KR200313498Y1 - apparatus for thermostatic control of shoe drier - Google Patents

Abstract

The present invention relates to a temperature control device of a shoe dryer, and is placed on a rotating crawler 130, and transferred into the chamber 120, the shoe dryer in the shoe drying by the near-infrared emitter 140 A non-contact infrared temperature sensor (200) installed at the outlet side of the chamber (120) for sensing the surface temperature of the shoe being placed and transported on the endless track body (130); A main controller 210 connected to the infrared temperature sensor 200 and controlling the radiation amount of the radiator 140 by receiving a signal transmitted from the infrared temperature sensor 200 and comparing with a set value; Connected to the infrared temperature sensor 200, receiving the signal transmitted from the infrared temperature sensor 200, if the transmitted signal value is less than the lower limit set value or more than the upper limit set value to control to maintain the previous signal value Auxiliary control unit 220; the temperature control device of the shoe dryer configured to include a technical gist. Accordingly, there is an advantage that the shoe is dried at a constant temperature by maintaining the temperature inside the drying furnace under a constant temperature.

Description

Apparatus for thermostatic control of shoe drier

The present invention relates to a temperature control device of a shoe dryer, and more particularly, to a temperature of a shoe dryer that detects the surface temperature of a shoe that has passed through a drying furnace using a non-contact infrared temperature sensor and controls the temperature inside the drying furnace. It relates to a control device.

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 done 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 on the upper portion of the diaphragm 101 and the conveyor belt 18 is attached to the roller 19 in an endless track on the upper portion of the diaphragm 101, and a suction port is formed on 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.

In order to solve the above problems, I filed myself under the title of Near-Infrared Shoe Dryer in the Korean Utility Model Registration No. 20-265379.

The prior art, as shown in Figure 2, in the shoe manufacturing conditioner so that the drying is made while the shoes are placed and moved on the rotating crawler 60, spaced apart on the upper track 60 An auxiliary frame 100 formed to cross the infinite track; 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; It is configured to include.

The prior art does not accurately detect the temperature of the shoes passing through the drying furnace by adopting a method of maintaining the drying temperature of the shoes by adjusting the ambient temperature in the drying furnace, thereby actively controlling the temperature of the outside air or the change of the material. There is a problem that is impossible.

Therefore, the present invention has been devised to solve the above problems of the prior art, by using a non-contact infrared temperature sensor to detect the surface temperature of the shoes passing through the drying furnace, thereby maintaining a constant drying temperature inside the drying furnace. And at the same time it is an object to provide a temperature control device of the shoe dryer that can control the temperature inside the drying furnace.

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

2 is a schematic perspective view of a shoe dryer according to another prior art.

3 is a perspective view of a shoe dryer equipped with a temperature control device according to the present invention.

4-front schematic view.

5-a block diagram of a temperature control device.

<Description of Symbols for Major Parts of Drawings>

100: frame 110: auxiliary frame

120: chamber 130: infinite track

131 dry plate 132 bar

140: radiator 150: reflector

160: adjustment bar 170: operation handle

200: infrared temperature sensor 210: main control part

220: auxiliary control unit 240: computer

The present invention for achieving the above object is a shoe dryer, which is placed on a rotating endless track body, is transferred to the inside of the chamber to dry the shoes by a near-infrared radiator, which is installed at the outlet side of the chamber, the endless A non-contact infrared temperature sensor for sensing the surface temperature of the shoe being transported on the track body; A first control unit connected to the infrared temperature sensor and receiving a signal transmitted from the infrared temperature sensor to control the radiation amount of the radiator by comparing with a set value; A second control unit connected to the infrared temperature sensor and configured to receive a signal transmitted from the temperature sensor and control to maintain the immediately previous signal value when the transmitted signal value is lower than or equal to the lower limit or higher than the upper limit. The technical control of the temperature control device of the shoe dryer is composed.

Here, the main control unit is connected to the communication port it is preferable that the detection temperature is monitored in real time.

Accordingly, there is an advantage that the shoe is dried at a constant temperature by maintaining the temperature inside the drying furnace under a constant temperature.

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

Figure 3 is a perspective view showing a temperature control device of the shoe dryer according to the present invention, Figure 4 is a front schematic view, Figure 5 is a block diagram of the temperature control device.

As shown, the temperature controller of the shoe dryer according to the present invention is installed in the shoe dryer, and is composed of an infrared temperature sensor 200, the main control unit 210, and the auxiliary control unit 220.

First, a brief description of the shoe dryer according to the present invention.

As shown, the shoe dryer of the present invention is composed of a frame 100, the auxiliary frame 110, the chamber 120 and the infinite track 130, the chamber 120 emits near-infrared radiation 140 ) And a reflection plate 150 to guide the generated near infrared rays to the lower side.

The auxiliary frame 110 is configured as a fixed bar 160 installed from the auxiliary frame 110 and an operation handle 170 formed in the fixed bar 160.

On the frame 100, an endless tracker 130 driven by a motor (not shown) is installed and repeated rotational movement occurs. On the upper surface of the endless tracker 130, a shoe, which is a drying object, is loaded. The loaded shoes are passed along with the rotation of the endless track body 130 to pass through the chamber 120, and drying of the shoe adhesive portion is made while passing through the chamber 120.

The crawler 130 is composed of a chain and a sprocket, and a drying plate 131 is installed to load a drying object on a long bar 132 formed from the chain.

The chamber 120 is installed to be spaced apart from the infinite crawler 130, and configured to adjust the upper, lower positions as necessary. The fixing bar 160 is provided with a plurality of operation handles 170, the end of the operation handle 170 is connected to the upper surface of the chamber 120 to be able to move the chamber 120 up and down.

An operation panel is formed on one side of the auxiliary frame 110 to form a control unit, which will be described later, on the operation panel.

The shoe passing through the shoe dryer is dried by the radiant heat of the near-infrared radiator 140 while passing through the chamber 120, and then flows out of the chamber 120. At this time, the drying temperature inside the chamber 120 should be kept constant, the temperature control apparatus of the present invention maintains the shoe drying temperature inside the chamber 120 constant.

Hereinafter, the temperature control device will be described in detail.

The infrared temperature sensor 200 is installed at the outlet side of the chamber 120 and detects the surface temperature of the shoe coming out of the chamber 120 while being placed on the crawler 130.

Normally, all objects above minus 273 ℃ have a slight vibration of atoms, the basic unit of matter. Since the vibrational energy of these atoms is the same as that of the infrared region, all objects emit infrared radiation. And the higher the temperature, the more infrared rays are emitted. For this reason, infrared rays are also called hot wires. By detecting infrared rays emitted from an object, it is possible to detect the temperature of the surface of the object without direct contact with the object. do. Since the infrared temperature sensor 200 corresponds to a known technique, a detailed description thereof will be omitted.

The detected signal is transmitted to the main control unit 210 formed on the operation panel.

The main control unit 210 is formed on the operation panel and is electrically connected to the radiator 140 while being connected to the infrared temperature sensor 200.

Therefore, when the signal transmitted from the infrared temperature sensor 200 is more than the set temperature (T), which is a set value, the radiator 140 is controlled to reduce the radiation amount of the radiator 140, and when the signal is less than the set temperature (T) The radiator 140 is controlled to increase the radiation amount of the radiator 140. The main controller 210 is configured to control the on / off of the radiator 140 and the rotational speed of the infinite crawler 130.

The auxiliary control unit 220 is formed on the operation panel, it is connected to the infrared temperature sensor 200 and the control unit 210.

The side of the auxiliary control unit 220 is a signal transmitted from the infrared temperature sensor 200, the detection signal when there is no shoes, or when there is a foreign body in the trackless body 130, which is an abnormal signal. If there is no shoes on the endless track body 130, or there is a foreign material is a sudden temperature rise or temperature drop will be detected.

When the abnormal temperature rise or abnormal signal of the temperature drop, i.e., the lower limit set point T _L value below a specific temperature or the upper limit set value T _U or more above a specific temperature is transmitted from the infrared temperature sensor 200, The auxiliary control unit 220 confirms that the transmitted signal is an abnormal signal, and transmits a control signal to the main control unit 210 to maintain the immediately previous signal value.

Therefore, the main controller 210 controls the radiation amount of the radiator 140 to correspond to the previous signal value.

Although the auxiliary control unit 220 has been described in a form separate from the main control unit 210, the main control unit 220 may be configured to include the function of the auxiliary control unit 220 in the main control unit 210. It belongs to the category of design.

The main control unit 210 is connected to the computer 240 using a communication port such as RS-232C, the signal detected by the infrared temperature sensor 200 is transmitted to the computer 240 to monitor the drying temperature of the shoe in real time Configured to do so.

The operation effect by the above configuration is as described later.

The user places the shoes to be dried on the upper surface of the drying plate 131 on the endless track body 130, input the set values, such as set values, upper and lower set values in the control unit 210, 220 to operate the dryer. do.

By operating the dryer, the crawler 130 is rotated, and the shoes placed on the crawler 130 are introduced into the chamber 120 and the radiator 140 generates radiant heat corresponding to the set value. The shoe to which the is applied becomes dry.

The dried shoes are leaked to the outside of the chamber 120 and the surface temperature of the leaked shoes is sensed by the infrared temperature sensor 200, and the detected signals are transmitted to the main control unit 210 so that the main control unit 210 is transferred to the main control unit 210. By controlling the radiation amount of the radiator so that the surface temperature of the shoe is kept constant, the drying temperature of the shoe is kept constant.

At this time, the abnormal signal is transmitted to the auxiliary control unit 220 so that the main control unit 210 maintains the previous signal value, so that the abnormal signal corresponds to a sudden temperature change.

The present invention by the above configuration, there is an effect that the shoe is dried at a constant temperature by maintaining a constant temperature inside the drying furnace.

In addition, even if an external factor such as a sudden temperature change is applied, the interior of the dryer can maintain a stable constant temperature, and thus active temperature control is also possible in response to a sudden temperature change or a change in material.

In addition, the real-time monitoring of the drying temperature can be confirmed in real-time trends, such as changes in the surface temperature of the shoe material, there is an effect that the immediate action is possible when abnormality is found.

Claims (2)

In the shoe dryer, which is placed on the endless track body 130 that is rotated and is transferred into the chamber 120 to dry the shoe by the near-infrared radiator 140, A non-contact infrared temperature sensor 200 installed at an exit side of the chamber 120 and detecting a surface temperature of a shoe that is placed and transported on the endless track body 130; A main controller 210 connected to the infrared temperature sensor 200 and controlling the radiation amount of the radiator 140 by receiving a signal transmitted from the infrared temperature sensor 200 and comparing with a set value; Connected to the infrared temperature sensor 200, receiving the signal transmitted from the infrared temperature sensor 200, if the transmitted signal value is less than the lower limit set value or more than the upper limit set value to control to maintain the previous signal value Auxiliary control unit 220; temperature control device of the shoe dryer characterized in that it comprises a. According to claim 1, The main control unit 210 is connected to the communication port temperature control device of the shoe dryer, characterized in that the detection temperature is monitored in real time.