KR101048424B1 - Oven Conveyors for Hardening Vessels - Google Patents

Abstract

The present invention relates to an oven conveyor capable of curing a container produced through a thermoforming process, and an object of the present invention is to move a container produced through a thermoforming process to a hot winder having different temperatures. It is to provide an oven conveyor for curing the container, which can be discharged after being made. To this end, the present invention, the container is injected; A hot air part for heating the container introduced through the input part; A discharge part through which the container transmitted from the hot air part is discharged; And a controller for controlling the functions of the input unit, the hot air unit, and the discharge unit, wherein the temperature inside the hot air unit may be changed from the input unit direction to the discharge unit direction.

Canister, curing, oven

Description

Oven conveyor for container curing {AN OVEN CONVEYOR FOR AGING A CONTAINER}

The present invention relates to an apparatus for manufacturing a container, and more particularly, to an oven conveyor capable of curing a container produced through a thermoforming process.

In general, typical disposable products that are used once and discarded include lunch box containers, cup noodles containers, buffers, etc. (hereinafter, simply referred to as 'containers').

Most of these containers are easily manufactured and used in plastic, and are generally manufactured by a PLA extrusion process consisting of a sheet preheating step, a product forming step, an automatic alignment step, an aging (hardening) step, and a lamination / packing step. .

On the other hand, the container produced through the thermoforming step as described above may further improve heat resistance and durability due to the curing process.

Therefore, in the related art, after the production is completed, the container is directly put into the oven for curing, and the curing is performed while controlling the temperature. After the predetermined time elapses, the container is discharged and taken out to the product.

However, the conventional curing oven as described above simply cures the container in a heated state to a predetermined temperature, and the user needs to control the temperature control and curing time, etc. Inadequate control of temperature and time has led to the occurrence of defective products.

In addition, since the user has to put or discharge the container in the oven to match the curing temperature and time, there is a problem that the work efficiency is reduced.

An object of the present invention for solving the above problems is to provide an oven conveyor for curing the container, which can be discharged after curing while moving to the hot air portion is set to a different temperature through the thermoforming process. It is.

The present invention for achieving the above object, the input unit is a container; A hot air part for heating the container introduced through the input part; A discharge part through which the container transmitted from the hot air part is discharged; And a controller for controlling the functions of the input unit, the hot air unit, and the discharge unit, wherein the temperature inside the hot air unit is lowered from the input unit direction toward the discharge unit direction.

The present invention has an excellent effect that the curing process can be automatically performed by moving the container produced through the thermoforming process to a hot air portion set at different temperatures and then curing the container.

In addition, since the present invention can automatically harden 20,000 containers at a time by performing the curing process, the work efficiency can be significantly improved compared to the manual type, which can only process about 60 at a time. have.

In addition, the present invention has an excellent effect that the user's labor is unnecessary because the curing process for the container is automatically made according to the preset temperature and speed.

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

1 is a perspective view of one embodiment of a container curing oven conveyor according to a first embodiment of the present invention, Figure 2 is a plan view of one embodiment of a container curing oven conveyor according to a first embodiment of the present invention.

The oven curing container conveyor according to the present invention is to automatically cure the heat-resistant container to be discharged to the final shipment product, the operator automated the operation of curing the container by putting the container directly into the oven. That is, the present invention is in the process of manufacturing a container by the conventional PLA extrusion process consisting of a sheet preheating step, product forming step, automatic alignment step, aging (aging, curing) step and lamination / packaging step, in particular, the aging (curing) step Performs a function to automatically execute.

To this end, the oven curing oven conveyor according to the present invention, as shown in Figures 1 and 2, the input unit 100, the container is introduced, hot air blowing unit 200 for heating the container while the temperature is sequentially changed , A discharge part 500 through which the container transmitted from the hot air part is discharged, and a control part 600 for controlling the functions of the input part, the hot air part, and the discharge part.

First, the input unit 100 performs a function of receiving a container that has been thermoformed, and transmits the container, which is composed of a plurality of rollers, to the hot air blowing unit. To this end, as shown in Figures 1 and 2, the input unit, the input unit 120 for sequentially inputting the container, the input feeder 110 for transferring the input container to the hot air blowing portion and for supporting the feeder and the input feeder It is configured to include a support (130). Here, the injector 120 allows the containers to be stacked in the vertical direction, and discharges the containers at the lowermost portion to the inlet feeder sequentially, and is configured such that the containers stacked vertically can be arranged in two rows. Meanwhile, as illustrated in FIG. 2, the input feeder 110 includes three rollers including the first input feeder 110a, the second input feeder 110b, and the third input feeder 110c. The container discharged from the first row of feeders is conveyed to the hot air section while spanned by the first feed conveyor and the second feed feeder, and the container discharged from the second row of feeders is transferred to the second feed feeder and The hot air is conveyed to the hot air blowing portion while being held by the third feed conveyor. That is, the present invention can transfer two containers to the hot air at a time. On the other hand, the roller constituting the input feeder, the operation of the components for sequentially discharging the container in the feeder may be driven by a drive unit (not shown) such as a motor controlled by the control unit.

Next, the hot air unit 200 performs a function of curing the container transferred from the input unit to a preset temperature, for example, 150 to 50 ° C. to be aged. To this end, the hot air unit is a tunnel-shaped housing 210 through which the front and rear surfaces are connected to the input unit, at least two or more hot air heaters 220 to be mounted on the top or side of the housing to generate hot air. A first heat circuit breaker 230 mounted to the front of the housing to prevent the heat inside the housing from being discharged toward the inlet, and mounted to the rear of the housing to prevent the heat inside the housing from being discharged toward the outlet; 2 thermal breaker 270, a temperature sensor 240 mounted on the housing for sensing the temperature inside the housing, a speed sensor 250 mounted on the housing for detecting the speed of the container passing through the housing, from the housing It includes a feeder 260 for transferring the container introduced into the discharge unit 500 direction and a support 290 for supporting the feeder, the housing and the hot air.

The housing 210 has a front surface and a rear surface penetrated therein, and may be formed in a rectangular shape as shown in FIGS. 2 and 3, but may also be formed in a domed shape having a rounded upper surface.

The hot air heater 220 is for heating the inside of the housing to a predetermined temperature, and may be composed of a heater for generating heat and at least one fan for circulating air heated by the heater. On the other hand, the present invention is to cure the container undergoing the molding process in a hot heated state, while gradually cooling to a low temperature, the temperature inside the housing is preferably lowered toward the discharge direction from the input direction. Therefore, the present invention can be equipped with a plurality of hot air fans in the housing, in particular, by setting the temperature of the heater of each hot air fan differently, the temperature can be lowered toward the discharge direction from the input direction.

The first heat circuit breaker 230 may be mounted on the front upper end of the housing and may be configured as a curtain draped toward the input unit 100. In this case, the curtain may be formed of a material that is not deformed by the heat inside the housing, for example, a thin plate-shaped metal curtain. In addition, the second heat circuit breaker 270 is formed of a metal curtain like the first heat circuit breaker, and is mounted on the upper end of the rear surface of the housing so that the second heat circuit breaker 270 may be draped toward the discharge part 500. However, the first heat circuit breaker or the second heat circuit breaker may be composed of an air curtain to be mentioned in the following description.

The temperature sensor 240 detects a temperature inside the housing and may be configured by using various types of temperature sensors which are generally used. The temperature information detected by the temperature sensor is transmitted to the controller, and when the temperature by the temperature information is different from the temperature inside the preset housing, the controller controls the heater or the fan of the hot air fan to maintain the temperature inside the housing at the preset temperature. To perform the function. In addition, the present invention is to reduce the temperature inside the housing sequentially from the input unit direction to the discharge unit direction, by mounting a plurality of temperature sensors in the housing, by sensing the temperature of each section inside the housing, each section The temperature of the hot air fan in charge can be controlled individually.

The speed sensor 250 detects a moving speed of the container in the housing, and may be configured using various types of speed sensors that are currently used. That is, the speed sensor detects the moving speed of the conveyor (belt or roller) mounted inside the housing or directly measures the speed of the container passing over the conveyor (belt or roller) by using a sensor composed of a light emitting part and a light receiving part. It may be detected, or may be detected by detecting the rotational speed of the motor (drive unit) for driving the conveyor (belt or roller). The speed information detected by the speed sensor is transmitted to the control unit. When the speed by the speed information is different from the preset speed inside the housing, the control unit controls the driving unit that is responsible for driving the feeder, thereby moving the speed of the container inside the housing. This function keeps the speed at the preset speed.

That is, the hot air unit as described above is provided with a hot air fan 220 capable of generating hot air, and is composed of a feeder (belt) 260 connected to the input unit, the containers that have undergone the curing process inside the housing automatically It performs a function to transfer to the discharge unit (500). On the other hand, as described above, between the hot air blowing portion 200 and the input portion 100 and between the hot air blowing portion and the discharge portion 500 is provided with a first and second heat circuit breaker consisting of a metallic curtain or air curtain, Heat inside the housing can be prevented from escaping to the outside through the inlet or outlet direction.

In addition, in the inside of the housing of the hot air section, when each section in the housing is managed at a separate temperature, each section should be managed at a separate temperature. In the part barking each section, the metal curtain as described above Alternatively, by mounting a plurality of third heat circuit breakers composed of air curtains, the temperature of each section inside the housing may be maintained separately. That is, according to the present invention, the inside of the housing of the hot air can be separated into three temperature sections, and the third and fourth heat circuit breakers can be mounted between the sections. At this time, the present invention can be divided into the first section 150 ~ 100 ℃, the second section 100 ~ 80 ℃, the third section 80 ~ 50 ℃ from the direction of the input portion of the housing interior space, the first section The third and fourth thermal breakers which perform the same function as the first or second thermal breakers between the second section and the second section and between the second section and the third section, so that the temperature of each section is maintained separately. In this case, by installing a temperature sensor for each section, the control unit may control the temperature of each section individually.

Next, the discharge part 500 performs a function of receiving a container of which the heat curing process is completed and discharging it to the outside while passing through a hot winder, and sequentially stacking the discharged container consisting of a plurality of rollers. . To this end, the discharge unit as illustrated in FIGS. 1 and 2, a stacker 520 for sequentially stacking containers, a stack transporter 510 for transporting a container discharged from the hot air to the stacker, and a stacker with a stacker. It is configured to include a support 530 for supporting the conveyor. Here, the stacker 520 is for stacking the containers conveyed from the stack transport in the vertical upward direction, and is configured to stack the containers in two rows. Meanwhile, as illustrated in FIG. 2, the stacked feeder 510 includes three rollers including a first stacked feeder 510a, a second stacked feeder 510b, and a third stacked feeder 510c. The container conveyed from the first stacker and the second stacker is stacked in the first row of the stacker, and the container transported from the second stacker and the third stacker is the second stacker. Stacked in rows. That is, the present invention can be discharged by receiving two containers from the hot air at a time. On the other hand, the roller constituting the stacking conveyer, the operation of the components for sequentially stacking the container in the stacker may be driven by a drive unit (not shown) such as a motor controlled by the control unit.

Lastly, the control unit 600 is for controlling the functions of the input unit, the hot air unit, and the discharge unit as described above, and as illustrated in FIG. 2, the driving unit (roller or motor) mounted on the components. Etc.), a fan, a heater, a temperature sensor, an interface 610 for communicating with speed sensors, an input unit 630 for receiving various control signals from a user, an input control signal or the driving unit, a fan, a heater, and the like. , An output device 640 for outputting information transmitted from at least one of a temperature sensor and a speed sensor, a storage device 650 storing various information necessary for controlling the components, and the interface, input device, and output device. It may be configured to include a controller 620 for controlling the function of the storage. Here, the interface may communicate with the driving unit, the fan, the heater, the temperature sensor, and the speed sensors in a wired or wireless manner.

3 is an exemplary view showing a thermal breaker applied to the oven curing oven conveyor according to the first embodiment of the present invention, in particular, an exemplary view showing the configuration of the thermal breaker that can generate an air curtain.

As described above, the first to fourth heat breakers mounted on the hot air part may be configured of a metal curtain or an air curtain. Hereinafter, the air curtain may be configured using the first heat breaker 230 illustrated in FIG. 3. This is explained.

That is, as illustrated in FIG. 3, the first heat circuit breaker 230 including the air curtain is mounted on the fan 231 driven by the driving unit to generate air, and the upper side of one side of the housing bordering the discharge unit. In the interior space, a plurality of nozzles are formed to face the first duct 233 on which the fan is mounted, and the conveyor (belt or roller) mounted on the vertical bottom of the duct among the surfaces of the first duct ( 234 and a second duct 232 extending from the lower end of the conveyor facing the plurality of nozzles to the left and right sides of the housing and penetrating the duct.

Therefore, the air injected from the nozzle flows into the second duct disposed in the vertical lower end of the nozzle, moves along the second duct extending on the left and right sides of the housing, and then flows back into the first duct. As such, the reason for introducing the air discharged from the first duct back into the first duct is to minimize the temperature change inside the first housing. That is, since the air discharged from the first duct is in contact with the inside of the housing, the air inside the housing can be absorbed during the injection process, and the heat inside the housing is absorbed by absorbing the heat inside the housing and reusing the heated air. Emission to the outside can be prevented. On the other hand, for the above purpose, the first heat circuit breaker may receive the air heated by the heater of the hot air inlet and discharge it through the nozzle.

In addition to the first heat circuit breaker, the second heat circuit breaker or the third heat circuit breaker and the fourth heat circuit breaker may also be configured as the air curtain as described above.

Referring to the operation method of the container curing oven conveyor according to the present invention as follows.

The container produced through the thermoforming process is transferred to the input unit 100 by the user or through another roller connected to the input unit, and then transferred to the hot air blower 200 by the input feeder 110 of the input unit. do.

The container is thermally cured while the heater and the fan are driven by the controller to pass through the hot air portion maintained at the preset temperature. At this time, the temperature inside the hot air is maintained at a high temperature as described above, it may be smaller than the temperature of the container itself. Moreover, the temperature inside a hot air blast part is comprised so that it may become low toward a discharge part direction from an input part direction by a hot air fan.

The container passing through the hot air blowing unit 200 is finally discharged to the outside through the discharge unit 500.

Meanwhile, the temperature sensing unit or the speed detecting unit mounted on the hot air unit detects the temperature or the moving speed of the vessel inside the housing of the hot air unit and transmits it to the control unit, and the control unit detects the detected temperature or speed and the preset temperature or speed. In different cases, the driving unit, the fan, or the heater may be driven to maintain the temperature or speed of the inside of the housing of the hot air at a predetermined temperature or speed.

Figure 4 is a perspective view of one embodiment of a container curing oven conveyor according to a second embodiment of the present invention, Figure 5 is a plan view of one embodiment of a container curing oven conveyor according to a second embodiment of the present invention. In the following description, descriptions of the same constructions and functions as those described in the first embodiment will be briefly described or omitted.

As shown in FIGS. 4 and 5, an oven conveyor for curing a container according to a second embodiment of the present invention includes an input unit 10 into which a container is input, and a first hot air unit for heating the container to a first temperature. 20, the second hot air portion 30 for conveying the container heated in the first hot air portion while maintaining the second temperature, for discharging the container transferred from the second hot air portion to the third temperature and then discharging it To control the function of the third hot air blowing portion 40, the discharge portion 50 through which the container transmitted from the third hot air blowing portion is discharged and the input portion, the first hot air blowing portion, the second hot air blowing portion, the third hot air blowing portion, and the discharge portion. It is configured to include a control unit 60 for.

First, the input unit 10 performs a function of receiving a container that has been thermoformed, and transmits the container, which is composed of a plurality of rollers, to the first hot air blowing unit. The roller is driven by a driving unit (not shown) such as a motor, and the driving unit may be mounted on the support 70 or the like. In addition, the driving unit may be driven by a control signal transmitted from the controller 60 by wire or wirelessly. On the other hand, the driving unit may perform a function of driving all the rollers mounted on the first hot winder, the second hot winder, the third hot winder and the discharge unit as well as the input unit.

Next, the first hot air blower 20 performs a function of curing the container transferred from the input part to a predetermined temperature, for example, 100 to 150 ° C. by aging. To this end, the first hot air blower is installed in the tunnel-shaped first housing 21 through which the front and rear surfaces connected to the input part are penetrated, and the first hot air blower 22 for generating hot air. ), Mounted on the front of the first housing to prevent the heat inside the first housing is discharged in the direction of the inlet, the first heat circuit breaker 23, mounted on the first housing to sense the temperature inside the first housing A temperature sensor 24 for mounting, a speed sensor 25 mounted on the first housing for detecting the speed of the container passing through the first housing, and continuously connected to a roller of the feeding unit to transfer the container in the direction of the second hot air balloon And a conveyer 26.

The first housing 21 has a front surface and a rear surface penetrated therein, and may have a rectangular shape as illustrated in FIGS. 4 and 5, but may also have a domed shape having a rounded upper surface.

The first hot air fan 22 is configured to heat the inside of the first housing to a predetermined temperature, and includes a heater 22b for generating heat and at least one fan 22a for circulating air heated by the heater. Can be.

The first heat circuit breaker 23 may be mounted on the front upper end of the first housing and draped in the direction of the feeder (roller) 26. At this time, the curtain may be composed of a metal curtain or an air curtain, as described in the first embodiment. In addition, a third heat breaker 23 ′ having the same shape as the first heat breaker or the second heat breaker may be mounted on the rear surface of the first housing.

The temperature sensor 24 senses the temperature inside the first housing and performs the same function as the temperature sensor described in the first embodiment.

The speed sensor 25 senses the moving speed of the container inside the first housing, and performs the same function as the speed sensor described in the first embodiment.

That is, the first hot air unit as described above is provided with a first hot air fan 22 capable of generating hot air, and is composed of a feeder (roller) 26 connected to the input unit, and is cured inside the first housing. Automatically transfers the processed containers to the second hot air balloon. On the other hand, between the first hot air portion and the input portion is provided with a first heat circuit breaker consisting of a metallic curtain or air curtain, it is possible to prevent the heat inside the first housing to escape to the outside through the input portion. In addition, a third heat breaker including the metal curtain or the air curtain as described above may be provided between the first hot air portion and the second hot air portion.

Next, the second hot air blower 30 performs a function of transferring the container transferred from the first hot air blower to the third hot air blower while maintaining a constant temperature. To this end, the second hot air is composed of a first housing and a second housing 31 through which the second hot air is penetrated, and the inside of the second hot air is connected to a feeder (roller) of the first hot air and the third hot air. It consists of the machine (roller) 34. As shown in FIG. That is, the first housing, the second housing, and the third housing to be described below are formed as one through tunnel, and form a closed space except for the inlet and the outlet. However, the third hot breaker 23 ′ as described above may be provided at the connecting portion of the first hot winder and the second hot winder, and the first to third hot breakers may also be provided between the second hot winder and the third hot winder. A fourth heat breaker 43 ′ capable of performing the same function may be provided. That is, the plurality of thermal breakers as described above are spaces generated in the respective compartments, that is, the heat generated in each of the first hot air portion, the second hot air portion, and the third hot air portion, or adjacent to the adjacent space. It blocks the transmission. On the other hand, the thermal breakers are intended to be easily transported to the discharge portion along the roller, the container introduced through the input portion, it is preferable that the metal curtain or air curtain formed of a thin metal plate capable of withstanding high temperature as described above Do. In addition, at least one of a temperature sensor or a speed sensor that performs the same function as the temperature sensor or the speed sensor mounted on the first hot wind unit may be mounted inside the second hot air unit. On the other hand, the temperature inside the second hot air portion is preferably kept smaller than the temperature inside the first hot air portion, for example, may be maintained at 80 ~ 100 ℃.

Next, the third hot air blower 40 heats the container transferred from the second hot air blower to a predetermined temperature, for example, a temperature lower than the temperature of the second hot air blower (50 to 80 ° C.), thereby curing the container. To perform the function. To this end, the third hot air portion is mounted on the upper or side surfaces of the tunnel-shaped third housing 41 and the third housing through which the front surface connected to the discharge portion and the rear surface connected to the second hot air portion are penetrated. The second hot air blower 42 for generating a heat, 42 is mounted on the front of the third housing is installed in the second heat circuit breaker 43, the third housing to prevent the heat inside the third housing to be discharged toward the discharge portion Temperature sensor 44 for sensing the temperature inside the third housing, a speed sensor 45 for detecting the speed of the container passing through the third housing, mounted in the third housing, the container is continuously connected to the roller of the discharge It includes a feeder (roller) 46 for conveying in the direction of the discharge portion.

Here, except that the temperature inside the third housing is kept smaller than that of the first hot air blower and the second hot air blower by the second hot air blower composed of the heater 42b and the fan 42a. Functions and components are the same as those of the first hot air portion. Therefore, detailed description thereof is omitted.

On the other hand, as described above, the first to fourth thermal breakers mounted on the first hot air portion and the third hot air portion may be configured of the metal curtain or the air curtain as described above.

Next, the discharge part 50 is for discharging the container, which has undergone the thermal curing process from the third hot air part while passing through the first hot air part to the third hot air part, to be discharged to the outside, and is composed of a plurality of rollers as the input part. It is.

Lastly, the control unit 60 is for controlling the functions of the input unit, the first hot air unit, the second hot air unit, the third hot air unit and the discharge unit as described above, and are mounted on the components. , An interface 61 capable of communicating with a fan, a heater, a temperature sensor, and speed sensors, an input unit 63 for receiving various control signals from a user, an input control signal or the driving unit, a fan, a heater, a temperature An output 64 for outputting information transmitted from at least one of a sensor and a speed sensor, a storage 65 in which various information necessary for controlling the components is stored, and the interface, input, output, and storage. It may be configured to include a controller 62 for controlling the function of the group.

Here, the interface may communicate with the driving unit, the fan, the heater, the temperature sensor, and the speed sensors in a wired or wireless manner.

Referring to the operation method of the container curing oven conveyor according to the present invention as follows.

The container manufactured through the thermoforming process is transferred to the input unit 10 by the user or through another roller connected to the input unit, and then transferred to the first hot air unit 20 by the roller of the input unit.

The container is thermally cured while passing through the first thermosetting unit in which the heater and the fan are driven and maintained at a predetermined temperature by the controller. At this time, the temperature inside the first heat curing unit is maintained at a high temperature as described above, may be smaller than the temperature of the container itself.

The container which has passed through the first hot air portion is thermoset again while passing through the second hot air portion. At this time, the temperature of the second hot air portion is maintained at a temperature smaller than the temperature of the first heat curing portion.

The container which passed the 2nd hot air part is finally thermosetted while passing through a 3rd hot air part. At this time, the temperature of the third hot air portion is maintained at a temperature smaller than the temperature of the second heat curing portion.

The container passing through the third hot air portion is finally discharged to the outside through the discharge portion.

On the other hand, while the first hot air portion to the third hot air portion while the container is input and transported, the first housing to the third housing or the temperature inside the housing or the moving speed of the container is sensed and transmitted to the control unit, the control unit is When the temperature or speed is different from the preset temperature or speed, the driving unit, the fan, or the heater may be driven to maintain the temperature or speed inside the first to third housings at the predetermined temperature or speed.

Those skilled in the art will appreciate that various changes and modifications can be made without departing from the technical spirit of the present invention. Therefore, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification, but should be defined by the claims.

1 is a perspective view of one embodiment of the oven conveyor for curing the container according to the first embodiment of the present invention.

Figure 2 is a plan view of one embodiment of the oven conveyor for curing the container according to the first embodiment of the present invention.

Figure 3 is an illustration of a thermal circuit breaker applied to the oven curing oven conveyor in accordance with a first embodiment of the present invention.

Figure 4 is a perspective view of one embodiment of a container curing oven conveyor according to a second embodiment of the present invention.

Figure 5 is a plan view of one embodiment of a container curing oven conveyor according to a second embodiment of the present invention.

<Description of the symbols for the main parts of the drawings>

100: inlet 200: hot air

500: discharge part 600: control part

Claims (15)

An input unit into which a container is inserted; A hot air part for heating the container introduced through the input part; A discharge part through which the container transmitted from the hot air part is discharged; And It includes a control unit for controlling the function of the input unit, hot air blowing unit, discharge unit, The temperature inside the hot air portion can be changed from the input part direction to the discharge part direction, The hot air portion, A tunnel-shaped housing through which front and rear surfaces facing the inlet and outlet are penetrated; At least two hot air fans mounted on an upper side or side of the housing to generate hot air; A first heat circuit breaker mounted on a front surface of the housing to prevent heat inside the housing from being discharged toward the input part; A second heat circuit breaker mounted on a rear surface of the housing to prevent heat inside the housing from being discharged toward the discharge part; A temperature sensor mounted on the housing for sensing a temperature inside the housing; It includes a feeder for transferring the container introduced into the housing from the inlet in the direction of the outlet, The control unit is a container curing oven conveyor, characterized in that for controlling the temperature inside the housing in accordance with the temperature information transmitted from the temperature sensor. The method of claim 1, The input unit, An injector for sequentially injecting the containers; And Container curing oven conveyor comprising an input feeder for transferring the container introduced through the feeder to the hot air portion. The method of claim 2, The injector, Container stacking oven conveyor characterized in that the container is stacked in the vertical direction, the container at the bottom end sequentially discharged to the inlet feeder. The method of claim 2, The input feeder includes a first input feeder, a second input feeder and a third input feeder composed of rollers, The first input feeder and the second input feeder conveys the container discharged from the first heat of the feeder to the hot air portion, And the second input feeder and the third input feeder transport the container discharged from the second heat of the feeder to the hot air portion. delete The method of claim 1, The hot air portion, And a speed sensor mounted on the housing to detect a speed of the container passing through the housing. The control unit is a container curing oven conveyor, characterized in that for controlling the transfer speed of the container passing through the housing in accordance with the speed information transmitted from the speed sensor. The method of claim 1, The first heat circuit breaker or the second heat circuit breaker, Oven conveyor for curing the container, characterized in that the air curtain. The method of claim 1, Inside the housing, A first section facing the input section and maintained at a first temperature; A second section continuous with the first section and maintained at a second temperature; And It is continuous with the second section, facing the discharge portion, it can be divided into a third section maintained at a third temperature, The control unit, And control the hot air blowers such that the second temperature is lower than the first temperature and the third temperature is lower than the second temperature. The method of claim 8, A third heat circuit breaker mounted between the first section and the second section to prevent heat from the first section from being discharged into the second section; And And a fourth heat circuit breaker mounted between the second section and the third section to prevent the heat of the second section from being discharged into the third section. The method of claim 1, The discharge portion, A laminator for sequentially laminating containers; And The oven conveyor for curing the container comprising a stacking conveyer for transferring the container discharged from the hot air to the stacker. The method of claim 7, wherein The air curtain, A fan for generating air; A first duct mounted on an upper end of the housing and having a fan mounted therein; A plurality of nozzles formed to face a roller mounted at a vertical lower end of the first duct among the surfaces of the first duct; And And a second duct extending from the lower ends of the rollers facing the plurality of nozzles to the left and right sides of the housing and penetrating the first duct. The method of claim 7, wherein The air curtain, Oven conveyor for curing the container, characterized in that using the air heated by the hot air fan. The method of claim 1, The hot air portion, A first hot air blower for heating the container introduced through the feeder to a first temperature; A second hot wind portion for conveying the vessel heated in the first hot wind portion while maintaining the second temperature; And A third hot winder for discharging the container transferred from the second hot winder to a third temperature and then discharging the container; The control unit is a container curing oven conveyor, characterized in that for controlling the function of the input unit, the first hot air portion, the second hot air portion, the third hot air portion. The method of claim 13, The first hot air portion or the third hot air portion, A tunnel-shaped housing through which front and rear surfaces are penetrated; A hot air fan mounted on an upper side or a side of the housing to generate hot air; A thermal breaker mounted on a front surface of the housing to prevent heat from being discharged to the outside of the housing; And Conveyor curing oven conveyor comprising a roller for conveying the container. The method of claim 13, Is mounted on at least one of the first hot air portion, the second hot air portion, and the third hot air portion, and the inside of at least one of the first hot air portion, the second hot air portion, and the third hot air portion. Further comprising a temperature sensor for sensing the temperature, The controller may control the temperature of at least one of the first hot winder, the second hot winder, and the third hot winder by analyzing a temperature detection signal transmitted from the temperature sensor. conveyor.

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