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

Introduction 

A power screw is a drive used in machinery to convert a rotary motion into a linear motion for power transmission. It produces uniform motion and the design of the power screw may be such that

(a) Either the screw or the nut is held at rest and the other member rotates as it moves axially. A typical example of this is a screw clamp.

(b) Either the screw or the nut rotates but does not move axially. A typical example for this is a press. Other applications of power screws are jack screws, lead screws of a lathe, screws for vices, presses etc. Power screw normally uses square threads but ACME or Buttress threads may also be used. Power screws should be designed for smooth and noiseless transmission of power with an ability to carry heavy loads with high efficiency. We first consider the different thread forms and their proportions:

Square threads

The thread form is shown in figure-6.1.1.1. These threads have high efficiency but they are difficult to manufacture and are expensive. The proportions in terms of pitch are: h1= 0.5 p ; h2 = 0.5 p - b ; H = 0.5 p + a ; e = 0.5 p a and b are different for different series of threads.

Power Screws & Their Efficiency | Design of Machine Elements - Mechanical Engineering

There are different series of this thread form and some nominal diameters, corresponding pitch and dimensions a and b are shown in table-6.1.1.1 as per I.S. 4694-1968.

 

6.1.1.1T – Dimensions of three different series of square thread form.

Power Screws & Their Efficiency | Design of Machine Elements - Mechanical Engineering

According to IS-4694-1968, a square thread is designated by its nominal diameter and pitch, as for example, SQ 10 x 2 designates a thread form of nominal diameter 10 mm and pitch 2 mm.

Acme or Trapezoidal threads

The Acme thread form is shown in figure- 6.1.1.2. These threads may be used in applications such as lead screw of a lathe where loss of motion cannot be tolerated. The included angle 2φ = 29o and other proportions are

Power Screws & Their Efficiency | Design of Machine Elements - Mechanical Engineering and h = 0.25 p + 0.25 mm

 

Power Screws & Their Efficiency | Design of Machine Elements - Mechanical Engineering

A metric trapezoidal thread form is shown in figure- 6.1.1.3 and different proportions of the thread form in terms of the pitch are as follows: Included angle = 30o ; H1= 0.5 p ; z = 0.25 p + H1/2 ; H3 = h3 = H1+ ac = 0.5 p + ac

ac is different for different pitch, for example
ac = 0.15 mm for p = 1.5 mm ; ac = 0.25 mm for p = 2 to 5 mm;
a = 0.5 mm for p = 6 to 12 mm ; a= 1 mm for p = 14 to 44 mm.

Power Screws & Their Efficiency | Design of Machine Elements - Mechanical Engineering

Some standard dimensions for a trapezoidal thread form are given in table- 6.1.1.2 as per IS 7008 (Part II and III) - 1973:

Power Screws & Their Efficiency | Design of Machine Elements - Mechanical Engineering

According to IS7008-1973 trapezoidal threads may be designated as, for example, Tr 50 x 8 which indicates a nominal diameter of 50 mm and a pitch of 8 mm.

Buttress thread

This thread form can also be used for power screws but they can transmit power only in one direction. Typical applications are screw jack, vices etc. A Buttress thread form is shown in figure- 6.1.1.4. and the proportions are shown in the figure in terms of the pitch. On the whole the square threads have the highest efficiency as compared to other thread forms but they are less sturdy than the trapezoidal thread forms and the adjustment for wear is difficult for square threads.

When a large linear motion of a power screw is required two or more parallel threads are used. These are called multiple start power drives.

 

Power Screws & Their Efficiency | Design of Machine Elements - Mechanical Engineering

Efficiency of a power screw 

A square thread power screw with a single start is shown in figure6.1.2.1. Here p is the pitch, α the helix angle, dm the mean diameter of thread and F is the axial load. A developed single thread is shown in figure- 6.1.2.2 where L = n p for a multi-start drive, n being the number of starts. In order to analyze the mechanics of the power screw we need to consider two cases:

(a) Raising the load
(b) Lowering the load.

Power Screws & Their Efficiency | Design of Machine Elements - Mechanical EngineeringPower Screws & Their Efficiency | Design of Machine Elements - Mechanical Engineering

Raising the load This requires an axial force P as shown in figure- 6.1.2.3. Here N is the normal reaction and μN is the frictional force. For equilibrium

P - μ N cos α - N sin α = 0
F + μ N sin α - N cos α = 0

This gives

Power Screws & Their Efficiency | Design of Machine Elements - Mechanical Engineering

Power Screws & Their Efficiency | Design of Machine Elements - Mechanical Engineering  

Torque transmitted during raising the load is then given by

Power Screws & Their Efficiency | Design of Machine Elements - Mechanical Engineering

Since Power Screws & Their Efficiency | Design of Machine Elements - Mechanical Engineeringwe have

Power Screws & Their Efficiency | Design of Machine Elements - Mechanical Engineering

The force system at the thread during lowering the load is shown in figure- 6.1.2.4. For equilibrium

P - μ N cos α + N sin α = 0
F - N cos α -μ N sin α = 0

This gives

Power Screws & Their Efficiency | Design of Machine Elements - Mechanical Engineering

 

Power Screws & Their Efficiency | Design of Machine Elements - Mechanical Engineering

 

Torque required to lower the load is given by

Power Screws & Their Efficiency | Design of Machine Elements - Mechanical Engineering

And again taking    Power Screws & Their Efficiency | Design of Machine Elements - Mechanical Engineering           we have

Power Screws & Their Efficiency | Design of Machine Elements - Mechanical Engineering

 

Condition for self locking

The load would lower itself without any external force if μπdm < L and some external force is required to lower the load if μπdm < L

This is therefore the condition for self locking.
 

Efficiency of the power screw is given by

Power Screws & Their Efficiency | Design of Machine Elements - Mechanical Engineering

Here work output = F. L

Work input = p. πdm

This gives

Power Screws & Their Efficiency | Design of Machine Elements - Mechanical Engineering

The above analysis is for square thread and for trapezoidal thread some modification is required. Because of the thread angle the force normal to the thread surface is increased as shown in figure- 6.1.2.5. The torque is therefore given by

Power Screws & Their Efficiency | Design of Machine Elements - Mechanical Engineering

This considers the increased friction due to the wedging action. The trapezoidal threads are not preferred because of high friction but often used due to their ease of machining.

Power Screws & Their Efficiency | Design of Machine Elements - Mechanical Engineering

Bursting effect on the nut 

Bursting effect on the nut is caused by the horizontal component of the axial load F on the screw and this is given by ( figure- 6.1.2.5)

F= F tan φ

For an ISO metric nut 2φ = 60o and Fx = 0.5777 F.

 

Collar friction

If collar friction μc is considered then another term μFdc/2 must be added to torque expression. Here dc is the effective friction diameter of the collar. Therefore we may write the torque required to raise the load as

Power Screws & Their Efficiency | Design of Machine Elements - Mechanical Engineering

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

1. What are power screws and how do they work?
Ans. Power screws are mechanical devices used to convert rotational motion into linear motion. They consist of a threaded shaft and a nut that engages with the threads. When the shaft is rotated, the nut moves along the threads, resulting in linear motion.
2. What are the advantages of using power screws?
Ans. Power screws offer several advantages in mechanical engineering applications. They provide high mechanical advantage, allowing for large loads to be moved with relatively low input torque. They also offer precise positioning, self-locking capabilities, and the ability to transmit motion over long distances.
3. How can the efficiency of power screws be determined?
Ans. The efficiency of power screws can be determined by comparing the theoretical effort required to move the load (calculated using the mechanical advantage) to the actual effort required. Efficiency is defined as the ratio of the actual effort to the theoretical effort, expressed as a percentage.
4. What factors affect the efficiency of power screws?
Ans. Several factors can affect the efficiency of power screws. Friction between the threads and the nut, as well as friction in the bearing surfaces, can reduce efficiency. The lead angle of the screw, the pitch of the threads, and the type of lubrication used also play a role in determining efficiency.
5. How can the efficiency of power screws be improved?
Ans. To improve the efficiency of power screws, reducing friction is key. This can be achieved by using lubrication between the nut and the threads, selecting low-friction materials for the screw and nut, and ensuring proper alignment and clearance. Additionally, choosing a suitable lead angle and pitch can optimize efficiency for a specific application.
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