RU60842U1 - SHOES WITH VENTILATION (OPTIONS) - Google Patents

Abstract

The utility model relates to the shoe industry, and can be used in the manufacture of ventilated shoes. The technical result is a simplification of the design of ventilated shoes, improving operational properties associated with the simplification of the rules for using shoes. An additional technical result according to option 2 is a reduction in the material consumption of shoes, an increase in hygienic properties. The essence of the claimed utility model according to option 1 is that footwear with ventilation contains a top blank with a sole, an insole made of elastic material, and an intake valve system. At the same time, the insole is hermetically connected along the perimeter with the sole and has perforations, and the intake valve system is made in the form of a valve layer attached to the insole from below, the valves of which cover the insole perforations from below. In this case, the space between the insole and the sole is filled with shock absorbing elements attached to the sole, and for the removal of moist air from this space, the shoes contain an exhaust valve with a channel. The exhaust valve may be located in the unloaded area of the arch of the foot in the hole of the sole or side - at the junction of the insole and the sole. The essence of the claimed utility model according to option 2 is that shoes with ventilation contains a workpiece top with a sole, an insole made of elastic material, and a system of intake valves. In this case, the insole is hermetically connected along the perimeter with the sole, and has perforation holes in the form of slots with a trapezoidal cross section with the formation of inlet valves. In this case, the angle formed by the straight lines on which the lateral sides of the trapezoid of the said section lie are equal to 10-20 degrees, and the bases of this trapezoid are formed by the insole surfaces. The slope of the bisector of the previously mentioned angle relative to the height of the trapezoid is 30-60 degrees. At the same time, the space between the insole and the sole is filled with shock absorbing elements attached to the sole, and for the removal of moist air from the said space, the shoes contain an exhaust valve.

The exhaust valve may be located in the unloaded area of the arch of the foot in the hole of the sole or side - at the junction of the insole and the sole. The exhaust valve may be located in the unloaded area of the arch of the foot in the hole of the lower layer or on the side at the junction of the upper and lower layers. 6 c.p., 13 ill.

Description

The utility model relates to the shoe industry, and can be used in the manufacture of ventilated shoes.

The purpose of the utility model is to increase the hygienic properties of various types of household and sports shoes and simplify the design of ventilated shoes.

Ventilated shoes are famous.

A well-known group of ventilated shoes (USSR AS No. 350453, A 43 B 7/06, 1972 [1], USSR AS No. 1169598, A 43 B 7/06, 1985 [2]), in which ventilation occurs by creating excess pressure in the interior of the shoe. Shoes are equipped with a piston pump, are structurally complicated and have insufficiently high operational properties, due to the long and, accordingly, unreliable flexible channel that communicates the pump chamber with the atmosphere. In addition, the design features of the pump narrow the varieties of ventilated shoes of this design due to the need to perform heels and shafts in it, i.e. in fact, varieties of ventilated shoes of this design are reduced only to rubber boots.

A well-known group of ventilated shoes (French patent for the invention N2558044, A 43 B 7/08, 1985 [3]; RF patent for the invention No. 21118501, A 43 B 7/06, 1998 [4]), containing the upper with the sole forming with an insole, a chamber of an air pump equipped with a spring, inlet and outlet valves, in communication with the interior of the shoe and connected to the air intake channel.

This shoe combines the implementation of ventilation by creating excess pressure in the inner space of the shoe and the increased working volume of the air pump chamber as a result of its part being placed over the insole located in the area of the heel of the foot, made in the form of a thrust surface and which in turn is the central component of the upper elastic the walls of the chamber of the air pump. At the same time, shoes have drawbacks consisting in the complexity of the design due to the introduction of additional elements in the shoe design - a thrust bearing and a spring. In addition, the design is not suitable for drying shoes.

Known insole for footwear with ventilation of the foot according to the patent of the Russian Federation for utility model No. 27888, A 43 B 7/28, 2003 [5], consisting of a soft, shock-absorbing

porous material located in the pads, while walking allows you to ventilate the foot through the holes located around the perimeters of the pads.

Also known is an insole for shoes according to the patent of the Russian Federation for the invention No. 2129822, A 43 B 17/08, 1999 [6], consisting of two layers with cavities, protrusions and channels, the lower flat layer is made of a form-resistant material, and the upper layer is made of elastic material and duplicated by material.

The disadvantage of these insoles is that they allow only forced air circulation in the interior of the shoe, and are not intended to remove humid air from this space outside the shoe.

Also known is an insole for shoes according to the patent of the Russian Federation for utility model No. 49430, A 43 B 17/08, 2005 [7], consisting of two layers connected to each other by means of a tube equipped with an “unloading” valve, providing in the lower layer an excess pressure, the upper layer has perforations and a cavity with a channel located under the arch of the foot, with an inlet and outlet valve for filling the cavity with air and passing air through the channel into the lower layer, deflectors mounted in the sub-finger section of the upper layer are made in the form e cylinder with a spherical head with holes.

The specified insole has a complex structure with a large set of small heterogeneous parts, which makes its production more expensive and reduces reliability. In addition, the insole is designed to supply air to the interior of the shoe, and its use is therefore limited by the creation of air circulation in the interior of the shoe, or by the supply of fresh air inside the shoe in closed rooms or in dry weather. In the first case of using the insole, there is a low hygienic effect, and in the second - a narrow scope and the need for additional retrofitting of the already complex insole design with dust filters.

The closest technical solution to the claimed footwear with ventilation is the USSR famous patent certificate No. 1357007, A 43 B 7/06, 1987 [8] ventilated Victoria shoes, with a top blank with a sole and an inner stocking with an insole that the upper part has a cuff of porous material with channels for ventilation. The insole is made of two layers of elastic material and contains a means for ventilation in the form of a system of valves and air ducts. In the upper elastic layer

insoles are made inlet valves and air ducts. The bottom layer of the insole contains exhaust valves and has corrugations to improve air exchange.

Such shoes are structurally complicated: a special inner stocking is provided in the design, equipped in its upper part with a cuff made of porous material with ventilation channels and in its lower part with an insole with a large number of upper inlet and lower exhaust valves, interconnected by many vertical air ducts, a protective mesh on top of the insole and a grooved shape on the side of the sole of the shoe of the lower layer of the insole. In addition, this shoe has low operational properties: it is inconvenient to use - you must first put on the inner stocking with the insole on the foot and put on the shod foot inside the top of the shoe, after which the inner stocking should be secured to the upper with the cuff.

Common features with the prototype are the following: the presence of a workpiece top with a sole; insoles made of elastic material; and intake valve systems.

The technical result achieved by the claimed solution is to simplify the design of ventilated shoes, improve operational properties associated with the simplification of the rules for using shoes.

An additional technical result according to option 2 is to reduce the material consumption of ventilated shoes and increase the hygienic properties of shoes.

The essence of the claimed utility model according to option 1 is that footwear with ventilation contains a top blank with a sole, an insole made of elastic material, and an intake valve system. At the same time, the insole is hermetically connected along the perimeter with the sole and has perforations, and the intake valve system is made in the form of a valve layer attached to the insole from below, the valves of which cover the insole perforations from below. In this case, the space between the insole and the sole is filled with shock absorbing elements attached to the sole, and for the removal of moist air from this space, the shoes contain an exhaust valve with a channel.

The exhaust valve may be located in the unloaded area of the arch of the foot in the hole of the sole or side - at the junction of the insole and the sole.

The essence of the claimed utility model for option 2 is that shoes with ventilation contains a workpiece top with a sole, an insole made of elastic material, and an intake valve system. In this case, the insole is hermetically connected along the perimeter with the sole, and has perforation holes in the form of slots with a trapezoidal cross section with the formation of inlet valves. In this case, the angle formed by the straight lines on which the lateral sides of the trapezoid of the said section lie are equal to 10-20 degrees, and the bases of this trapezoid are formed by the extensions of the insole surfaces. The slope of the bisector of the previously mentioned angle relative to the height of the trapezoid is 30-60 degrees. In this case, the space between the insole and the sole is filled with shock absorbing elements attached to the sole, and for the removal of moist air from the said space, the shoes contain an exhaust valve.

The exhaust valve may be located in the unloaded area of the arch of the foot in the hole of the sole or side - at the junction of the insole and the sole.

The design of the claimed shoe provides for the removal of moist air from the inside of the shoe to the outside.

Graphic materials illustrating the claimed utility model.

Figure 1 - diagram of the structure of shoes (option 1).

Figure 2 is an example of the location of the exhaust valve (option 1), a view of the insole from above with a cutout.

Figure 3, 4, 5 - diagram of the part of the shoe in three phases of walking according to option 1.

6 is a top view of the insole according to option 1 (type A in figure 1), the dotted line shows the position of the valves of the valve layer.

7 is a top view of the valve layer according to option 1.

Fig - diagram of the structure of shoes (option 2).

Fig.9 is a top view of the insole according to option 2 (view B in Fig.8).

Figure 10, 12, 13 is a diagram of a part of the shoe in three phases of walking according to option 2.

11 is an example of the location of the exhaust valve (option 2), a view of the insole from above with a cutout.

Shoes with ventilation according to option 1 (Fig. 1) contains a blank of top 1 with a sole 2 and an insole 3 made of elastic material. In the insole 3, perforations 4 are made over the entire surface, covered by an intake valve system 5 of the valve layer 6 attached to the insole 3 from the bottom. This design of the insole 3 and the valve layer 6 provides a feed

air into the inner space 7 between the insole 3 and the sole 2. The inner space 7 is filled with shock absorbing elements 8 attached to the sole 2 in the form of vertical tides in contact with the valve layer 6 and acting through it on the insole 3. The shock absorbing elements 8 are arranged so that taking into account their deformation when walking, they did not touch the inlet valves 5. In the least loaded area of the arch of the foot in the hole (not indicated) of the sole 2 or side, at the junction of the insole 3 and the sole 2 (figure 2), at least one exhaust valve 9 with the corresponding air passage 10 communicating with the atmosphere.

Ventilation of the inventive shoes according to option 1 is as follows. At rest (Fig. 3) (both in the compressed and in the free state of the shock absorbing elements 8), there is no directed air circulation around the foot, and the inlet 5 and outlet 9 valves are in a closed state.

From the moment the shoe touches the ground when walking (Fig. 4), under the influence of body weight F, the shock absorbing elements 8 are compressed, while in the inner space 7 between the insole 3 and the sole 2, an excess air pressure P ₁ > P _{A is created} , which ensures the opening of the exhaust valve 9 and the exit of moist air from the space 7 through this valve 9 into the air channel 10 and further into the atmosphere. In this case, the air pressure P ₁ inside the space 7 decreases, and when it is equal to the atmospheric pressure P _A , the exhaust valve 9 closes.

When removing the static load from the insole (Fig. 5), in the process of tearing the shoe off the ground, the insole 3 rises due to the elastic forces N of the shock-absorbing elements 8. In this case, a vacuum is created in the inner space 7, the air pressure P ₂ inside this space 7 is less than atmospheric pressure P _A (P ₂ <P _A ). This ensures that the inlet valves 5 are opened and moist air enters through the openings 4 from the superlative space 11 (the inner space of the shoe) into the space 7 between the insole 3 and the sole 2. The air pressure P ₂ inside the space 7 rises, and when it becomes equal to atmospheric P _A , the intake valves 5 are closed.

The described cycle is repeated during walking at each step, which provides constant ventilation of the legs and shoes when walking.

Shoes with ventilation according to option 2 (Fig. 8) contains a blank of top 1 with a sole 2 and an insole 3 made of elastic material. Insole 3 by

the entire surface has perforations 4 in the form of slots (Fig. 9). The cross section of the slit (figure 10) is a trapezoid with an angle of 12 formed by straight lines on which the sides of the trapezoid are 10-20 degrees. The base of the trapezoid is formed by the extensions of the surfaces of the insole 3. The angle formed by the bisector 13 of the angle 12 and the height 14 of the trapezoid is 30-60 degrees. Moreover, in the insole 3 in the region of the openings 4, upper protrusions 15 and inlet valves 16 are formed. The inner space 7 between the insole 3 and the sole 2 is filled with shock absorbing elements 8 attached to the sole 2 in the form of tides in contact with the insole 3. The shock absorbing elements 8 are arranged so so that, taking into account their deformation when walking, they do not come in contact with the valves 16. This design of the insole 3 and the location of the shock absorbers 8 ensure that when the insole is used, air passes through the insole 3 in only one direction - in Cored oil space 7. In the least loaded arch area of the foot in a hole (not indicated) in the base 2 or on the side, in place of the compound 3 and the insole 2 of the sole (11) is mounted at least one exhaust valve 9 with the corresponding air passage 10.

Ventilation of the inventive shoes according to option 2 is as follows. At rest (figure 10) (both in the compressed and in the free state of the shock absorbing elements 8), there is no directed air circulation around the foot, the intake valves 16 are open, and the exhaust valve 9 is in the closed state.

From the moment the foot touches the ground (Fig. 12), under the influence of the weight of the body F, the shock absorbing elements 8 are compressed, while in the inner space 7 between the insole 3 and the sole 2, an excess air pressure P ₁ > P _{A is created} , which provides the opening of the exhaust valve 9, and the bending and closing of the intake valves 16. In this case, the moist air comes out of the space 7 through the exhaust valve 9 into the air channel 10 and then into the atmosphere. In this case, the air pressure P ₁ inside the space 7 decreases, and when it is equal to the atmospheric pressure P _A , the exhaust valve 9 closes and the intake valves 16 open.

When removing the static load from the insole (Fig.13) in the process of tearing the foot off the ground, the insole 3 rises due to the elastic forces N of the shock-absorbing elements 8. In this case, a vacuum is created in the inner space 7,

which air pressure P ₂ in this space is less than atmospheric pressure (P ₂ <P _A ). This ensures that moist air enters from the superstructure 11 (the inner space of the shoe) through the perforations 4 into the inner space 7 between the insole 3 and the sole 2. As the damping elements 8 expand, their elastic forces N decrease. At the same time, the air pressure P ₂ inside the space 7 rises, and when it is equal to the atmospheric P _A , the flow of moist air from the superstructure 11 stops.

The described cycle is repeated during walking at each step, which provides constant ventilation of the legs and shoes when walking.

Improving the hygienic properties of the inventive shoes according to option 2 is achieved due to the fact that, unlike shoes according to option 1, the insole is hermetically connected along the perimeter with the sole and has perforation holes in the form of slots with a trapezoidal cross section with the formation of inlet valves. In this case, the angle formed by the straight lines on which the lateral sides of the trapezoid of the said section lie are equal to 10-20 degrees, and the bases of this trapezoid are formed by the extensions of the insole surfaces. The slope of the bisector of the previously mentioned angle relative to the height of the trapezoid is 30-60 degrees. This technical solution leads to the fact that when not in use, the inlet valves are open, and the space between the insole and the sole communicates with the interior of the shoe, which provides natural ventilation and drying of the shoe when not in use.

The selection of shock-absorbing elements of different densities in combination with the number of inlet valves allows you to choose the optimal operating parameters, such as ventilation intensity, wear resistance. The simplicity of the design allows to find wide application in the manufacture of comfortable sports and household shoes.

INFORMATION SOURCES.

1. USSR author's certificate No. 350453, A 43 B, 7/06, 1972

2. USSR author's certificate No. 1169598, A 43 B 7/06, 1985

3. French patent for the invention N2558044, A 43 In 7/08, 1985

4. RF patent for the invention No. 2185101, A 43 B 7/06, 1998

5. RF patent for utility model No. 27888, A 43 B 7/28, 2003

6. RF patent for the invention No. 2129822, A 43 B 17/08, 1999

7. RF patent for utility model No. 49430, А 43 В 17/08, 2005

8. USSR Copyright Certificate No. 1357007, A 43 B, 7/06, 1987

Claims (8)

1. Shoes with ventilation, containing a blank of the top with the sole, an insole made of elastic material, and an intake valve system, characterized in that the insole is hermetically connected around the perimeter with the sole and has perforations, and the intake valve system is designed as attached to the insole at the bottom of the valve layer, the valves of which cover the bottom of the perforation holes of the insole, and the space between the insole and the sole is filled with shock absorbing elements attached to the sole, and for the removal of wet The air from this space shoes contains an exhaust valve with a channel. 2. Shoes with ventilation according to claim 1, characterized in that the exhaust valve is located in the unloaded area of the arch of the foot. 3. Shoes with ventilation according to claim 2, characterized in that the exhaust valve is located in the opening of the sole. 4. Shoes with ventilation according to claim 2, characterized in that the exhaust valve is located on the side, at the junction of the insole and the sole. 5. Shoes with ventilation, containing a blank of the top with the sole, an insole made of elastic material, and an intake valve system, characterized in that the insole is hermetically connected around the perimeter with the sole, the insole having perforation holes in the form of slots with a trapezoidal cross section to form inlet valves, and the angle formed by the straight lines on which the sides of the trapezoid of the said section lie are equal to 10-20 °, and the bases of this trapezoid are formed by the extensions of the insole surfaces, and the slope of the bisector of the previously mentioned angle relative to the height of the trapezoid is 30-60 °, and the space between the insole and the sole is filled with shock absorbing elements attached to the sole, and the shoes contain an exhaust valve to remove moist air from the said space. 6. Shoes with ventilation according to claim 5, characterized in that the exhaust valve is located in the unloaded area of the arch of the foot. 7. Shoes with ventilation according to claim 6, characterized in that the exhaust valve is located in the opening of the sole. 8. Shoes with ventilation according to claim 6, characterized in that the exhaust valve is located on the side, at the junction of the insole and the sole.