KR200265379Y1 - shoes dryer using near infrared rays - Google Patents

Abstract

The present invention relates to a dryer, and in particular, in order to interconnect the outsole, upper, etc. constituting the shoes using the adhesive to dry the adhesive quickly to be combined, for this purpose, the present invention is rotated In the shoe manufacturing conditioner so that the drying is made while the shoes are placed on the endless track to move, the auxiliary frame 100 is formed while crossing the endless track spaced apart from the upper portion of the endless track (60); The reflector plate 220 is formed between the endless tracker 60 and the auxiliary frame 100 and is provided with a radiator 210 that emits near infrared rays and functions to irradiate the near infrared rays generated by the radiator downward. A chamber 200; A fixed part 310 and the reflecting plate 220 installed from the auxiliary frame are constrained with the plurality of operation handles 320 to adjust the vertical position of the reflecting plate. The present invention relates to a near-infrared shoe dryer having a technical point that a drying treatment is performed.

Description

Near Infrared Shoe Dryer {shoes dryer using near infrared rays}

The present invention relates to a dryer used in shoe manufacturing, and more particularly, to a near-infrared shoe dryer using near-infrared to increase productivity by rapid drying.

In general, in shoe manufacturing, the upper and the shoe sole is bonded using a liquid adhesive when the shoe upper and the shoe sole are bonded. In the shoe manufacturing process, in which mass production takes place, there was a necessity that the drying operation should be dried quickly with continuity.

Hereinafter, a shoe manufacturing dryer of Patent Application No. 10-1991-0007208 as a prior art will be described, and FIG. 1 is a schematic cross-sectional view of the prior art.

According to the above conventional technique, a chain conveyor 5 made of a chain 5A and a pipe 5B is attached to a chain gear 4 which is formed by adhering a drying chamber 1A to a lower portion of the diaphragm 101 of the base 1. Is installed in the orbit, and the lower and upper portions of the circulation passage (2) through which the suction hole (2A) is opened and the distribution chamber (3) through which the inlet hole (3A) is formed to communicate with the circulation passage (20), 2) The heater 6 and the evaporator 10 of the cooler 9 are installed in the drying chamber 1A by the fan 8 of the motor 7 through the inlet hole 3A. The drying chamber 1B is formed at the upper portion of the diaphragm 101 and the conveyor belt 18 is adhered to the roller 19 in an endless track on the upper portion of the diaphragm 101, and a suction port is formed at the upper portion of the drying chamber 1B. 13, which forms a circulation path 11 in which the heater 14 is fixed, and heats the heated air through the distribution path 12 and the inlet hole 12A by the fan 16 of the motor 15. It was related with the shoe manufacturing dryer made to be able to flow into the yarn 1B.

The dryer according to the related art has a structure in which the heating air and cooling air are pumped into the drying chamber by a fan, and there is a problem that the structure is complicated because air flows in and out through a circulation path.

In addition, since the shoes are dried by circulating heated air in the drying chamber, the temperature of the drying chamber is substantially the same, and thus, there is a problem in that the optimum temperature condition cannot be formed when the types of products vary.

Accordingly, the present invention devised to solve the above problems is to provide a near-infrared shoe dryer to enable rapid drying in near-infrared, and to maintain the optimum adhesion temperature according to the type of shoes by partitioning the chamber. The purpose.

1-a schematic cross-sectional view of a shoe manufacturing dryer according to the prior art.

Figure 2-schematic perspective view of a near-infrared shoe dryer constructed in accordance with an embodiment of the present invention.

3-one side view to FIG. 2.

Figure 4 is a block diagram showing another embodiment of the present invention.

<Description of Major Symbols Used in Drawings>

50: frame 60: infinite track

61: chain 62: sprocket

63: dry plate 64: bar

100: auxiliary frame 100a: vertical column

100b: horizontal column 110: operation panel

200: chamber 210: radiator

220: reflector 225: partition plate

300: setting unit 310: fixed bar

320: operation handle

The present invention for achieving the above object, in the shoe manufacturing conditioner so that the drying is made while the shoe is placed on the endless track to be rotated, it is formed while crossing the endless track spaced on the top of the endless track An auxiliary frame; A chamber formed between the crawler and the auxiliary frame and provided with a radiator for emitting near infrared rays, and having a reflector configured to irradiate the near infrared rays generated by the radiator downward; A fixed bar installed from the auxiliary frame and a setting unit configured to allow the reflection plate to be restrained with a plurality of operation handles to adjust the upper and lower positions of the chamber. The present invention relates to a near-infrared shoe dryer capable of forming different temperature conditions.

In general, the production of shoes is characterized by mass production and mass production, and it is necessary to increase productivity in order to secure sufficient competitiveness. Accordingly, the present invention has the advantage of providing a near-infrared shoe dryer that can reduce the working cycle time as a dryer that can be used for the combination of upper and sole, which is a drying process in shoe manufacturing, and can simultaneously dry different products. have.

Near-infrared rays are short-wavelength rays that are transmitted at a thermal wavelength only to an object without heating air at a wavelength of 0.8 to 1.4 µm as infrared rays closest to the sun's radiant heat generated when the temperature of the heating element is 1800 ° C to 2200 ° C.

Hereinafter will be described in detail the near-infrared shoe dryer according to an embodiment of the present invention. 2 is a schematic perspective view showing a near-infrared shoe dryer constructed in accordance with an embodiment of the present invention. FIG. 3 shows a side view of FIG. 2.

As shown, the near-infrared shoe dryer of the present invention is composed of a frame 50, an auxiliary frame 100, the chamber 200 and the setting unit 300 and the radiator 210 for generating a near infrared ray in the chamber 200 And a reflection plate 220 to guide the generated near infrared rays to the lower side. In addition, the setting part 300 is configured as a fixing bar 310 installed from the auxiliary frame 100 and an operation handle 320 formed on the fixing bar.

On the frame, an endless track 60 driven by a motor (not shown) is installed, and a repetitive rotational motion occurs. On the upper surface of the endless track 60, a shoe, which is a drying object, is loaded. The loaded shoes are passed along with the rotation of the crawler 60 to pass through the chamber 200 and to be dried while passing through the chamber.

The tracked body 60 is a general known technique, and in one embodiment of the present invention is to be composed of a chain 61 and a sprocket 62, and the object to be dried on a long bar 64 formed from the chain 61 The drying plate 63 is to be installed so that it can be loaded.

The auxiliary frame 100 is installed on the upper surface of the endless track body 60, and the auxiliary frame is separated from the frame 50 in which the endless tracker 60 is formed, and is easily grounded. On the lower side in contact with the moving wheel (not shown) to be installed. More specifically, the auxiliary frame 100 forms a c-shape in which the lower side is opened, and is separated from the frame 50 so as to be easily installed or moved. For convenience of description, a pair of members in contact with the ground of the auxiliary frame 100 is called a vertical column 100a and interconnecting an upper end of the vertical column is called a horizontal column 100b. Of course, the auxiliary frame 100 may be fixed by bolting or welding so as to be integral with the side of the frame 50, which also corresponds to the scope of the present invention.

Preferably to form the operation panel 110 on the vertical column (100a), which is one side of the auxiliary frame 100, the operation panel 110, the temperature control of the near-infrared radiator to be described later and the on-off of the radiator In addition, the rotational speed of the endless track can be controlled. Note that the configuration of the operation panel is a general known technique.

Subsequently, a fixing bar 310 is vertically connected to the vertical column 100a at a lower side of the horizontal pillar 100b of the auxiliary frame 100. The chamber 200 is provided below the fixed bar.

The chamber 200 is installed to be spaced apart from the crawler 60, and configured to adjust the vertical position as needed. To this end, the fixing bar 310 and the operation handle 320 are provided as the setting unit 300. The fixing bar 310 is provided with a plurality of operation handles, the end of the operation handle 320 is connected to the upper surface of the chamber 200 can be moved up and down.

The center shaft portion of the manipulation handle 320 is formed with a male screw thread, and is coupled with a female screw thread formed on the fixed bar to rotate. That is, as the upper surface of the chamber is coupled to the lower side of the center shaft portion to rotate the operation handle, the chamber is also changed up and down at the same time. In one embodiment of the present invention to adjust the vertical position of the chamber 200 is connected to this as the operation handle 320 is screwed to the setting unit 300, but is not limited thereto only and the chamber is up and down Other means of moving may also be used, which would also fall within the scope of the present invention.

Next, the radiator 210 and the reflector plate 220 formed in the chamber 200 will be described. The radiator 210 may use a well-known near-infrared lamp, and a preferable heat generation temperature is maintained at about 1800-2200 ° C. to generate near-infrared rays.

Reflector 220 is formed over the entire inner surface of the chamber 200, so that the radiator 210 is installed on the upper surface of the reflector. The reflector plate 220 is formed in the same shape as the chamber, and in one embodiment of the present invention, the chamber 200 and the reflector plate 220 are configured to have a rectangular opening. Forming a reflecting plate on the side of the chamber is to increase the efficiency by allowing the near-infrared radiation to be emitted to the upper side of the infinite crawler.

In addition, the reflector plate 220 is provided with a partition plate 225 partitioning the three regions as shown, and thus it is possible to independently control the temperature generated in each compartment, thereby, different products from each other It has the feature that it can be dried at the same time by putting. That is, in each chamber 200 divided by the partition plate 225, the temperature of each chamber can be adjusted differently by separately controlling the heating temperature of the radiator 210 which is installed independently.

The shape of the reflecting plate 220 is not limited to the flat rectangular structure as in the above embodiment, it may be configured in an arch shape. In an embodiment of the present invention, the chamber 200 is integrally manufactured and shanghai is also made at the same time. However, if necessary, the chamber 200 may be separated and manufactured to independently adjust the vertical position. .

Next, another embodiment of the present invention will be described. 4 is a schematic configuration diagram showing another embodiment of the present invention, and as shown, the chamber 200 and the reflector plate 220 may be formed.

As in one embodiment, the chamber 200 has three compartments, but in another embodiment, these three compartments are separated from each other so that the vertical position can be adjusted independently. In addition, the shape of the reflector plate 220 is also configured to be arcuate rather than flat so that the generated near infrared rays can be radiated toward the center.

In the present invention, the near-infrared ray is used as a heat generating source of the radiator, but the present invention is not limited thereto, and the substitution of a simple radiator falls within the scope of the present specification.

The present invention by the configuration as described above, by reducing the cycle time by performing the drying operation using the near-infrared rays, there is an effect that the productivity is increased, and the auxiliary frame is formed frame and reflector plate and chamber is formed Since the frame is manufactured separately, it is easy to carry and set.

In addition, the near-infrared shoe dryer according to the present invention is divided into a plurality of chambers by the vertical height adjustment function and the partition plate of the chamber, and under the optimum conditions according to the product introduced by adjusting the exothermic temperature of the radiator installed in each chamber. There is also an effect that the drying operation can be performed.

In addition, unlike the general hot air dryer, the present invention does not generate much vibration or noise during operation, and in addition to drying shoe finished products, it can be used for drying semi-finished products such as shoe soles and other products. It also works.

Claims (3)

In the shoe manufacturing conditioner to dry the shoe while the shoe is placed on the crawler 60 is rotated, An auxiliary frame 100 spaced apart from the upper end of the endless track body 60 to cross the endless track body; The reflector plate 220 is formed between the endless tracker 60 and the auxiliary frame 100 and is provided with a radiator 210 that emits near infrared rays and functions to irradiate the near infrared rays generated by the radiator downward. A chamber 200; A setting part 300 to which the fixing bar 310 and the reflecting plate 220 installed from the auxiliary frame 100 are constrained with the plurality of operation handles 320 to adjust the vertical position of the chamber 200; Near-infrared shoe dryer characterized in that it comprises a rapid drying treatment is configured to include. The method of claim 1, wherein the auxiliary frame 100, NIR shoe dryer, characterized in that the operation panel 110 is formed on one side. The method of claim 1 or 2, wherein the chamber 200, A near-infrared shoe dryer characterized in that it is divided into a plurality of zones so that the radiation temperature of each radiator 210 and the vertical position of the chamber 200 can be independently controlled.