Tips to replace your Fashion Sho Laces | Sunplum.com

With all the technology innovations of sports shoes, choosing the best replacement shoe laces can be a difficult and important task.

Therefore, more knowledge is needed as this knowledge is a power and the decision of a customer to buy on one network and return to buy again can fall on professionalism.

Once you understand the client's needs on a professional level, you are also thinking of moving forward and trying to recreate at the top what will suit him according to body structures, leg width, his previous shoe.

Once you know what's good for him and you explain to him on a professional level, chances are the client will be convinced and come back again.

The best replacement shoe laces that not only improves performance but also allows for proper foot movement and shock absorption and thus protects the client's legs from injuries.

The most important component of professional sneaker fitting is the client's foot structure and behaviour during activity.

The foot movement during a fairly complex activity and the activity involves dozens of muscles and joints.

In order for find the best replacement shoe laces, we need to understand the Foot biomechanics… at https://sunplum.com we researched it fully and here is what we found:

The foot is made up of 28 bones connected through 35 joints.

The architectural structure of the foot bones forms three arches:

1- medial [internal] 2- literal [external] 3- lateral arch

During walking and running, the leg arches collapse thus allowing shock absorption.

While walking / running we land on the outside of the shoe, abrasion on the outside of the heel expresses normal foot activity.

After landing, the foot rolls from the outside to the inside.

The inward roll is called pronation - this is a proper foot process designed to allow shock and elasticity in the front of the foot.

In many trainers, there is a situation of over-fronts, a condition in which the foot rolls too much.

This condition HYPER PRONATION is the main factor in the development of injuries among trainers, such as: stress fractures, inflammation, knee injuries and more.

The opposite problem is a condition in which the foot does not roll in, in this situation the foot does not effectively absorb shocks and this defect can also lead to injuries.

The pushing phase: While walking and running the leg function is: to carry the weight of our bodies, to brake shocks and to allow the pushing forces against the ground to move our bodies forward.

These requirements are basically contrary to each other. In the first stage of shock braking, the leg becomes a rigid structure, the ability of the foot to allow this contrast lies in the anatomical and biomechanical set of the foot.

The rigid structure of the leg is the one that gives it that ability.

Rainbow on the one hand is a very stable engineering structure but on the other hand can also crash easily.

What holds the arch structure is the TALUS bone as soon as there is a change in bone condition it will redefine whether the bow is flexible or rigid.

As the body progresses beyond the foot that is on the ground the whole process changes direction and shape, and at the push of the foot it turns from a flexible structure to a [supination] structure.

Pushing the leg against the ground while the leg is still flexible, puts pressure on the soft tissues, muscles, tendons and ligaments, and as the pressure increases, we feel the injury.

With each leg rigid, pushing efficiency and the ability to transfer power are more effective.

The pushing phase: Stage the braking shock called pronation. The TALUS bone changes its position, causing the arch to collapse [the foot flexes and brakes with the landing shock]. This mechanism is also important to adjust the foot to the soil change, especially when barefoot.

In addition, while the bow collapses, the leg lengthens and therefore the shoe has to be a little larger.

In sporting activities, the market area, knee and thigh contribute to the process of breaking the shock. Also, the pelvic activity tends sideways and then the spine vertebrae twist.