KR20090002659U - Work shoes with magnet inserted - Google Patents

Abstract

The present invention was devised to prevent frequent slippage when working on the steel plate and to promote stable work. The magnet is built into the shoe sole to enhance the manpower with the iron plate and to block the magnetic force when moving fast. It is an object of the present invention to provide a magnet working shoe.

Magnet, work shoes

Description

Work shoes with magnet inserted}

The present invention relates to a work shoes, and more particularly to a work shoes with a magnet built in to prevent slipping when working on the iron plate.

Most shipbuilding and shipbuilding work is done on steel plates. In this case, workers wear work shoes, but the steel plate has a small friction, so if carelessly slips, it may lead to injuries, and especially in inclined areas, sea water, or rain, it may face a very dangerous situation.

In fact, the work on the iron plate is often intervened not only on board the ship, but also when transporting or unloading goods in the factory, and many workers are exposed to such risks unsafely, so safety measures are urgently needed.

Most of the conventional shoes using magnets were developed for health promotion purposes such as acupressure and blood flow improvement, and specialized research from the prior art is required for stable landing on an iron plate.

The present invention was devised to prevent frequent slippage when working on the steel plate and to promote stable work. The magnet is built into the shoe sole to enhance the manpower with the iron plate and to block the magnetic force when moving fast. It is an object of the present invention to provide a magnet working shoe.

In order to achieve the above object, the present invention is a magnet mounted horizontally to the sole; A magnet mounting groove accommodating the magnet and formed in a size and shape such that the magnet can move horizontally; A position adjusting portion formed of a rigid body, one end of which is coupled to the magnet and the other end of which extends to the outside of the shoe, and has an adjustment lever at the end extending to the outside; And a magnetic shield coupled to a part of the bottom surface of the magnet mounting groove, by moving the control lever so that the magnet can be moved between a position where the magnetic shield is provided and a position not provided in the magnet mounting groove. It provides a magnetic work shoes, characterized in that configured to be.

According to the present invention, by embedding a magnet in the sole so that it can be magnetically coupled with the iron plate to prevent slipping when working on the iron plate, and adjust the position exposed to the outside of the shoe in situations where magnetic force is not required, such as fast movement or safe The magnetic force can be easily cut off by changing the position of the magnet using the lever, thereby providing a magnet work shoe which is very useful when working on a steel plate.

In addition, the structure is simple, the manufacturing process is simple and the cost increase can be minimized, thereby meeting the required economics.

Hereinafter, specific embodiments of the present invention will be described with reference to the accompanying drawings.

1 is a view illustrating the use of the work shoes according to the present invention, the magnet 2 is embedded in the shoe sole 1 to stably land through the magnetic coupling when stepping on the external iron plate, the position exposed to the outside It can be seen that the magnet can be horizontally rotated using the adjusting unit 3.

The magnet should be buried by a suitable method in a position where magnetic force with the iron plate in the shoe sole can be easily formed, but foreign matter gets stuck in the embedded magnet or does not impair the durability of the shoe.

The specific embedding position of the magnet is preferably installed on the heel side of the shoe in which the foot ball is located horizontally, but if necessary, the embedding position is a part that can be modified in various ways such as heel side or overall distribution. Also, the height of the buried in the sole may be the lowest of the sole where the magnet is exposed on the sole surface of the shoe, but if there is no major obstacle to the release of magnetic force, the buried in the sole is sealed inside the sole as shown in the drawing in terms of durability of the shoe or maintaining the functionality of the magnet desirable.

The method of embedding the magnet is a method of insert injection or the like, and when the sole of the shoe is molded, the magnet is first installed and molded integrally with the shoe sole.

As such, it is advantageous to maintain the durability and magnetic force function of the shoe so that the magnet is not exposed to the outside, and it is also convenient to couple the magnetic shield to be described later, and is a method of simplifying the overall manufacturing process of the shoe.

Figure 2 shows an embodiment of the magnet buried structure inside the shoe sole 1, a magnet mounting groove (4) is formed in the shoe sole (1) up to about twice the size of the magnet and the magnet mounting groove (4) The magnetic shielding portion 5 is provided in an area that can cover the entire magnet on a part of the bottom surface.

The magnet mounting groove 4 is a space in which the magnet can move horizontally in the sole 1, a means 41 for providing a rotation axis of the position adjusting unit, a limit space 42 for limiting the movement range, and the like. It is formed in a structure including, the specific structure is a part that can be variously modified according to the connection method of the position adjusting unit and the magnet in addition to the illustration of the drawings.

The magnetic shield 5 is a component that blocks the magnetic force of the magnet 2 so that it can be converted to the function of general work shoes when magnetic force is unnecessary, lead, mercury, zinc, copper, titanium, austenite series It is formed by using materials that can play the role of magnetic shielding, such as stainless steel, silicon steel sheet, etc.

Since the magnetic shield 5 will form a certain height, to make the bottom surface of the magnet mounting groove flat after the magnetic shield is coupled, the magnetic shielding portion of the magnetic mounting groove is to be combined. It will be necessary to form 43.

Of course, even if the height of the portion where the magnetic shield 5 is formed to increase the height of the magnet will not be a big problem, but if possible, make the bottom height of the magnet mounting groove constant and mount the magnet on the floor It would be advantageous to ensure the stability of the operation and the durability of the product.

The magnet moves horizontally in the magnet mounting groove 4, and reciprocates between a position where the magnetic force blocking portion 5 is provided at a lower portion and a position not provided, thereby providing two functions of magnetic force blocking and magnetic force emission. do.

In other words, when the magnet 2 moves to a position where the magnetic force blocking portion 5 is provided at the lower portion thereof, the magnetic force is blocked so that magnetic coupling with an external iron plate is impossible, and the magnetic force blocking portion 5 is not provided. If you move to there is no magnetic force blocking effect, the magnetic force of the magnet (2) is transmitted to the outside as it is possible to combine the magnetic plate with the external iron plate.

In this way, it is possible to realize that the magnet can be moved between the position where the magnetic shield is coupled and the position where it is not, by the position adjusting portion 3 coupled to the magnet.

The position adjusting unit 3 is formed of a rigid body so that the operator can operate to change the position of the magnet, one end is connected to the magnet, the other end is formed to extend out of the shoe, the control lever 31 on the outer end The operator can move the control lever 31 so that the position of the magnet can be easily adjusted.

Looking at one embodiment of the position adjusting unit 3 in more detail with reference to the drawings, the fitting groove to the projection 21 provided on the magnet for connecting to the magnet and to be able to flow in the horizontal movement ( 32 is formed, and the end side 32 exposed to the outside may be rotatably fixed by the corresponding portion 41 and the coupling means 34 of the sole to serve as a rotation axis.

The present invention is a technical idea that the magnet is mounted on the shoe sole is switched to any one of the two states of the magnetic discharge and the magnetic block, the coupling relationship between the above-described magnet and the position control unit is sufficient if one of the various conventional methods are adopted. It is clear that the specific binding relationship is not a technical feature of the present invention.

3 and 4 is an exemplary view using the position adjusting unit 3, one end of the position adjusting unit 3 is coupled to the upper portion of the magnet and the other end is exposed to the outer portion of the shoe sole, the portion exposed to the outside The control lever 31 provided is moved within two position limits of the magnetic force release position and the magnetic force blocking position. As a result, the operator moves the control lever 31 to horizontally move the magnet 2 connected to the position adjusting unit 3 between a position where the magnetic force blocking portion 5 is provided and a position where the magnetic force blocking portion is not provided. You can choose.

3 is a case where the magnet is located at a position where the magnetic shield 5 is not provided in the lower portion of the magnet, and the magnetic force is released to be magnetically coupled to the iron plate, and FIG. 4 shows the magnetic shield 5 at the lower portion of the magnet. In the case where the magnet is located at the position provided with), the magnetic force is blocked to facilitate the movement.

In this embodiment, as a preferred embodiment, the movement in the left and right directions with respect to the bottom surface is presented. In addition, the magnet is movable in any direction in the range of up, down, left and right on the bottom surface.

In addition, the magnet may be configured such that in addition to the horizontal movement, the magnet can be rotated 180 degrees against the bottom surface between the magnetic shielding surface and the magnetic surface provided with the end portion of the magnetic force in the magnet mounting groove, the outer steel plate of the magnet The magnetic shield is applied directly to the opposite side of the surface to be combined with or coupled to it, and the magnet is rotated more than 180 degrees in the magnet mounting groove with the position adjusting portion as the rotation axis, and either the magnetic surface or the magnetic shield surface is opposite to the bottom surface. To make it possible.

In this case, the control lever installed at the externally exposed end (outer end) provides two position limits of the magnet face and the magnetic force cut off face, allowing the operator to rotate the magnet 180 degrees using the control lever. It is obvious that the magnet and the magnet mounting groove should be configured to be easily rotated by 180 degrees with respect to the position adjusting part of the rotating shaft of the magnet.

1 is an exemplary view of the use of working shoes according to the present invention.

Figure 2 is a detailed view of the sole according to the present invention.

Figure 3 is a detailed view of the connection structure of the magnet, the magnet mounting groove and the position control in the magnetic release position.

Figure 4 is a detailed view of the connection structure of the magnet, the magnet mounting groove and the position control in the magnetic blocking position.

<Description of the major reference numerals>

1: shoe sole 2: magnet

3: Position adjusting unit 31: Control lever

4: magnet mounting groove 5: magnetic shield

Claims (6)

A magnet mounted horizontally on the sole; A magnet mounting groove formed in the shoe sole to accommodate the magnet and have a size and shape such that the magnet can move horizontally; A position adjusting portion formed of a rigid body, one end of which is coupled to the magnet and the other end of which extends to the outside of the shoe, and has an adjustment lever at the end extending to the outside; And a magnetic shield formed in a portion of the bottom surface of the magnet mounting groove to cover an entire magnet, and the magnetic lever is moved within the magnet mounting groove by moving the control lever. Magnetic work shoes, characterized in that configured to be moved between and not provided. The magnet work shoe according to claim 1, wherein the magnet mounting groove is formed inside the shoe sole so as not to be exposed to the floor. The magnetic mounting groove of claim 1, wherein the magnetic mounting groove is formed by the height of the magnetic shielding portion so that the entire bottom surface of the magnetic mounting groove is flat when the magnetic shielding portion is formed on the bottom surface of the magnetic mounting groove. Magnetic work shoes, characterized in that formed in (iii). The magnet working shoe according to claim 1, wherein one end of the position adjusting part is connected to an upper part of the magnet. 2. The magnet work shoe according to claim 1, wherein the control lever is formed on an outer portion of the sole. 2. The magnet work shoe according to claim 1, wherein the magnet and the magnet mounting groove are formed on the heel of the shoe.

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