KR200257387Y1 - A surface roughen machine for shoes midsole - Google Patents

Abstract

According to the present invention, a chamber having a constant volume is formed inside the housing, and the shoe midsole conveying conveyor passes through the chamber of the housing, and an ultraviolet lamp is formed at a position adjacent to the mesh belt of the shoe midsole conveying conveyor. The present invention relates to a device for roughening the surface of the shoe midsole by irradiating ultraviolet rays of a predetermined wavelength to the shoe midsole mounted on the mesh belt.

In detail, ultraviolet rays in the wavelength range of 184 to 253 nm having low thermal energy and low transmittance are irradiated, and an ultraviolet ray lamp for controlling the distance from the mesh belt is formed by an electric motor. Projections are formed on the guide rolls by applying a periodic shock to the mesh belt to uniformly irradiate the guide rolls to uniformly irradiate the surface of the shoe midsole with the ultraviolet rays of the above-described wavelength. A surface roughness device configured to finely destroy a surface front surface.

Description

Surface roughen machine for shoes midsole

The present invention irradiates far ultraviolet rays in the wavelength range of 184 to 253 nm with low thermal energy and low transmittance, and adjusts the distance to the mesh belt according to the size of the shoe midsole mounted on the mesh belt. A protruding protrusion is formed on the guide roll by applying a periodic impact on the mesh belt so that the ultraviolet ray lamp is formed and the ultraviolet ray is uniformly irradiated on the front surface of the lower surface of the shoe midsole mounted to the mesh belt. The present invention relates to an apparatus which is formed to uniformly irradiate the entire surface of a shoe midsole with ultraviolet rays having a wavelength of 184 to 253 nm, thereby roughly destroying the surface of the shoe midsole at room temperature, thereby roughening the entire surface of the shoe midsole.

The shoe sole is formed in the insole facing the sole and the bottom of the insole to form a triple structure of the midsole forming the center of the shoe sole and the bottom of the midsole to contact the ground, the insole, midsole and sole Bonded to each other by an adhesive. However, if the surface of the shoe midsole is smooth, the adhesive strength of the adhesive bonding the shoe sole is greatly reduced, so that the insole and the sole are easily separated from the shoe midsole. Therefore, by irradiating the surface of the shoe midsole with ultraviolet rays of a constant wavelength to finely destroy the surface of the shoe midsole, the surface of the shoe midsole should be roughened to improve the adhesion of the shoe midsole.

The surface roughness device of the conventional shoe midsole has a constant volume chamber formed inside the housing, and a shoe midsole conveying conveyor is formed to penetrate the chamber of the housing, and a mesh belt is installed on the shoe midsole conveying conveyor and the upper surface of the mesh belt is formed. . A near-ultraviolet lamp for irradiating near-ultraviolet and visible light in the wavelength range of 320 to 420 nm adjacent to the lower portion is fixed. The near-ultraviolet and visible light in the above-described wavelength range is irradiated to the shoe midsole mounted on the mesh belt. . However, since the near-ultraviolet and visible light in the wavelength range of 320 to 420 nm are very large in thermal energy, the temperature inside the chamber is raised to a high temperature of 50 to 60 ° C. to cause thermal deformation in the shoe midsole. In order to solve the heat deformation of the shoe midsole, a ventilator must be formed in the surface roughness device to ventilate and cool the inside of the chamber. However, the ventilator is not only effective in cooling the shoe midsole mounted on the mesh belt but also reduces the installation cost of the surface roughness device. There is a problem of increasing.

In addition, since a part of the near-ultraviolet rays irradiated from the near-ultraviolet lamp under the mesh belt is blocked by the mesh belt, ultraviolet rays are not uniformly irradiated on the lower front surface of the shoe midsole mounted on the mesh belt, which causes a decrease in the adhesion of the shoe midsole There is a problem that leads to.

An object of the present invention is to irradiate far ultraviolet rays in the wavelength range of 184 to 253 nm and to extend a certain range by a sensor device and an electric motor to adjust the distance to the mesh belt according to the size of a shoe sole mounted on a mesh belt. A ramp is formed and a protrusion is formed on the guide roll by applying a periodic shock to the mesh belt to form a guide roll so that ultraviolet rays with low thermal energy and low permeability are uniformly irradiated on the entire surface of the shoe midsole. The present invention provides a surface roughening device for a shoe midsole that roughens the entire surface of the shoe midsole while finely destroying the surface of the midsole.

Ultraviolet rays with short wavelengths are shown in the following table. As shown in Fig. 1, the thermal energy is low and the transmittance is lower than that of near ultraviolet rays.

<Table. 1> UV-property comparison table

division Far ultraviolet rays Heavy ultraviolet rays Near ultraviolet wavelength 184-235 nm 235 to 320 nm 320-400 nm Thermal energy small middle Big Permeability low middle high

Therefore, the far-ultraviolet rays irradiated from the far-ultraviolet lamp of the present invention have lower thermal energy than the near-ultraviolet and visible light irradiated from the conventional ultraviolet lamp, so that the inside of the chamber is kept at room temperature, while the transmittance is low. The generating action is equal to or greater than near ultraviolet.

In order to uniformly irradiate the front surface of the shoe midsole mounted on the mesh belt with ultraviolet rays, the position of the shoe midsole must be continuously changed by applying a periodic impact to the mesh belt to cause the shoe midsole mounted on the mesh belt to spring up. .

1 is a side view of the present invention

2 is a classification diagram of wavelengths of light rays

3 is a front view of the present invention

* Explanation of symbols for the main parts of the drawings

1: far-ultraviolet lamp 2: shoe midsole

3: mesh belt 4: sensor device

5: rotating shaft 6: fastener

9: electric motor 10: guide roll

11: protrusion 12: guide rod (a, b)

13: frame

The surface roughness device of the shoe midsole of the present invention is a rotary shaft 5 of the electric motor 9 which is formed to irradiate far ultraviolet rays in the wavelength 184 to 253 nm region and is controlled by the sensor device 4 which measures the size of the shoe midsole 2. Shock generation projections 11 are formed on the outer diameter of the ultraviolet ray lamp 1 fastened to the outer surface of the ultraviolet ray lamp 1 and the guide roll 10 for guiding the mesh belt 3 so as to periodically apply the impact to the mesh belt 3. There is a characteristic to be formed.

The present invention will be described in detail with reference to the drawings and embodiments.

A chamber of a constant volume is formed inside the housing of the surface roughening device of the shoe midsole, and a shoe midsole conveying conveyor is formed to penetrate the chamber. It performs the action of transporting the shoe midsole 2 to the outside. A mesh belt 3 is formed on the shoe midsole conveying conveyor so that far ultraviolet rays can pass therethrough, and the shoe midsole 2 is mounted on the mesh belt 3 and transported.

A plurality of far ultraviolet lamps 1 are formed along the longitudinal direction of the mesh belt 3 at regular intervals from the mesh belt 3 of the shoe midsole conveying conveyor, and irradiated from the far ultraviolet lamp 1. Ultraviolet rays of a constant wavelength are irradiated in the direction of the mesh belt 3. The far ultraviolet rays irradiated from the far-ultraviolet lamp 1 formed as described above finely destroy the surface of the shoe midsole 2 mounted on the mesh belt 3 so as to roughen the surface of the shoe midsole 2. .

The far ultraviolet lamp 1 is a rod-shaped lamp formed so as to irradiate far ultraviolet rays in a wavelength of 184 to 253 nm. Ultraviolet rays with a wavelength of less than 184 nm generate ozone in the chamber, and ultraviolet rays exceeding the wavelength of 253 nm increase the temperature inside the chamber because of the large thermal energy, so that the ultraviolet lamp 1 has far ultraviolet rays in the wavelength range of 184 to 253 nm. It is formed to irradiate. The far ultraviolet rays in the wavelength range of 184 to 253 nm have a very low thermal energy compared to near ultraviolet rays and visible rays irradiated with a conventional ultraviolet lamp, and thus maintain the inside of the chamber at room temperature, while the transmittance is low, so that the surface of the shoe midsole 2 is low. The action of causing microcracks in the film is equivalent to or greater than near ultraviolet light.

A plurality of guide rods 12a and 12b are formed on the upper portion of the far ultraviolet lamp 1 formed on the mesh belt 3. One end of the guide rods 12a and 12b is fixed to the upper surface of the far ultraviolet lamp 1 and is erected in a vertical direction to be supported by the frame 13 inside the chamber. The frame 13 fixed to the upper wall of the chamber is formed with a hole through which the guide rods 12a and 12b pass at positions corresponding to the guide rods 12a and 12b of the far ultraviolet lamp 1. As described above, a thread is formed on the outer diameter of any one of the guide rods 12a among the plurality of guide rods 12a and 12b formed on the upper portion of each far ultraviolet lamp 1 and passing through the holes of the frame 13. The thread of the guide rod 12a is fastened to the rotation shaft 6 of the electric motor 9. Therefore, the far ultraviolet lamp 1 is guided by the guide rods 12a and 12b and proceeds in the vertical direction.

On the upper part of the frame 13 fixed to the chamber, an electric motor 9 is formed, which is connected to the far ultraviolet lamp 1 to advance the far ultraviolet lamp 1 in a vertical direction, and the electric motor 9 is formed in the chamber. It is fixed at the top and connected to each far ultraviolet lamp 1, respectively. A disk-shaped fastener 6 is formed at the end of the rotary shaft 5 of the electric motor 9, and the fastener 6 is fastened to the thread of the guide rod 12a of the far ultraviolet lamp 1. In the present embodiment, although the rotary shaft 5 of the electric motor 9 and the guide rod 12a of the far ultraviolet lamp 1 are connected by the fastener 6, the fastener is connected to the rotary shaft 5 of the electric motor 9. (6) is not formed and the rotary shaft 5 of the electric motor 9 and the guide rod 12a of the far ultraviolet lamp 1 may be directly connected. Therefore, the guide rod 12a and the far ultraviolet lamp 1 are advanced in the vertical direction by the rotational action of the rotary shaft 5 of the electric motor 9 between the far ultraviolet lamp 1 and the mesh belt 3. You can adjust the distance.

Although there is a method of connecting the hydraulic cylinder to the guide rod 12b of the far ultraviolet lamp 1 to advance the far ultraviolet lamp 1 in the vertical direction, in order to advance the far ultraviolet lamp 1 by an accurate distance, It is preferable to connect the guide rod 12a of the lamp 1 and the rotary shaft 5 of the electric motor 9 to advance the far ultraviolet lamp 1 in the vertical direction.

The distance between the far ultraviolet lamp 1 and the mesh belt 3 is adjusted according to the size of the shoe midsole 2 mounted on the mesh belt 3 so that the shoe midsole 2 mounted on the mesh belt 3 is adjusted. Fine cracks should be generated evenly over the entire surface. Accordingly, the sensor device 4 is formed at a position adjacent to the upper portion of the mesh belt 3 so as to measure the size of the shoe midsole 2 mounted on the mesh belt 3. The sensor device 4 may be formed at the entrance of the chamber in number or may be formed in each of the ultraviolet lamps 1 individually. The sensor device 4 is connected to the electric motor 9 to control the rotation of the rotary shaft 5 of the electric motor 9 on the basis of the measured size of the shoe midsole 2, the rotary shaft of the electric motor 9 By performing the rotation action of (5) to advance the far ultraviolet lamp (1) connected to the rotary shaft (5) in the vertical direction to perform the action of adjusting the distance between the far ultraviolet lamp (1) and the mesh belt (3) do.

Applying a periodic shock to the mesh belt (3) so that the entire lower portion of the shoe midsole (2) mounted on the mesh belt (3) is uniformly irradiated to cause the shoe midsole (2) to bounce off the shoe midsole ( The position of 2) should be changed. A single impact generating projection 11 is formed on the outer diameter of the guide roll 10 for guiding the mesh belt 3 so that the periodic impact is applied to the mesh belt 3. Since the impact generating protrusion 11 protrudes along the length direction of the guide roll 10, when the guide roll 10 is rotated at a constant speed, the impact generating protrusion 11 formed on the outer diameter of the guide roll 10 is fixed. ) Exerts a periodic impact on the mesh belt 3. When the impact is applied to the mesh belt 3, the shoe midsole 2 mounted on the mesh belt 3 pops up to change the position of the shoe midsole 2, so that the front surface of the lower surface of the shoe midsole 2 is changed. Ultraviolet rays are irradiated uniformly.

The shoe midsole transfer conveyor and the far ultraviolet lamp 1 are operated and the shoe midsole 2 is mounted on the mesh belt 3 of the shoe midsole transfer conveyor. The shoe midsole 2 is conveyed into the chamber of the surface roughening device by the mesh belt 3. The sensor device 4 formed adjacent to the upper portion of the mesh belt 3 measures the size of the shoe midsole 2 and according to the measured size of the shoe midsole 2 of the rotary shaft 5 of the electric motor 9. Rotation and vertical movement of the guide rod 12a fastened to the rotary shaft 5 of the electric motor 9 are controlled. As the guide rod 12a moves up and down, the far ultraviolet lamp 1 coupled to the guide rod 12a proceeds in a vertical direction, so that the distance between the far ultraviolet lamp 1 and the mesh belt 3 is increased. Adjusted. As described above, the distance between the far ultraviolet lamp 1 and the mesh belt 3 is adjusted to uniformly generate fine cracks by far ultraviolet rays on the entire surface of the shoe midsole 2 mounted on the mesh belt 3. do. If the size of the shoe midsole 2 is particularly large, the distance between the far ultraviolet lamp 1 and the mesh belt 3 is adjusted to be close, and if the size of the shoe midsole 2 is small, particularly the thickness is far ultraviolet lamp The distance between the (1) and the mesh belt 3 is adjusted to be far. The shoe midsole 2 transferred into the chamber is an image of the mesh belt 3. The surface of the sole 2 is minutely destroyed by the ultraviolet rays irradiated from the far ultraviolet lamps 1 adjacent to the lower part. Since the far ultraviolet lamp 1 irradiates far ultraviolet rays in a wavelength range of 184 to 253 nm with a small thermal energy, the inside of the chamber of the surface roughness device maintains a normal temperature even when a fan is not formed in the surface roughness device. Thus, the mesh belt 3 Shoe midsole (2) mounted on the) also maintains the room temperature, so no heat deformation occurs.

In addition, the impact generating protrusion 11 formed on the outer diameter of the guide roll 10 for guiding the mesh belt 3 periodically impacts the mesh belt 3 so that the shoe sole is mounted on the mesh belt 3 ( 2) to reposition to change the position of the shoe midsole (2), while the outside of the shoe midsole (2) is irradiated with ultraviolet rays uniformly in front of the lower surface of the shoe midsole (2) The front surface of 2) becomes rough evenly.

The surface roughness device of the shoe midsole according to the present invention irradiates far ultraviolet rays in the wavelength range of 184 to 253 nm and is fixed by the sensor device and the electric motor to adjust the distance from the mesh belt according to the size of the shoe midsole mounted on the mesh belt. A far-ultraviolet lamp is formed in the range, and a projection which protrudes the mounted shoe midsole by applying a periodic shock to the mesh belt is formed on the guide roll, so that the ultraviolet ray having low thermal energy and low transmittance is uniform on the front surface of the shoe midsole. The surface of the shoe midsole is destroyed finely at room temperature, thereby preventing thermal deformation of the shoe midsole and making the surface roughness of the shoe midsole uniform, thereby improving the adhesion of the shoe midsole.

Claims (2)

A chamber having a constant volume is formed inside the housing and is formed so that the shoe midsole conveying conveyor penetrates the chamber of the housing and guides the mesh belt 3 and the mesh belt 3 to the shoe midsole conveying conveyor. ) Is formed and an ultraviolet lamp (1) is formed adjacent to the mesh belt (3) is irradiated with ultraviolet light of a predetermined wavelength to the shoe midsole (2) mounted on the mesh belt (3) of the shoe midsole (2) In the surface roughness apparatus which destroys a surface finely, An ultraviolet lamp (1) fastened to the rotary shaft (5) of the electric motor (9) formed to irradiate ultraviolet rays and controlled by a sensor device (4) measuring the size of the shoe sole (2), and the mesh belt (3) The surface roughness device of the shoe midsole, characterized in that the impact generating projections (11) is formed on the outer diameter of the guide roll (10) for guiding the mesh belt (3) to give a periodic impact on the. 2. The surface roughness apparatus of a shoe sole according to claim 1, wherein the far ultraviolet lamp (1) is formed so as to irradiate far ultraviolet rays in a wavelength range of 184 to 253 nm.