KR100509518B1 - method for drying and pressing of shoe - Google Patents

Abstract

The present invention relates to a dry crimping method for shoe bonding, comprising: an adhesive applying step of applying an adhesive to an outsole and an upper; A drying step of accommodating the shoe that has undergone the adhesive coating process on the conveyor belt and transferring the shoe into the near-infrared radiation chamber to dry the shoe surface temperature at about 50 to 65 ° C. by heat transfer by the near-infrared radiator; After the drying process, pressurizing the pressure plate by the cooling operating oil, the pressing pressure of the pressure plate and the cold pressure of the cooling operating oil delivered to the shoe by a cold pressing process for cooling the shoe cold compression method comprising a Make a point. Accordingly, after drying the shoe to which the adhesive is applied for a short time, by increasing the adhesive force of the adhesive portion of the shoe by cold pressing the adhesive portion has the advantage of reducing the defective rate of the shoe and improve the productivity.

Description

Method for drying and pressing of shoe

The present invention relates to a dry pressing process of shoes, and more particularly, after drying an adhesive-coated shoe, by increasing the adhesive force of the adhesive portion of the shoe by cold pressing the adhesive portion to reduce the defective rate of the shoe and improve the productivity It relates to a dry pressing method of shoes to improve.

In general, in the case of a shoe is formed of the sole coupled to the upper and the upper.

The sole consists of an outsole that forms the sole of the shoe and a midsole that usually forms the sole of the shoe. The outsole is usually made of rubber material to satisfy the functions for wear resistance and anti-slip, and the midsole is mainly made of foamed and expanded synthetic resin material for absorbing the impact and restoring it when it is light and impacted. do.

Since the outsole and the midsole constituting the sole as described above is different in material and the manufacturing method is different, the outsole is usually manufactured separately so that the outsole is attached to the bottom of the midsole. When the sole of the shoe is manufactured, the upper is coupled to the sole, thereby manufacturing the shoe.

The sole manufacturing process, the upper manufacturing process and the bonding process of the sole and upper is usually made of a continuous working process.

During the final process of the work, the adhesive part should be bonded while the sole and the upper are bonded with the adhesive, so that the failure rate and productivity of the shoe are determined by how quickly and stably the adhesive part is adhered.

Accordingly, the present invention has been devised in view of the above, and in the state where the adhesive is dried on a shoe coated with an adhesive, the bonding time is shortened by cold pressing the portion to be bonded under a predetermined pressure. At the same time to improve the adhesive strength to minimize the defect rate and to provide a dry pressing method of shoes to improve the productivity.

The present invention for achieving the above object is an adhesive coating process for applying an adhesive to the sole and upper; A drying step of accommodating the shoes subjected to the adhesive coating process on the conveyor belt and transporting the shoes to the inside of the near-infrared radiation chamber to dry the shoe surface temperature by 50-65 ° C. by the near-infrared radiator; After the drying process, pressurizing the pressure plate by the cooling operating oil, the pressing pressure of the pressure plate and the cold pressure of the cooling operating oil delivered to the shoe by a cold pressing process for cooling the shoe cold compression method comprising a Make a point.

Accordingly, after drying the shoe to which the adhesive is applied for a short time, by increasing the adhesive force of the adhesive portion of the shoe by cold pressing the adhesive portion has the advantage of reducing the defective rate of the shoe and improve the productivity.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

Figure 1 is a process diagram showing a dry pressing process of the shoe according to the invention, Figure 2 is a schematic diagram of a drying apparatus for drying the shoe, Figure 3 is a schematic diagram of a cold press for cold pressing the shoe.

As shown, the dry pressing method of the shoe according to the present invention is largely composed of an adhesive coating step, a drying step, and a cooling compression step.

First, the adhesive agent application process is demonstrated.

The adhesive coating process is a process for bonding the shoe upper and the sole by applying an adhesive to the shoe is carried out using a hot melt, an aqueous oil (PU) adhesive and the like.

Since the adhesive coating step is a well-known technique, detailed description thereof will be omitted.

For the shoes bonded through the adhesive coating process is a drying process is carried out, the drying process is dried using a near-infrared drying apparatus, as shown in FIG.

Drying in the near-infrared drying apparatus heats only from about 2 mm to the surface of the shoe using near-infrared radiation instead of hot air drying to heat only 2 to 5 mm.

Drying is to place the shoes to be dried on the upper surface of the drying plate 111 on the endless track body 110, input the set value, such as a set value, upper and lower set value to the control unit 140 to operate the dryer.

By the operation of the dryer, the crawler 110 is rotated and the shoes placed on the crawler 110 flow into the chamber 100 and the near-infrared emitter 120 installed inside the chamber 100 corresponds to the set value. The radiant heat is generated to dry the shoe to which the adhesive is applied.

At this time, as described above, the shoe is not heated to the inside by the radiation of the radiator 120 is heated only to about 2 to 5 mm point inside the shoe surface and the heating temperature is about 50 to 65 ℃ This is different from hot air drying, which heats the interior and even the last.

The dried shoes are leaked to the outside of the chamber 100 and the surface temperature of the leaked shoes is detected by the infrared temperature sensor 130, and the detected signals are transmitted to the controller 140, whereby the surface of the shoes is controlled by the controller 140. By controlling the radiation amount of the radiator 120 so that the temperature is kept constant (50 ~ 65 ℃), the drying temperature of the shoe is kept constant.

Here, the shoe surface temperature flowing out of the chamber 100 is maintained at about 50 ~ 65 ℃ and the temperature inside the shoe is to maintain a lower state than the temperature.

For the shoe that passed through the drying process, the cooling compression process is performed, and the process is performed using the cooling compression machine as shown in FIG. 3.

In the process of adhering shoes, when the temperature falls below 20 ℃, crystallization of the adhesive starts. After that, as the adhesive crystallizes, the curing agent forms a connection chain in the adhesive to increase the adhesive strength. In the case of the outsole and the upper after the drying process was pressed by a compression process in the cooling using a separate cooling device to obtain the required adhesive strength.

In other words, as the sole and upper passed through the hot air dryer are heated to the inside and the last to a high temperature, the sole and upper required a considerable cooling device and time required to cool below 20 ° C. In fact, since the shoes are in a high temperature state, the crystallization does not proceed, so that the adhesive strength is poor. In the dry pressing method of the present invention, since the inner temperature and the last temperature of the sole and upper passing through the near-infrared drying device are considerably lower than the surface temperature of the sole and the upper, it is easy to cool them to 20 ° C. or lower, and thus It is possible to achieve the bonding and crystallization of the adhesive at the same time by putting the shoe subjected to the drying process into a cooling press equipped with a predetermined cooling function to transfer the pressing force to the shoe and simultaneously cool it. Accordingly, the effect of reducing the production process while improving the adhesive strength of the shoe.

The shoe coated with the adhesive after the drying process is placed upright on the sieve accommodated in the last on the upper pressure plate 211 inside the pressure chamber 200 of FIG.

In addition, when the start button is pressed, the upper and lower cylinders 220 are operated to allow the pressure chamber 200 to flow upward so that the pressure chamber 200 and the upper cover 201 are in contact with each other.

In addition, by circulating the heat exchanger 234 side by the operation of the cooling means 230 and the circulation pump 240 composed of the compressor 231, the condenser 232, the expansion valve 233, the heat exchanger 234. The working oil cooled by the inlet flows into the pressure chamber 213 formed in the pressure chamber 200 to transmit the pressing force to the external pressure plate 212 formed of a synthetic resin material such as rubber formed in the pressure chamber 213. The pressure transmitted to the external pressure plate 212 is transferred to the internal pressure plate 211 formed of a synthetic resin material such as rubber.

The inner pressing plate 211 compresses the adhesive part of the shoe by the pressing force transmitted to the inner pressing plate 211 and cool air of the hydraulic oil is transferred to the shoe so that the adhesive part of the shoe is bonded and cooled at the same time.

Here, since the cooling mechanism of the cooling means 230 is well known, a detailed description thereof will be omitted.

At this time, the temperature sensor 250 formed in the pressure chamber 213 detects the temperature of the hydraulic oil flowing into the pressure chamber 213, and when the temperature of the hydraulic oil reaches the set temperature, the circulation pump 240 and the cooling means. 230 is automatically stopped.

In addition, when the temperature of the working oil is higher than the set temperature, the circulation pump 240 and the cooling means 230 is operated to cool the working oil.

Adhesive strength test was performed on the shoe formed as described above, and the adhesive strength test table is shown in Table 1.

As shown in the above table, the average adhesive strength when the refrigerator is used is 7.225 kgf / cm, and the average adhesive strength when the refrigerator is not used is 4.9 kgf / cm. The average difference was 2.325 kgf / cm.

In other words, the cold pressing using the freezer showed better initial adhesive strength than the pressing without using the freezer.

The present invention by the above configuration has the effect of excellent adhesive strength by drying only the adhesive portion without heating the inner portion of the shoe using a near-infrared radiator, and cold-dried dry shoes.

In addition, there is also an effect that the production process is reduced and the productivity is improved at the same time by pressing and bonding at the same time without the cooling device for cooling the dried shoes separately.

1-a process diagram showing a dry pressing process of the shoe according to the present invention.

2 is a schematic view of a drying apparatus for drying shoes.

3-Schematic diagram of a cold press for cold pressing a shoe.

<Description of Symbols for Major Parts of Drawings>

100: chamber 110: infinite track

111: drying plate 120: radiator

130: infrared temperature sensor 140: control unit

200: pressurized chamber 201: upper cover

210: pressure plate 211: internal pressure plate

212: external pressure plate 213: pressure chamber

220: upper and lower cylinder 230: cooling means

231 compressor: 232 condenser

233: expansion valve 234: heat exchanger

240: circulation pump 250: temperature sensor

Claims (1)

An adhesive coating step of applying the adhesive to the sole and the upper; A drying step of accommodating the shoe that has undergone the adhesive coating process on the conveyor belt and transferring the shoe into the near-infrared radiation chamber to dry the shoe surface temperature at about 50 to 65 ° C. by heat transfer by the near-infrared radiator; After the drying process, pressurizing the pressure plate by the cooling operating oil, the pressing pressure of the pressure plate and the cold pressure of the cooling operating oil delivered to the shoe by a cold pressing process for cooling the shoe; dry compression of the shoe comprising a Way.