KR102487428B1 - Safety shoes - Google Patents

Abstract

The present invention relates to a safety shoe provided with a toe cap inside the toe to protect the toe from falling objects. In particular, it relates to safety shoes capable of preventing foot injuries by preventing a spring phenomenon.

Description

Safety shoes {Safety shoes}

The present invention relates to a safety shoe provided with a toe cap inside the toe to protect the toe from falling objects.

Safety boots are worn and used by workers at construction sites where falling objects frequently occur.

In these safety shoes, a toe cap made of metal is provided inside the toe of the safety shoe, and through the toe cap, the toe of the operator is protected from falling objects.

As shown in FIG. 1, a conventional safety shoe 1 is provided with a toe cap 3 on top of a midsole 2.

In this case, the bent portion 3a of the toe cap 3 is supported by the upper surface of the midsole 2.

As shown in FIG. 2 , when an impact due to the weight of a falling object is applied to the toe cap 3 , the bent portion 3a presses both sides of the midsole 2 downward. As both sides of the midsole 2 are pressed, the midsole 2 in the region between the bent portions 3a rises due to the characteristics of the midsole 2, which has a large modulus of elasticity and is made of a soft material. In this way, a phenomenon in which a load is applied to the toe cap 3 and the midsole 2 rises is called a spring phenomenon.

The above spring phenomenon reduces the height between the toe cap 1 and the midsole 2, so that the toe cap 100 touches the user's foot, causing injury to the user's foot.

Accordingly, safety shoes for preventing the spring phenomenon have been developed, and patents related to these anti-spring safety shoes include Korean Utility Model Registration No. 20-0290573 (hereinafter referred to as 'Patent Document 1') and Korea Utility Model Registration No. What was described in No. 20-0332257 (hereinafter referred to as 'Patent Document 2') is known.

In the case of Patent Document 1, by incorporating a plurality of steel balls into the front end of the midsole member, even if an external load is applied to the toe cap, the midsole member is not pressed by the diameter of the steel ball to improve the safety of the foot.

However, in the case of Patent Document 1, when the load applied to the toe cap increases, the spring phenomenon occurs because the steel fire presses the soft midsole member.

Even in the case of Patent Document 2, even if the lower portion of the bent portion of the toe cap is supported by the horseshoe-shaped support member, as the load applied to the toe cap increases, a spring phenomenon inevitably occurs.

As above, simply by supporting the bent part of the toe cap with a hard member, the spring cannot be completely prevented, so when an impact is applied to the toe cap by a falling object, the space inside the toe cap is reduced, so that the instep of the toe cap come into contact with it and cause injury.

Korean Utility Model Registration No. 20-0290573 Korean Utility Model Registration No. 20-0332257

The present invention has been made to solve the above problems, and an object of the present invention is to provide a safety shoe capable of preventing injury to the foot by preventing a spring phenomenon.

A safety shoe according to one feature of the present invention, in a safety shoe having a toe cap inside a front nose, includes a spring prevention unit interposed between a midsole and the toe cap, and the spring prevention unit is located on the left side of the midsole. a first support part, the upper surface of which supports the left lower surface of the bent part of the toe cap; a second support part disposed on the right side of the midsole, the upper surface of which supports the right lower surface of the bent part of the toe cap; and a bridge connecting the first support part and the second support part, the lower surface of which is seated on the upper surface of the midsole. Including, the upper surface of the first support portion is provided with a first inclined portion formed to be inclined toward the upper portion of the first support portion toward the left side of the midsole, and the first support portion forms a left side of the bent portion to the left side of the midsole. The uppermost part of the first inclined part is located on the left side of the midsole rather than the lower surface of the bent part so as to have a shape wrapped around the bent part, and the upper surface of the second support part is formed to be inclined toward the upper part of the second support part toward the right side of the midsole. A second inclined part is provided, and the uppermost part of the second inclined part is located on the right side of the midsole rather than the lower surface of the bent part so that the second support part has a shape surrounding the right side of the bent part from the right side of the midsole.

In addition, the material of the anti-spring portion is characterized in that made of a material harder than the material of the midsole.

In addition, a front curved portion corresponding to the front shape of the toe cap is provided at the front of the bridge.

In addition, the bridge is characterized in that it has a shape corresponding to the shape of the insole provided on the upper part of the midsole.

A safety shoe according to another feature of the present invention, in a safety shoe having a toe cap inside a front nose, includes a spring preventing portion interposed between a midsole and the toe cap, wherein the spring preventing portion has a lower surface of the midsole. A bridge installed on the upper surface of; first and second support units connected to the left and right ends of the bridge and respectively installed on the left and right sides of the midsole; and first and second inclined portions provided on each of the first and second support portions so as to surround the left and right sides of the bent portion of the toe cap, and when a load is applied to the toe cap, the first and second support portions It is characterized in that a tensile force is generated in the bridge by applying force in an outward direction of the midsole by the first and second inclined portions.

In addition, as the load applied to the toe cap increases, the tensile force generated in the bridge increases.

In addition, when a load is applied to the toe cap, the first and second support parts are displaced in a direction away from each other.

In addition, it is characterized in that the bridge and the first and second supports are manufactured separately and bonded to each other.

In addition, it is characterized in that the bridge and the first and second support parts are manufactured integrally.

According to the safety boots of the present invention as described above, there are the following effects.

The load applied to the toe cap is transmitted to the first and second supports supporting the toe cap, so that the bridge can be maintained taut. Accordingly, the spring phenomenon can be effectively prevented by the bridge suppressing the rise of the central region of the midsole.

When a load is transmitted to the toe cap through the first and second inclined surfaces of the first and second supports, a tensile force is generated by the first and second supports to keep the bridge more taut, thereby effectively reducing the spring phenomenon. It can be prevented.

The first and second supports are respectively inserted into the first and second grooves to generate a tensile force on the bridge, so that the bridge can be more taut and the midsole can completely suppress rising.

Since each of the first and second support parts functions as a wedge through the third and fourth inclined parts to generate a tensile force in the bridge, the spring phenomenon can be more effectively prevented.

By forming a space in which the first support part and the second support part are movable, the tensile force of the bridge is further increased, and the spring phenomenon can be effectively prevented.

1 is a rear cross-sectional view of a conventional safety shoe.
Figure 2 is a diagram showing a spring phenomenon that occurs when an impact is applied to a conventional safety shoe.
Figure 3 is a side state diagram showing a state wearing safety boots according to the first embodiment of the present invention.
Figure 4 is a rear cross-sectional view of the safety shoe according to the first embodiment of the present invention.
5 is a rear cross-sectional view showing that the sprainback preventing part is coupled to the midsole of FIG. 4;
Figure 6 is a plan view of the anti-spring portion of the safety shoe according to the first embodiment of the present invention.
Figure 7 is a plan view showing a modified example of the bridge of the anti-spring part of the safety shoe according to the first embodiment of the present invention.
8 is a rear cross-sectional view of a safety shoe according to a second embodiment of the present invention.
9 is a plan view of the midsole of FIG. 8;
10 is a rear cross-sectional view of the midsole of FIG. 8;
11 is a rear cross-sectional view showing that the anti-spring portion is coupled to the midsole of FIG. 10;
12 is a rear cross-sectional view of a safety shoe according to a third embodiment of the present invention.
13 is a plan view of the midsole of FIG. 12;
14 is a rear sectional view of the midsole of FIG. 12;
15(a) and 15(b) are perspective views of the anti-spring portion of FIG. 14;
16 is a rear cross-sectional view showing that the spring prevention part of FIGS. 15 (a) and 15 (b) is coupled to the midsole of FIG. 14;
17 is a rear cross-sectional view of a safety shoe according to a fourth embodiment of the present invention.
18 is a rear cross-sectional view of a safety shoe according to a fifth embodiment of the present invention.
19 is a rear cross-sectional view showing that the sprainback preventing part is coupled to the midsole of FIG. 18;

The following merely illustrates the principles of the invention. Therefore, those skilled in the art can invent various devices that embody the principles of the invention and fall within the concept and scope of the invention, even though not explicitly described or shown herein. In addition, it should be understood that all conditional terms and embodiments listed in this specification are, in principle, expressly intended only for the purpose of making the concept of the invention understood, and are not limited to such specifically listed embodiments and conditions. .

The above objects, features and advantages will become more apparent through the following detailed description in conjunction with the accompanying drawings, and accordingly, those skilled in the art to which the invention belongs will be able to easily implement the technical idea of the invention. .

Embodiments described in this specification will be described with reference to sectional views and/or perspective views, which are ideal exemplary views of the present invention. Therefore, embodiments of the present invention are not limited to the specific shapes shown, but also include changes in shapes generated according to manufacturing processes.

Safety shoes 10 according to the first embodiment of the present invention

Hereinafter, the safety shoe 10 according to the first embodiment of the present invention will be described with reference to FIGS. 3 to 6 .

3 is a side state diagram showing a state in which safety boots are worn according to the first embodiment of the present invention, FIG. 4 is a rear cross-sectional view of the safety boots according to the first embodiment of the present invention, and FIG. 5 is a midsole of FIG. A rear cross-sectional view showing that the sprangback preventing part is coupled, and FIG. 6 is a plan view of the spring preventing part of the safety shoe according to the first embodiment of the present invention.

3 to 6, the safety shoe 10 according to the first embodiment of the present invention includes a toe cap 100 provided inside the front nose of the safety shoe 10; and, the toe cap 100 An insole 200 provided on the upper part of the bent part 110 of the; and a midsole 300 provided on the lower part of the insole 200; and a lower part of the midsole 300 to protect the bottom of the safety shoe 10. An outsole 400 formed; and an outer shell 500 that surrounds the outer surface of the toe cap 100 and forms the outer surface and shape of the safety shoe 10; and a spring interposed between the midsole 300 and the toe cap 100 Preventing unit 600; may be configured to include.

The toe cap 100 is provided inside the front nose of the safety shoe 10 and serves to protect the user's foot F.

The toe cap 100 is made of a hard material such as metal.

The toe cap 100 is provided with a bent portion 110 formed to form a part of the bottom surface of the toe cap 100 .

In the toe cap 100, the front wall, the upper wall, the left wall, and the right wall form the front, top, left, and right sides of the toe cap 100, respectively.

The toe cap 100 is formed so that the bent portion 110 formed to be bent and extended under each of the front wall, the left wall, and the right wall forms a part of the bottom surface of the toe cap 100.

Accordingly, the toe cap 100 has a shape in which a portion of the bottom surface is open and the front, top, left, and right surfaces are closed by the front, top, left, and right walls.

The front wall, the upper wall, the left wall, and the right wall are integrally formed to extend with each other, and each of the front wall, the upper wall, the left wall, and the right wall is treated as a curved surface, so that it narrows toward the front of the toe cap 100. It has a streamlined shape as a whole.

The bent part is formed to be bent and extended under each of the front wall, the left wall, and the right wall.

The bent portion forms only a part of the bottom surface of the toe cap 100. The bent portion 110 has a 'U' shape as a whole. Accordingly, the bottom surface of the toe cap 100 has a 'U' shape with an open interior.

The bent portion 110 is bent toward the bottom surface of the toe cap 100 such that the angle between the inner surface of the front wall, the left wall, and the right wall and the upper surface of the bent portion 110 is 90° or more. In this case, the width of the bent portion 110 has a length of several mm to several tens of mm.

An insole 200 is provided above the bent portion 110 of the toe cap 100, and the insole 200 is a part that touches the sole of the foot.

A midsole 300 is provided below the insole 200, and an outsole 400 forming the bottom of the safety shoe 10 is provided below the midsole 300.

In addition, the outer shell 500 is wrapped around the outer surface of the toe cap 100, and this outer shell 500 forms the outer surface and shape of the safety shoe 10.

As described above, the safety shoe 10 may have a multi-layered outsole structure in which the midsole 300 and the outsole 400 are provided below the midsole 300, so that the outsole 400 forms the bottom of the safety shoe 10. .

Unlike this, the safety shoe 10 may have a single-layer outsole structure in which the midsole 300 or the outsole 400 forms the bottom of the safety shoe 10 by being provided with only the midsole 300 or the outsole 400.

Hereinafter, the anti-spring portion 600 will be described.

As shown in FIGS. 4 and 5, the anti-spring part 600 is disposed on the left side of the midsole 300, and its upper surface supports the left lower surface of the bent part 110 of the toe cap 100. 1 support part 610; and a second support part 620 disposed on the right side of the midsole 300, the upper surface of which supports the right lower surface of the bent part 110 of the toe cap 100; and the first support part A bridge 630 connecting the 610 and the second support 620 and having its lower surface seated on the upper surface of the midsole 300; may be configured to include.

In addition, the spring prevention unit 600 is connected to the bridge 630, the lower surface of which is installed on the upper surface of the midsole 300; and the left and right ends of the bridge 630, respectively, so that the load is applied to the toe cap 100. When applied, a tensile force is generated in the bridge 630, and the first and second support parts 610 and 620 are installed on the left and right sides of the midsole 300, respectively.

The first support part 610 is disposed and installed on the left side of the midsole 300, and the second support part 620 is disposed and installed on the right side of the midsole 300.

The first support part 610 and the second support part 620 are connected by a bridge 630 .

The lower surface of the first support part 610 is coupled to the upper left surface of the midsole 300 . Therefore, the first support part 610 is installed on the left upper surface of the midsole 300 .

The upper surface of the first support part 610 supports the left lower surface of the bent part 110 of the toe cap 100.

The upper surface of the first support part 610 is provided with a first inclined part 611 formed in an upper direction of the first support part 610 toward the outer side of the midsole 300 .

The first inclined portion 611 is inclined toward the upper portion of the first support portion 610 toward the left side of the midsole 300 . Accordingly, the first inclined portion 611 is inclined toward the upper portion of the first support portion 610 toward the outer side of the midsole 300 .

The first inclined portion 611 supports the lower left side of the bent portion 110 of the toe cap 100. In other words, the first inclined portion 611 comes into contact with the lower left side of the bent portion 110 of the toe cap 100.

In this case, the uppermost part of the first inclined part 611 is located outside the midsole 300 than the lower left side of the bent part 110 of the toe cap 100. Accordingly, the first support part 610 has a shape surrounding the left side of the bent part 110 of the toe cap 100 from the outside of the midsole 300 .

The lower surface of the second support part 620 is coupled to the right upper surface of the midsole 300 . Therefore, the second support part 620 is installed on the upper right side of the midsole 300 .

The upper surface of the second support part 620 supports the right lower surface of the bent part 110 of the toe cap 100.

The upper surface of the second support portion 620 is provided with a second inclined portion 621 formed in an upper direction of the second support portion 620 toward the outer side of the midsole 300 .

The second inclined portion 621 is inclined toward the top of the second support portion 620 toward the right side of the midsole 300 . Accordingly, the second inclined portion 621 is inclined toward the upper portion of the first support portion 610 toward the outer side of the midsole 300 .

The second inclined portion 621 supports the lower right side of the bent portion 110 of the toe cap 100. In other words, the second inclined portion 621 comes into contact with the lower right side of the bent portion 110 of the toe cap 100.

In this case, the uppermost part of the second inclined part 621 is located outside the midsole 300 than the lower right side of the bent part 110 of the toe cap 100. Accordingly, the second support portion 620 has a shape that surrounds the right side of the bent portion 110 of the toe cap 100 from the outside of the midsole 300 .

The aforementioned first inclined portion 611 and the second inclined portion 621 may be linear inclined portions or curved inclined portions.

The bridge 630 is disposed between the first and second support parts 610 and 620 to connect the first and second support parts 610 and 620 .

The lower surface of the bridge 630 is coupled to the upper surface of the midsole 300 . Accordingly, the bridge 630 is installed on the upper surface of the midsole 300 .

The bridge 630 may connect the first and second supports 610 and 620 by connecting the left and right upper surfaces to the lower surfaces of the first and second supports 610 and 620, respectively.

As shown in FIG. 6 , a front curved portion 631 corresponding to the front shape of the toe cap 100 may be provided at the front of the bridge 630 . Accordingly, the overall shape of the bridge 630 may have the same shape as the shape of the nose of the safety shoe 10.

Unlike the above, as shown in FIG. 7 , the bridge 630a may have other modifications.

Figure 7 is a plan view showing a modified example of the bridge of the anti-spring part of the safety shoe according to the first embodiment of the present invention.

The overall shape of the bridge 630a may have a shape corresponding to that of the insole 200 provided above the midsole 300 .

In this case, the bridge 630a may be interposed between the insole 200 and the midsole 300 .

Therefore, even if the anti-spring portion having the bridge 630a is provided, the safety shoe 10 can be manufactured more conveniently by directly coupling the insole 200 to the top of the bridge 630a without a separate member.

The aforementioned anti-spring portion 600, that is, the material of the bridge 630 and the first and second support portions 610 and 620 may be made of a harder material than that of the midsole 300. Accordingly, the anti-spring portion 600 , that is, the bridge 630 and the first and second support portions 610 and 620 have a lower modulus of elasticity than the midsole 300 .

The bridge 630 and the first and second support parts 610 and 620 may be made of hard reinforced fabric or hard epoxy.

The bridge 630 and the first and second support parts 610 and 620 may be made of the same material or different materials.

The bridge 630 and the first and second support parts 610 and 620 may be integrally formed by injection processing or the like.

The spring prevention unit 600 having the above-described configuration functions to prevent the spring phenomenon by suppressing the front central portion of the midsole 300 from rising when a load is applied to the upper wall of the toe cap 100 by a falling object. do.

In detail, when a load is applied to the upper wall of the toe cap 100 by a falling object, the load is applied to the first inclined portion 611 of the first support portion 610 through the left side of the bent portion 110. The load is transferred to the second inclined portion 621 of the second support portion 620 through the right side of the bent portion 110 .

The bridge 630 is installed in the midsole 300 so that its lower surface is seated and coupled to the upper surface of the midsole 300 in a taut state. As above, when the load is transmitted to the first and second supports 610 and 620, The bridge 630 may suppress the rise of the central portion of the midsole 300 .

Since the first inclined portion 611 is inclined upward toward the left side of the first support portion 610, the force applied to the first inclined portion 611 from the top to the bottom is will act in the left direction of

Since the second inclined portion 621 is inclined upward toward the right side of the second support portion 620, the force applied to the second inclined portion 621 from the top to the bottom is will act in the right direction of

As described above, the load of the falling object is transferred to the bent portion 110 and the first and second inclined portions 611 and 621 of the toe cap 100, and the first and second support portions 610 and 620 are moved in the left and right directions, respectively. force will work.

In other words, the first and second support parts 610 and 620 exert force in the outward direction of the midsole 300 .

As described above, as forces are applied to the first and second supports 610 and 620 in the left and right directions, that is, in the outer direction of the midsole 300, a tensile force acts on the bridge 630.

Due to the tensile force generated by the first and second support parts 610 and 620, the bridge 630 is maintained more taut.

Meanwhile, as the first and second support portions 610 and 620 are pushed down from the top to the bottom, a force acts on the left and right sides of the midsole 300 in a downward direction. Accordingly, the force of rising the central region of the midsole 300 upward is applied.

However, as described above, the bridge 630 maintained taut due to the tensile force effectively suppresses the central region of the midsole 300 from rising upward. Therefore, the area of the midsole 300 provided with the bridge 630 cannot rise upward. Therefore, unlike conventional safety shoes, the safety shoes 10 of the first embodiment of the present invention do not generate a spring phenomenon.

In addition, as the load applied to the toe cap 100 increases, the tensile force acting on the bridge 630 increases, so that the midsole 300 can be more effectively prevented from rising. Thus, the spring can be prevented effectively.

In other words, in the safety shoe 10 according to the first embodiment of the present invention, as the load applied to the toe cap 100 increases, the tensile force generated in the bridge 630 increases, and through this, the spring phenomenon is effectively that can be prevented.

In addition, when a load is applied to the toe cap 100, the first and second support portions 610 and 620 are displaced in a direction away from each other, thereby generating a tensile force in the bridge 630.

As such, the safety shoe 10 according to the first embodiment of the present invention can prevent the spring phenomenon that occurs in conventional safety shoes in advance. Therefore, the space between the upper wall of the toe cap 100 and the upper surface of the midsole 300 is reduced so that the user's instep comes into contact with the upper wall of the toe cap 100, thereby effectively preventing injury to the instep. .

In the anti-spring part 600, the bridge 630 and the first and second support parts 610 and 620 may be manufactured separately and bonded to each other. In this case, the bridge 630 and the first and second support parts 610 and 620 may be made of different materials.

As an example, as shown in FIGS. 8 and 11, the anti-spring portion 600' of the safety shoe 10' according to the second embodiment of the present invention to be described later is a bridge 630 and the first and second The support portions 610' and 620' are separately manufactured and bonded to each other, and are made of different materials.

Unlike the above, in the anti-spring part 600, the bridge 630 and the first and second support parts 610 and 620 may be integrally manufactured. In this case, the bridge 630 and the first and second support parts 610 and 620 may be made of the same material as each other.

As an example, as shown in FIGS. 12, 15(a), 15(b) and 16, the anti-spring part 600 of the safety shoe 10" according to the third embodiment of the present invention to be described later. In "), the bridge 630 and the first and second support parts 610" and 620" are integrally manufactured and made of the same material as each other.

Safety shoes (10') according to the second embodiment of the present invention

Hereinafter, a safety shoe 10' according to a second embodiment of the present invention will be described with reference to FIGS. 8 to 11.

8 is a rear cross-sectional view of a safety shoe according to a second embodiment of the present invention, FIG. 9 is a plan view of the midsole of FIG. 8, FIG. 10 is a rear cross-sectional view of the midsole of FIG. 8, and FIG. 11 is a spring on the midsole of FIG. It is a rear cross-sectional view showing that the prevention part is coupled.

The safety shoe 10' according to the second embodiment of the present invention includes a toe cap 100 provided inside the front nose of the safety shoe 10; and a first groove 310' and a second groove 320' A midsole 300' provided on both sides; and an outsole 400 provided below the midsole 300' to form the bottom of the safety shoe 10; and a midsole 300' and toe cap 100 and an anti-spring portion 600' interposed therebetween, and the anti-spring portion 600' is inserted into the first groove 310' and disposed on the left side of the midsole 300', and its upper surface is toe A first support part 610' supporting the left lower surface of the bent part 110 of the cap 100; and inserted into the second groove 320' and disposed on the right side of the midsole 300', the upper surface of which is A second support part 620' supporting the right lower surface of the bent part 110 of the toe cap 100; and connecting the first support part 610' and the second support part 620', the lower surface of which is the midsole. It may be configured to include; a bridge 630 seated on the upper surface of (300 ').

Compared to the safety boots 10 according to the first embodiment of the present invention, the safety boots 10' according to the second embodiment of the present invention have first and second grooves 310' on both sides of the midsole 300'. , 320') are respectively provided, and the first and second support parts 610' and 620' of the anti-spring part 600', respectively, are inserted into the first and second grooves 310' and 320', respectively. , but the rest of the components are the same. Therefore, in the description of the safety shoes 10 according to the first embodiment of the present invention described above, the configuration of the safety boots 10 'according to the second embodiment of the present invention can be replaced, and the description of the overlapping configuration is omitted.

A first groove 310' is provided on the front left side of the midsole 300', and a second groove 320' is provided on the front right side of the midsole 300'.

The first groove 310' is disposed at a position corresponding to the left side of the bent part 110 of the toe cap 100, and the second groove 320' is located on the right side of the bent part 110 of the toe cap 100. is placed in a position corresponding to

Therefore, the first support part 610' is inserted and positioned inside the first groove 310', and the toe cap 100 supported by the first support part 610' is positioned above the first groove 310'. The left side of the bent portion 110 is located. In addition, the second support part 620' is inserted and positioned inside the second groove 320', and the toe cap 100 supported by the second support part 620' is located above the second groove 320'. The right side of the bent portion 110 of is located.

The first support part 610' is inserted into the first groove 310'. Accordingly, the first support part 610' is installed in the midsole 300' while being inserted into the first groove 310'.

In this case, the shape of the insertion portion of the first support portion 610' is the same as that of the first groove 310' so that the insertion portion of the first support portion 610' is inserted into the first groove 310' without gaps. can be formed.

As an example, in the second embodiment of the present invention, the shape of the insertion part region of the first support part 610' has a rectangular cross section, and the shape of the first groove 310' also has a cross section. It may have a rectangular shape.

The second support part 620' is inserted into the second groove 320'. Accordingly, the second support 620' is installed in the midsole 300' while being inserted into the second groove 320'.

In this case, the shape of the insertion portion of the second support portion 620' is the same as that of the second groove 320' so that the insertion portion of the second support portion 620' is inserted into the second groove 310' without gaps. can be formed.

As an example, in the second embodiment of the present invention, the shape of the insertion part region of the second support part 620' has a rectangular cross section, and the shape of the second groove 320' also has a rectangular cross section. can have a shape.

The bridge 630 connects the first support part 610' and the second support part 620', and the lower surface of the bridge 630 is coupled to the upper surface of the midsole 300'.

The first support part 610', the second support part 620', and the bridge 630 may be manufactured by injection molding as a single body.

The lower surface of the bridge 630 connecting the first support part 610' and the second support part 620' is seated in the upper surface area of the midsole 300' between the first and second grooves 310' and 320'. are combined In this case, the bridge 630 is seated and coupled to the upper surface area of the midsole 300' in a tense state.

In other words, the first support part 610' and the second support part 620' pull the bridge 630 from both sides, and the bridge 630 is seated on the midsole 300' with tension on the bridge 630. Since it is coupled while remaining, the bridge 630 is maintained in a taut state.

The anti-spring portion 600' of the safety shoe 10' according to the second embodiment of the present invention having the above configuration has the first and second support parts inserted into the first and second grooves 310' and 320', respectively. 610', 620'), the spring phenomenon can be more effectively prevented.

In detail, when a load is applied to the upper wall of the toe cap 100 by a falling object, the load is transmitted to the first support part 610' through the left side of the bent part 110, and the bent part 110 ), the load is transmitted to the second support part 620'.

In this case, since the first support part 610' and the second support part 620' are inserted into the first groove 310' and the second groove 320', respectively, a tensile force is continuously applied to the bridge 630. As a result, the bridge 630 may continue to be maintained in a taut state.

Meanwhile, as the first and second support portions 610 and 620 are pressed down from the top to the bottom, a force is applied to the left and right sides of the midsole 300' in a downward direction. Therefore, the force of the midsole 300' rising upward is applied.

However, as described above, the bridge 630 maintained taut due to the tensile force effectively suppresses the central region of the midsole 300' from rising upward. Therefore, the area of the midsole 300' provided with the bridge 630 cannot rise upward. Therefore, the safety shoe 10' of the second embodiment of the present invention does not generate a spring phenomenon.

In addition, as the load applied to the toe cap 100 increases, the tensile force acting on the bridge 630 increases, so that the midsole 300' can be more effectively prevented from rising. Thus, the spring can be prevented effectively.

As described above, as the safety shoe 10' according to the second embodiment of the present invention can prevent the spring phenomenon in advance, the space between the upper wall of the toe cap 100 and the upper surface of the midsole 300' By reducing the instep of the user's foot to come into contact with the upper wall of the toe cap 100, it is possible to effectively prevent injury to the instep.

Safety shoes (10 ") according to the third embodiment of the present invention

Hereinafter, a safety shoe 10" according to a third embodiment of the present invention will be described with reference to FIGS. 12 to 16.

12 is a rear sectional view of a safety shoe according to a third embodiment of the present invention, FIG. 13 is a plan view of the midsole of FIG. 12, FIG. 14 is a rear sectional view of the midsole of FIG. 12, and FIGS. 15(a) and 15( b) is a perspective view of the anti-spring portion of FIG. 14, and FIG. 16 is a rear cross-sectional view showing that the anti-spring portion of FIGS. 15 (a) and 15 (b) is coupled to the midsole of FIG. 14.

The safety shoe 10" according to the third embodiment of the present invention includes a toe cap 100 provided inside the toe of the safety shoe 10; and a first groove provided with a first groove inclined portion 311". (310") and a midsole (300") provided with second grooves (320") provided with second groove inclined portions (321") on both sides; and a safety shoe (10 An outsole 400 forming the bottom of the ); and an anti-spring portion 600" interposed between the midsole 300" and the toe cap 100; and the anti-spring portion 600" includes a first It is inserted into the groove 310" and disposed on the left side of the midsole 300", and a first inclined portion 611"" is provided on the upper surface to support the lower left side of the bent portion 110 of the toe cap 100. A first support part 610 "that is inserted into the second groove 320" and disposed on the right side of the midsole 300 ", and a second inclined part 621 "" is provided on the upper surface thereof to cap the toe cap ( A second support portion 620" supporting the lower right side of the bent portion 110 of 100; and connecting the first support portion 610" and the second support portion 620", the lower surface of which is the midsole 300" ) Can be configured to include; a bridge 630 seated on the upper surface of.

Compared to the safety boots 10' according to the second embodiment of the present invention, the safety shoes 10 "according to the third embodiment of the present invention have first and second grooves 310" and 320", respectively. 1 and 2 groove inclined parts 311" and 321" are provided, respectively, and the first and second inclined parts 611 are provided on the upper surfaces of the first and second supporting parts 610" and 620" respectively of the anti-spring part 600". ", 621") is formed and provided, but the rest of the components are the same. Therefore, with the description of the safety shoe 10 according to the first embodiment of the present invention and the safety shoe 10' according to the second embodiment of the present invention described above, the safety shoe 10 " according to the third embodiment of the present invention ) may be replaced, and descriptions of overlapping configurations are omitted.

A first groove 310" is provided on the front left side of the midsole 300", and a second groove 320" is provided on the front right side of the midsole 300".

The first groove 310" is disposed at a position corresponding to the left side of the bent part 110 of the toe cap 100, and the second groove 320" is located on the right side of the bent part 110 of the toe cap 100. is placed in a position corresponding to

Therefore, the first support part 610" is inserted and positioned inside the first groove 310", and the toe cap 100 supported by the first support part 610" is located above the first groove 310". The left side of the bent portion 110 is located. In addition, the second support part 620" is inserted and positioned inside the second groove 320", and the toe cap 100 supported by the second support part 620" is placed on the top of the second groove 320". The right side of the bent portion 110 of is located.

The first support part 610" is inserted into the first groove 310" of the midsole 300". Accordingly, the first support part 610" is inserted into the first groove 310" and the midsole 300 ") is installed.

A first inclined portion 611" is provided on the upper surface of the first support portion 610" and is inclined toward the outer side of the midsole 300" toward the upper portion of the first support portion 610".

The first inclined portion 611" is formed to be inclined toward the upper side of the first support portion 610" toward the left side of the midsole 300". Therefore, the first inclined portion 611" is formed to be inclined toward the midsole 300". It is formed to be inclined toward the upper direction of the first support part 610 "as it goes toward the outer side of.

The first inclined portion 611" supports the lower left side of the bent portion 110 of the toe cap 100. In other words, the first inclined portion 611" supports the bent portion 110 of the toe cap 100. is tangent to the lower left side of

In this case, the uppermost part of the first inclined portion 611" is located outside the midsole 300" than the lower left side of the bent portion 110 of the toe cap 100. Accordingly, the first support portion 610" has a shape surrounding the left side of the bent portion 110 of the toe cap 100 from the outside of the midsole 300".

The first groove 310" is provided with a first groove inclination portion 311" formed to be inclined toward the lower part of the midsole 300" as it goes toward the outside of the midsole 300". In other words, the first groove 310" is provided with a first groove inclined portion 311" that is inclined toward the lower part of the midsole 300" toward the left side of the midsole 300".

A third inclined portion 613" is provided on the lower surface of the first support portion 610" and is inclined toward the lower portion of the first support portion 610" toward the outer side of the midsole 300". In other words, the lower surface of the first support portion 610" is provided with a third inclined portion 613" that is inclined toward the lower portion of the first support portion 610" toward the left side of the midsole 300".

As described above, as the first groove 310" is provided with the first groove inclined portion 311" and the first support portion 610" is provided with the third inclined portion 613", the first support portion 610 When ") is inserted into the first groove 310", no gap is generated between the first support part 610" and the first groove 310".

Therefore, when the first support part 610" is inserted into the first groove 310", the third inclined part 613" and the first groove inclined part 311" come into contact with each other.

As described above, the first support portion 610" is inserted into the first groove 310". In this case, the shape of the insertion portion of the first support portion 610" is the same as that of the first groove 310" so that the first support portion 610" is inserted into the first groove 310" without gaps. It can be.

Accordingly, the first groove inclined portion 311" and the third inclined portion 613" may be inclined in the same shape as each other.

The above-mentioned first inclined portion 611", third inclined portion 613", and first groove inclined portion 311" may be linear inclined portions or curved inclined portions.

The second support part 620" is inserted into the second groove 320" of the midsole 300". Therefore, the second support part 620" is inserted into the second groove 320" and the midsole 300 ") is installed.

A second inclined portion 621" is provided on the upper surface of the second support portion 620" and is inclined toward the outer side of the midsole 300" toward the top of the second support portion 620".

The second inclined portion 621" is formed to be inclined toward the upper side of the second support portion 620" toward the right side of the midsole 300". Therefore, the second inclined portion 621" is formed to be inclined toward the midsole 300". It is formed to be inclined toward the upper direction of the second support part 620 "as it goes toward the outer direction of.

The second inclined portion 621" supports the lower right side of the bent portion 110 of the toe cap 100. In other words, the second inclined portion 621" supports the bent portion 110 of the toe cap 100. comes into contact with the lower right side of

In this case, the uppermost part of the second inclined portion 621" is located outside the midsole 300" rather than the lower right side of the bent portion 110 of the toe cap 100. Accordingly, the second support portion 620" has a shape surrounding the right side of the bent portion 110 of the toe cap 100 from the outside of the midsole 300".

The second groove 320" is provided with a second groove inclination portion 321" formed to be inclined toward the lower part of the midsole 300" as it goes toward the outside of the midsole 300". In other words, the second groove 320" is provided with a second groove inclined portion 321" that is inclined toward the lower side of the midsole 300" toward the right side of the midsole 300".

A fourth inclined portion 623" is provided on the lower surface of the second support portion 620" and is inclined toward the lower portion of the second support portion 620" toward the outer side of the midsole 300". In other words, the lower surface of the second support portion 620" is provided with a fourth inclined portion 623" that is inclined toward the lower portion of the second support portion 620" toward the right side of the midsole 300".

As described above, as the second groove 320" is provided with the second groove inclined portion 321" and the second support portion 620" is provided with the fourth inclined portion 623", the second support portion 620 When ") is inserted into the second groove 320", no gap is generated between the second support part 620" and the second groove 320".

Accordingly, when the second support portion 620" is inserted into the second groove 320", the fourth inclined portion 623" and the second groove inclined portion 321" come into contact with each other.

As described above, the second support portion 620" is inserted into the second groove 320". In this case, the shape of the insertion portion of the second support portion 620" is the same as that of the second groove 320" so that the second support portion 620" is inserted into the second groove 320" without gaps. It can be.

Accordingly, the second groove inclined portion 321" and the fourth inclined portion 623" may be inclined in the same shape as each other.

The above-described second inclined portion 621", fourth inclined portion 623", and second groove inclined portion 321" may be linear inclined portions or curved inclined portions.

The bridge 630 connects the first support part 610" and the second support part 620", and the lower surface of the bridge 630 is coupled to the upper surface of the midsole 300".

As shown in FIGS. 15(a) and 15(b), the anti-spring portion 600" is integrally formed with a bridge 630, a first support portion 610", and a second support portion 620". It can be.

A front curved portion 631 corresponding to the front shape of the toe cap 100 may be provided at the front of the bridge 630 . Accordingly, the overall shape of the bridge 630 may have the same shape as the shape of the nose of the safety shoe 10.

Unlike the above, the overall shape of the bridge may have a shape corresponding to that of the insole 200 provided on top of the midsole 300", as in the bridge 630a of another modified example of FIG. 4 described above. This Even in this case, the bridge may be integrally formed with the first and second support portions 610" and 620".

The lower surface of the bridge 630 connecting the first support part 610" and the second support part 620" is seated on the upper surface area of the midsole 300" between the first and second grooves 310" and 320". In this case, the bridge 630 is seated and coupled to the upper surface area of the midsole 300" in a tense state.

In other words, the first support part 610" and the second support part 620" pull the bridge 630 from both sides, and the bridge 630 is seated on the midsole 300" with tension on the bridge 630. Since it is coupled while remaining, the bridge 630 is maintained in a taut state.

The anti-spring part 600 "of the safety shoe 10" according to the third embodiment of the present invention having the above configuration has the first and second support parts inserted into the first and second grooves 310 "and 320", respectively. 610", 620"), the spring phenomenon can be more effectively prevented.

When a load is applied to the upper wall of the toe cap 100 by a falling object, the load is transmitted to the first inclined portion 611" of the first support portion 610" through the left side of the bent portion 110, The load is transmitted to the second inclined portion 621" of the second support portion 620" through the right side of the bent portion 110.

In this case, since the first inclined portion 611" is inclined upward toward the left side of the first support portion 610", the force applied to the first inclined portion 611" from the top to the bottom is It acts in the left direction of the first support part 610".

In addition, since the second inclined portion 621" is inclined upward toward the right side of the second support portion 620", the force applied to the second inclined portion 621" from the top to the bottom is It acts in the right direction of the second support part 620".

As described above, the weight of the falling object is transferred to the bent portion 110 of the toe cap 100 and the first and second inclined portions 611" and 621", and the left side of the first and second support portions 610" and 620", respectively. and the force acts in the right direction.

In other words, the first and second support portions 610" and 620" exert force in an outward direction of the midsole 300".

As described above, as forces are applied to the first and second supports 610" and 620" in the left and right directions, that is, in the outer direction of the midsole 300", a tensile force is applied to the bridge 630.

In addition, since each of the first support part 610 "and the second support part 620" is inserted into the first groove 310 "and the second groove 320", a tensile force is continuously applied to the bridge 630. do.

As described above, tension is applied to the bridge 630 by the first and second grooves 310" and 320" and the first and second inclined portions 611" and 621".

Furthermore, when a load is applied to the first support part 610", since the third inclined part 613" of the first support part 610" is in contact with the first groove inclined part 311", the first support part 610 "), as the load is applied, the force acts in the left direction of the first support part 610". That is, the left side of the first support portion 610", that is, the midsole The force acts in the outer direction of (300").

In addition, when a load is applied to the second support portion 620", the fourth inclined portion 623" of the second support portion 620" is in contact with the second groove inclined portion 321", so that the second support portion 620 "), as the load is applied, the force acts in the right direction of the second support part 620". That is, the right side of the second support part 620", that is, the midsole The force acts in the outer direction of (300").

As described above, the shapes of the first and second inclined portions 611" and 621" and the third and fourth inclined portions 613" and 623" of the first and second supporting portions 610" and 620", and the first, The shape of the first and second groove inclined portions 311" and 321" of the two grooves 310" and 320" and the first and second support portions 610" and 620" have the first and second grooves 310" and 320 ") Due to the configuration in which each is inserted without gaps, when the load of the falling object is transmitted to the toe cap 100, a tensile force is generated in the bridge 630 through the first and second supports 610" and 620", Due to this, the bridge 630 can be continuously maintained in a taut state.

Meanwhile, as the first and second support portions 610" and 620" are pressed down from the top to the bottom, a force is applied to the left and right sides of the midsole 300" in a downward direction. Therefore, the midsole ( 300") acts as a force rising upward.

However, as described above, the bridge 630 kept taut due to the tensile force effectively suppresses the central region of the midsole 300" from rising upward. Therefore, the midsole 300" provided with the bridge 630 The area of cannot rise to the top. Therefore, the safety shoe 10 "of the third embodiment of the present invention does not generate a spring phenomenon.

In addition, as the load applied to the toe cap 100 increases, the tensile force acting on the bridge 630 increases, thereby preventing the midsole 300" from rising more effectively. Thus, the spring This can be effectively prevented.

As described above, as the safety shoe 10" according to the third embodiment of the present invention can prevent the spring phenomenon in advance, the space between the upper wall of the toe cap 100 and the upper surface of the midsole 300" is By reducing the instep of the user's foot to come into contact with the upper wall of the toe cap 100, it is possible to effectively prevent injury to the instep.

Safety shoes (10a) according to the fourth embodiment of the present invention

Hereinafter, a safety shoe 10a according to a fourth embodiment of the present invention will be described with reference to FIG. 17 .

17 is a rear cross-sectional view of a safety shoe according to a fourth embodiment of the present invention.

As shown in FIG. 17, the safety shoe 10a according to the fourth embodiment of the present invention includes a toe cap 100 provided inside the front nose of the safety shoe 10a; and a first groove inclined portion 311a. A midsole 300a having a first groove 310a having a and a second groove 320a having a second groove inclined portion 321a provided on both sides; and a safety shoe provided at the bottom of the midsole 300a ( It includes an outsole 400 forming the bottom of 10); and an anti-spring portion 600a interposed between the midsole 300a and the toe cap 100, and the anti-spring portion 600a includes a first groove ( 310a) is disposed on the left side of the midsole 300a, and a first inclined portion 611a is provided on the upper surface to support the lower left side of the bent portion 110 of the toe cap 100. ); And, it is inserted into the second groove 320a and disposed on the right side of the midsole 300a. A second support part 620a supporting the; and a bridge 630 connecting the first support part 610a and the second support part 620a, the lower surface of which is seated on the upper surface of the midsole 300a; The depth of the first groove 310a is formed deeper than the height of the first support 610a so that a space is formed between the bottom of the first groove 310a and the lower surface of the first support 610a. The depth of the second groove 320a may be formed deeper than the height of the second support portion 620a so that a space is formed between the bottom of the second groove 320a and the lower surface of the second support portion 620a.

As described above, the safety shoe 10a according to the fourth embodiment of the present invention is compared to the safety shoe 10 "according to the third embodiment of the present invention in the first groove 310a and the second groove 320a, respectively. There is a difference in the size of the inserted first support part 610a and the second support part 620a, but the rest of the components are the same. Therefore, description of the safety shoe 10 " according to the third embodiment of the present invention described above Thus, the configuration of the safety shoe 10a according to the fourth embodiment of the present invention can be replaced, and description of the overlapping configuration will be omitted.

The depth of the first groove 310a is formed deeper than the height of the first support part 610a. That is, the height of the first support portion 610a is smaller than the depth of the first groove 310a.

Therefore, when the first support part 610a is inserted into the first groove 310a, a space is formed between the lower surface of the first support part 610a and the bottom surface of the first groove 310a.

In addition, when the first support part 610a is inserted into the first groove 310a, the third inclined part 613a of the first support part 610a is the upper part of the first groove inclined surface 311a of the first groove 310a. come into contact with the area.

The depth of the second groove 320a is formed deeper than the height of the second support part 620a. That is, the height of the second support portion 620a is smaller than the depth of the second groove 320a.

Therefore, when the second support part 620a is inserted into the second groove 320a, a space is formed between the lower surface of the second support part 620a and the bottom surface of the second groove 320a.

In addition, when the second support part 620a is inserted into the second groove 320a, the fourth inclined part 623a of the second support part 620a is the upper part of the second groove inclined surface 321a of the second groove 320a. come into contact with the area.

In the safety shoe 10a according to the fourth embodiment of the present invention having the above-described configuration, a higher tensile force is exerted on the bridge 630 compared to the safety shoe 10 " according to the third embodiment of the present invention, thereby reducing the spring phenomenon. more effectively prevented.

In detail, when a load is applied to the upper wall of the toe cap 100 by a falling object, the load is transmitted to the first support part 610a.

Thereafter, due to the first inclined portion 611a and the third inclined portion 613a, the load transmitted to the first support portion 610a is directed toward the lower left side of the safety shoe 10a, that is, the midsole 300a. Force acts on the first support portion 610a. Since a space is formed between the lower surface of the first support part 610a and the bottom surface of the first groove 310a, the first support part 610a is formed along the third inclined part 613a and the first groove inclined surface 311a. It moves to the lower left side of the safety shoe 10a, that is, the midsole 300a.

In addition, when a load is applied to the upper wall of the toe cap 100 by a falling object, the load is also transmitted to the second support part 620a.

Thereafter, due to the second inclined portion 621a and the fourth inclined portion 623a, the load transmitted to the second support portion 620a is directed toward the lower right side of the safety shoe 10a, that is, the midsole 300a. Force acts on the first support portion 610a.

Since a space is formed between the lower surface of the second support part 620a and the bottom surface of the second groove 320a, the second support part 620a is formed along the fourth inclined part 623a and the second groove inclined surface 321a. It moves to the lower right side of the safety shoe 10a, that is, the midsole 300a.

As described above, as the first support portion 610a and the second support portion 620a are moved to the lower left and lower right portions of the safety shoe 10a, respectively, the bridge generated by the first support portion 610a and the second support portion 620a The tensile force of 630 is generated more. Therefore, spring phenomenon caused by falling objects can be more effectively prevented.

As described above, the safety shoe 10a according to the fourth embodiment of the present invention forms a space in which the first support portion 610a and the second support portion 620a can move, thereby forming a safety shoe 10" according to the third embodiment. By making the tensile force of the bridge 630 greater than that, the spring phenomenon can be effectively prevented.

Safety shoes (10b) according to the fifth embodiment of the present invention

Hereinafter, a safety shoe 10b according to a fifth embodiment of the present invention will be described with reference to FIGS. 18 and 19 .

18 is a rear cross-sectional view of a safety shoe according to a fifth embodiment of the present invention, and FIG. 19 is a rear cross-sectional view showing that the sprainback preventing part is coupled to the midsole of FIG. 18 .

The safety shoe 10b according to the fifth embodiment of the present invention includes a toe cap 100 provided inside the front nose of the safety shoe 10b; and a first groove 310b having a first groove inclined portion 311b. ) And a midsole (300b) provided on both sides of the second groove (320b) provided with a second groove inclined portion (321b); and an outsole ( 400); and a spring preventing portion 600b interposed between the midsole 300b and the toe cap 100; the spring preventing portion 600b includes a first groove formed on the left side of the midsole 300b ( 310b), the upper surface of which supports the left lower surface of the bent part 110 of the toe cap 100; and the second groove 320b formed on the right side of the midsole 300b A second support part 620b is inserted and supports the right lower surface of the bent part 110 of the upper surface toe cap 100; and the upper surface of the first support part 610b goes to the left side of the midsole 300b. A first inclined portion 611b formed to be inclined in an upward direction of the first support portion 610b is provided, and an upper surface of the second support portion 620b is provided toward the upper side of the second support portion 620b toward the right side of the midsole 300b. When a load is applied to the toe cap 100, a force is generated in the lower left direction of the midsole 300b by the first support part 610b. Force is generated in the lower right direction of the midsole 300b by the support portion 620b.

As described above, the safety shoe 10b according to the fifth embodiment of the present invention has a difference in that the bridge is not provided compared to the safety shoe 10 " according to the third embodiment of the present invention, but the remaining components are Therefore, in the description of the safety shoe 10 " according to the third embodiment of the present invention described above, the configuration of the safety shoe 10b according to the fifth embodiment of the present invention can be replaced, and the configuration overlaps. The description is omitted.

As described above, even in the case of the safety shoe 10b according to the fifth embodiment of the present invention without a bridge, when a load is applied to the upper wall of the toe cap 100 by a falling object, the first groove inclined surface 311b , Force is applied to the first support part 610b in the lower left direction of the safety shoe 10b, that is, the midsole 300b, by the first inclined part 611b and the third inclined part 613b, and the second groove Force is applied to the second support portion 620b in the lower right direction of the safety shoe 10b, that is, the midsole 300b, by the inclined surface 321b, the second inclined portion 621b, and the fourth inclined portion 623b. .

In summary, when a load is applied to the toe cap 100, the first and second support portions 610b and 620b are displaced in directions away from each other.

As such, as force is applied to the first support portion 610b and the second support portion 620b in both directions of the safety shoe 10b, that is, the midsole 300b due to the load of the falling object, the midsole 300b itself has a tensile force This occurs, and as the load applied to the toe cap 100 increases, the tensile force generated in the midsole 300b increases.

As described above, since the tensile force of the midsole 300b increases as the load of the falling object is applied, the spring phenomenon can be prevented.

In the safety shoe 10b according to the fifth embodiment of the present invention, even if a bridge connecting the first support part 610b and the second support part 620b is not separately provided, a tensile force is generated in the midsole 300b itself, and the spring phenomenon can be prevented.

The present invention has been described with reference to the embodiments shown in the drawings, but these are merely exemplary, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the attached claims.

10, 10', 10", 10a, 10b: safety boots
100: toe cap 110: bent portion
200: Insoles
300, 300', 300", 300a, 300b: Midsole
310', 310", 310a, 310b: first groove
311 ", 311a, 311b: first groove slope
320', 320", 320a, 320b: 2nd groove
321", 321a, 321b: 2nd groove slope
400: outsole 500: outer skin
600, 600', 600", 600a, 600b: anti-spring
610, 610', 610", 610a, 610b: first support
611, 611 ", 611a, 611b: first slope
613 ", 613a, 613b: third slope
620, 620', 620 ", 620a, 620b: second support
621, 621 ", 621a, 621b: second slope
623 ", 623a, 623b: 4th slope
630, 630a: bridge 631: front curved portion

Claims (9)

In the safety boots provided with a toe cap inside the front nose,
Including; spring prevention part interposed between the midsole and the toe cap,
The spring prevention part,
a first support part disposed on the left side of the midsole, the upper surface of which supports the left lower surface of the bent part of the toe cap;
a second support part disposed on the right side of the midsole, the upper surface of which supports the right lower surface of the bent part of the toe cap; and
a bridge connecting the first support part and the second support part, the lower surface of which is seated on the upper surface of the midsole; including,
A first inclined portion is provided on the upper surface of the first support portion to be inclined toward the upper portion of the first support portion toward the left side of the midsole,
The uppermost part of the first inclined part is located on the left side of the midsole rather than the lower surface of the bent part so that the first support part has a shape surrounding the left side of the bent part from the left side of the midsole,
The upper surface of the second support portion is provided with a second inclined portion inclined toward the upper portion of the second support portion toward the right side of the midsole,
Safety boots, characterized in that the uppermost part of the second inclined portion is located on the right side of the midsole rather than the lower surface of the bent portion so that the second support portion has a shape surrounding the right side of the bent portion from the right side of the midsole. According to claim 1,
Safety shoes, characterized in that the material of the anti-spring portion is made of a harder material than the material of the midsole. According to claim 1,
Safety shoes, characterized in that the front of the bridge is provided with a front curved portion corresponding to the front shape of the toe cap. According to claim 1,
Safety boots, characterized in that the bridge has a shape corresponding to the shape of the insole provided on the upper part of the midsole. In the safety boots provided with a toe cap inside the front nose,
Including; spring prevention part interposed between the midsole and the toe cap,
The spring prevention part,
a bridge whose lower surface is installed on the upper surface of the midsole;
first and second support units connected to the left and right ends of the bridge and respectively installed on the left and right sides of the midsole; and
Including; first and second inclined portions provided on each of the first and second support portions to surround the left and right sides of the bent portion of the toe cap, respectively;
Safety shoes, characterized in that when a load is applied to the toe cap, the first and second support parts generate a tensile force in the bridge by applying force in an outward direction of the midsole by the first and second inclined parts. According to claim 5,
Safety shoes, characterized in that the tensile force generated in the bridge increases as the load applied to the toe cap increases. According to claim 5,
When a load is applied to the toe cap, the first and second support parts are displaced in a direction away from each other. According to claim 5,
Safety boots, characterized in that the bridge and the first and second support parts are manufactured separately and bonded to each other. According to claim 5,
Safety shoes, characterized in that the bridge and the first and second support parts are integrally manufactured.

Images