Design of Power Screws | Design of Machine Elements - Mechanical Engineering PDF Download

Stresses in power screws

Design of a power screw must be based on the stresses developed in the constituent parts. A power screw is subjected to an axial load and a turning moment. The following stresses would be developed due to the loading:

a) Compressive stress is developed in a power screw due to axial load. Depending on the slenderness ratio it may be necessary to analyze for buckling. The compressive stress σc is given by σDesign of Power Screws | Design of Machine Elements - Mechanical Engineering here dc is the core diameter and if slenderness ratio λ is more than 100 or so buckling criterion must be used. λ is defined as λ =Design of Power Screws | Design of Machine Elements - Mechanical Engineering  where I=Ak2 and L is the length of the screw. Buckling analysis yields a critical load Pc and if both ends are assumed to be hinged critical load is given by PC =  Design of Power Screws | Design of Machine Elements - Mechanical Engineering In general the equation may be written as  Design of Power Screws | Design of Machine Elements - Mechanical Engineering where n is a constant that depends on end conditions.

b) Torsional shear stress is developed in the screw due to the turning moment and this is given by    Design of Power Screws | Design of Machine Elements - Mechanical Engineering   where T is the torque applied

 

c) Bending stresses are developed in the screw thread and this is illustrated in figure-6.2.1.1. The bending moment  Design of Power Screws | Design of Machine Elements - Mechanical Engineering and the bending stress on a single thread is given byDesign of Power Screws | Design of Machine Elements - Mechanical EngineeringHere y    Design of Power Screws | Design of Machine Elements - Mechanical Engineering  and F′ is the load  on a single thread. Figure-6.2.1.2 shows a developed thread and figure shows a nut and screw assembly. This gives the bending stress at the thread root to be   Design of Power Screws | Design of Machine Elements - Mechanical Engineering           This is clearly the most probable place for failure. Assuming that the load is equally shared by the nut threads

d) Bearing stress σbr at the threads is given by Design of Power Screws | Design of Machine Elements - Mechanical Engineering

e) Again on similar assumption shear stress τ at the root diameter is given by  Design of Power Screws | Design of Machine Elements - Mechanical Engineering

Here n/ is the number of threads in the nut. Since the screw is subjected to torsional shear stress in addition to direct or transverse stress combined effect of bending, torsion and tension or compression should be considered in the design criterion.

 

Design procedure of a Screw Jack 

A typical screw jack is shown in figure-6.2.2.1 . It is probably more informative to consider the design of a jack for a given load and lift. We consider a reasonable value of the load to be 100KN and lifting height to be 500mm. The design will be considered in the following steps:

1. Design of the screw 

A typical screw for this purpose is shown in figure-6.2.2.2. Let us consider a mild steel screw for which the tensile and shear strengths may be taken to be approximately 448MPa and 224 MPa respectively. Mild steel being a ductile material we may take the compressive yield strength to be also close to 448MPa. Taking a very high factor of safety of 10 due to the nature of the application and considering the axial compression the core diameter of the screw dc is given by

Design of Power Screws | Design of Machine Elements - Mechanical Engineering

which gives dc ≈ 54 mm. From the chart of normal series square threads in table- 6.1.1.1 the nearest standard nominal diameter of 70 mm is chosen, with pitch p = 10 mm. Therefore, core diameter dc = 60 mm , Major diameter dmaj = 70mm , Mean diameter dm = 65 mm , Nominal diameter dn = 70mm. The torque required to raise the load is given by

Design of Power Screws | Design of Machine Elements - Mechanical Engineering

Where l = np, n being the number of starts. Here we have a single start screw and hence l = p =10mm, dm = 65mm, F = 100X103 N Taking a safe value of μ for this purpose to be 0.26 and substituting the values we get T = 1027 Nm.

Check for combined stress 

The screw is subjected to a direct compressive stress σc and a torsional shear stress τ. The stresses are given by  Design of Power Screws | Design of Machine Elements - Mechanical EngineeringDesign of Power Screws | Design of Machine Elements - Mechanical Engineering

The principal stress can be given by

Design of Power Screws | Design of Machine Elements - Mechanical Engineering

and maximum shear stress τmax = 29.96 MPa.

The factor of safety in compression  Design of Power Screws | Design of Machine Elements - Mechanical Engineering and in shear =Design of Power Screws | Design of Machine Elements - Mechanical Engineering Therefore the screw dimensions are safe. Check for buckling and thread stress are also necessary. However this can be done after designing the nut whose height and number of threads in contact is needed to determine the free length of the screw.

2. Design of the nut

A suitable material for the nut, as shown in figure- 6.2.2.3, is phosphor bronze which is a Cu-Zn alloy with small percentage of Pb and the yield stresses may be taken as

 Yield stress in tension σty = 125MPa
Yield stress in compression σcy = 150MPa
Yield stress in shear τy = 105MPa
Safe bearing pressure Pb = 15MPa.

Considering that the load is shared equally by all threads bearing failure may be avoided if

Design of Power Screws | Design of Machine Elements - Mechanical Engineering

where n/ is the number of threads in contact. Substituting values in the above equation we have n/ = 6.52. Let n/ =8. Therefore H = n/ p = 8X10 = 80mm. The nut threads are also subjected to crushing and shear. Considering crushing failure we have

Design of Power Screws | Design of Machine Elements - Mechanical Engineering

This gives σc = 12.24 MPa which is adequately safe since σcy = 150 MPa and therefore crushing is not expected. To avoid shearing of the threads on the nut we may write F = πdmaj t n/ τ where t is the thread thickness which for the square thread is Design of Power Screws | Design of Machine Elements - Mechanical Engineering ie 5. This gives τ =11.37 MPa and since τy= 105MPa shear failure of teeth is not expected. Due to the screw loading the nut needs to be checked for tension also and we may write

Design of Power Screws | Design of Machine Elements - Mechanical Engineering

A correlation factor C for the load is used to account for the twisting moment. With C=1.3 and on substitution of values in the equation D1 works out to be 70mm. But D1 needs to be larger than dmaj and we take D1 = 100mm. We may also consider crushing of the collar of the nut and to avoid this we may write

Design of Power Screws | Design of Machine Elements - Mechanical Engineering

Substituting values we have D2 = 110 mm. To allow for the collar margin we take D2 =120mm. Considering shearing of the nut collar πD1y = F . Substituting values we have a = 4mm Let a = 15mm

3. Buckling of the Screw.

Length L of the screw = Lifting height + H. This gives L= 500+80 = 580 mm With the nominal screw diameter of 70mm ,

Design of Power Screws | Design of Machine Elements - Mechanical Engineering

and  Design of Power Screws | Design of Machine Elements - Mechanical Engineering

The slenderness ration λ  Design of Power Screws | Design of Machine Elements - Mechanical Engineering

This value of slenderness ratio is small (< 40) and the screw may be treated as a short column . No buckling of the screw is therefore expected.

4. Tommy bar 

A typical tommy bar for the purpose is shown in figure-6.2.2.4.a. Total torsional moment without the collar friction is calculated in section 6.2.2.1 and T = 1027 Nm. The collar friction in this case ( see figure-6.2.2.1) occurs at the interface I. However in order to avoid rotation of the load when the screw rotates a loose fitting of the cup is maintained. Length l/ of the tommy bar = l1 + l3 and we may write the torque T as D3 T= F1l/ Where F1 is the maximum force applied at the tommy bar end and this may be taken as approximately 400 N . This gives  Design of Power Screws | Design of Machine Elements - Mechanical Engineering This length of the tommy bar is too large and one alternative is to place the tommy bar centrally and apply force at both the ends. This alternative design of the tommy bar is also shown in figure-6.2.2.4.b The bar is subjected to a bending moment and its maximum value may be taken as 1027 Nm. This means to avoid bending we may write  Design of Power Screws | Design of Machine Elements - Mechanical Engineering

where d1 is the tommy bar diameter as shown in figure- 6.2.2.4.b If we choose a M.S bar of σty = 448MPa the tommy bar diameter d1 works out to be d1 = 0.0285m. Let d1 = 30 mm and we choose d2 = 40mm

5. Other dimensions

D= (1.5 to 1.7 ) d           Let D= 112 mm
Design of Power Screws | Design of Machine Elements - Mechanical Engineering

Let L1 = 100 mm and t4 = 10 mm

t1 = 0.25 dnDesign of Power Screws | Design of Machine Elements - Mechanical Engineering18 mm , D5Design of Power Screws | Design of Machine Elements - Mechanical Engineering2.25 D2 = 270 mm, D6 = 1.75 D5 = 473 mm, t3 = t1/2 = 9 mm.

Design of Power Screws | Design of Machine Elements - Mechanical Engineering
6.2.1.1 F- Loading and bending stresses in screw threads

Design of Power Screws | Design of Machine Elements - Mechanical Engineering

Design of Power Screws | Design of Machine Elements - Mechanical Engineering

Design of Power Screws | Design of Machine Elements - Mechanical Engineering

Design of Power Screws | Design of Machine Elements - Mechanical Engineering

6.2.2.2F- The screw with the provision for tommy bar attachment

Design of Power Screws | Design of Machine Elements - Mechanical Engineering

Design of Power Screws | Design of Machine Elements - Mechanical Engineering

6.2.2.2F- The screw with the provision for tommy bar attachment

Design of Power Screws | Design of Machine Elements - Mechanical Engineering

6.2.2.4.b F- A typical centrally located tommy bar

 

The document Design of Power Screws | Design of Machine Elements - Mechanical Engineering is a part of the Mechanical Engineering Course Design of Machine Elements.
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FAQs on Design of Power Screws - Design of Machine Elements - Mechanical Engineering

1. What is the purpose of a power screw in mechanical engineering?
Ans. A power screw is commonly used in mechanical engineering to convert rotary motion into linear motion. It is designed to transmit power and provide controlled movement in various applications such as lifting heavy loads or adjusting the position of components.
2. How does the design of a power screw affect its efficiency?
Ans. The design of a power screw plays a significant role in its efficiency. Factors such as the thread pitch, lead angle, and frictional losses determine the mechanical advantage and resulting efficiency of the power screw. A well-designed power screw minimizes friction, maximizes mechanical advantage, and ensures smooth and efficient operation.
3. What are the different types of power screw designs commonly used in mechanical engineering?
Ans. There are several types of power screw designs used in mechanical engineering, including Acme threads, square threads, and buttress threads. Acme threads are commonly used for power transmission and linear motion applications, while square threads offer higher efficiency but are less commonly used. Buttress threads are designed to handle heavy loads in one direction and are often used in applications where a high load-carrying capacity is required.
4. How can the mechanical engineer determine the appropriate power screw design for a specific application?
Ans. The mechanical engineer can determine the appropriate power screw design for a specific application by considering factors such as load requirements, speed, efficiency, and environmental conditions. It is important to analyze the specific application's requirements and constraints to select the appropriate thread type, pitch, and lead angle to ensure optimal performance and reliability.
5. What are the advantages of using power screws over other mechanical motion conversion mechanisms?
Ans. Power screws offer several advantages over other mechanical motion conversion mechanisms. They provide high load-carrying capacity, precise control of linear motion, and the ability to hold positions without the need for external power. Power screws also have a simple and compact design, making them suitable for various applications where linear motion or power transmission is required.
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