heavy-duty applications or those that require high load-bearing capacities, as they may not provide sufficient strength or stability.
5. What are the applications of cotter and knuckle joints?
Ans. Cotter joints are commonly used in various applications, including: - Connecting machine parts: Cotter joints can be used to connect different machine components, such as levers, linkages, or crankshafts. - Structural connections: They can be used to connect structural members, such as trusses or frames, ensuring their stability and rigidity. - Automotive industry: Cotter joints can be found in various automotive applications, including connecting suspension components or steering linkages. Knuckle joints also find applications in different areas, such as: - Mechanical linkages: Knuckle joints can be used in mechanical linkages, allowing for rotational movement and transmission of forces. - Pivoting mechanisms: They are commonly used in door hinges, allowing doors to swing open and closed. - Articulated machinery: Knuckle joints are often used in the construction of articulated machinery, such as cranes or excavators, enabling them to move and operate in multiple directions.
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