KR101320797B1 - Dry oven used in production of polyester highly elastic cushioning material - Google Patents

Abstract

PURPOSE: A dry oven for highly elastic polyester cushion material production is provided to increase pressurization efficiency as heat with high temperature, which is heated through a pressurizing board and an interval and a thorough hole in between the pressurizing boards, is sent to the center of a laminated product and to obtain a cushion material with excellent quality since elasticity is improved as restoration is not conducted by cooling tissues in a state in which the laminated product is pressurized. CONSTITUTION: A dry oven for highly elastic polyester cushion material production comprises housing, an upper pressurizing unit, a lower pressurizing unit, and a cooling apparatus. The housing forms a space, in which heat is supplied, inside and forms an inlet part and an outlet part on sides. [Reference numerals] (100) Opening unit; (200) Carding unit; (300) Web laminating unit; (400) Heating and pressurizing unit; (AA) Normal cocoon floss

Description

Dry oven used in production of polyester highly elastic cushioning material}

The present invention relates to a dry oven for polyester high-elastic cushioning material, and more specifically, to press the laminate heated by a pressure plate which is formed of a plurality of through-holes and a plurality of through-holes are spaced at regular intervals and rotated by a cushioning material made of laminated short fibers. The present invention relates to a dry oven for producing a polyester high elastic cushion material, in which a laminate is cooled to maintain a pressurized structure and shape.

In general, cushion material using polyester short fibers has been used for a long time mainly for bedding such as bed mattress material, but recently, it is harmless to human body and recyclable compared to conventional cushioning materials such as urethane, sponge, chemical caltex, etc. It is characterized by environmentally friendly materials, and has attracted much attention as a substitute for them.

As a method of manufacturing a polyester cushioning material which is generally used as described above, the low melting point short fibers and the high melting point short fibers having different melting points shown in FIG. 1 are opened with a yarn like yarn using the carding means 100. The carded fiber is formed by using the carding means 200 having a predetermined thickness and width.

The web formed by the carding means 200 is spread evenly on the conveyance belt and the web is laminated several times using the web laminating means 300 to form a constant thickness to form a web laminate.

The web laminated material is pressed at the same time by heating and pressing the heating / compressing means 400 while transferring the web laminated material formed by being laminated by the web laminating means 300 to a predetermined height with a transfer belt, and laminated to a constant thickness, for example, 300 mm. The web laminate is formed to have a thickness of 50 mm to produce a general cushion material having a high density.

As a device for controlling the thickness by heating the laminated web laminate at high temperature and simultaneously pressurizing as described in the manufacturing method of high-density polyester heat-sealed silk cotton of the Republic of Korea Patent No. 774075 and Patent No. 623837 Press rolls are arranged at regular intervals to heat-compress the laminated web.

The heat press method using the press roll has a problem that slip occurs due to the feed rate during the pressing and the web laminate is lumped in one direction by the rotation of the press roll, or a pressurized portion is easily restored to its original state.

As another method, a device for manufacturing a cushioning material for a multilayer dog face and a mattress of Korean Patent Registration No. 153294 has been proposed. The apparatus for manufacturing a cushion material for a multilayer dog face and mattress is configured to pressurize the coated iron plate having a ventilation hole formed therein.

Here, the coated iron sheet is made of a single like conveyor belt, so that it is difficult to transfer heat to the stack. Therefore, only the surface of the stack is heated, and heat is not transferred to the center side.

In addition, there is a problem in that the surface of the laminate is damaged and deformed when the surface of the laminate, which is heated and pressurized, adheres to the surface of the coated iron sheet, and the surface of the laminate is broken and deformed when the laminate of the coated iron sheet and the heated pressurized laminate is deteriorated.

Korea Patent Registration No. 774075. Republic of Korea Patent No. 623837. Korea Patent Registration No. 153294.

The present invention has been made in view of the above-mentioned conventional problems, and an object of the present invention is that the short fiber structure is not horizontal, but is laminated in the production of high elastic polyester cushioning material having high elasticity such as airlaid and random method and excellent resilience. In order to make the laminate having a predetermined thickness, press plates having a plurality of through holes are installed at regular intervals, and a high temperature heat, which is heated by the gap between the press plates and the press plates, and the through holes is transferred to the center of the stack to increase the pressurization efficiency. In addition, since the pressure plate is rotated at regular intervals and rotated, the pressure plate is easily rotated, such as a laminate being pressed at the same time as pressing, and the pressure plate is formed in the form of a plate, and the laminate is formed by a cooling device at the rear end. Tissue is cooled in pressurized state to retain shape without restoration The elastic force is increased, and the pressure plate and the laminate are cooled to facilitate separation, thereby providing a dry oven for producing a polyester high-elastic cushion material that can obtain a good quality cushioning material having a clean surface.

An object of the present invention is to form a space for receiving a high temperature heat therein and having a inlet and an outlet on the side; An upper pressurizing means and a lower pressurizing means installed in the housing inner space and rotating by a motor drive; It is achieved by a dry oven for producing a polyester high-elastic cushioning material, characterized in that the cooling device is installed on the outlet side of the housing to prevent the restoration by cooling the laminate in a pressurized state.

The upper pressurizing means and the lower pressurizing means are connected to the chain is made of a rectangular shape and is achieved by a dry oven for producing a polyester high-elastic cushion material, characterized in that a plurality of pressure plates formed with a plurality of holes are provided at regular intervals.

The upper pressurizing means and the lower pressurizing means are achieved by a dry oven for producing a polyester high elastic cushion material, characterized in that the mesh member is rotated by a motor drive.

The upper pressing means is a mesh member that is rotated by the motor drive, the lower pressing means is connected to the chain is made of a rectangular shape and a plurality of pressing plates formed with a plurality of through holes are formed a plurality of polyester at regular intervals It is achieved by a dry oven for producing high elastic cushioning material.

It is achieved by a dry oven for producing a polyester high-elastic cushioning material, characterized in that the mesh member surrounding all or part of the upper pressing means and the lower pressing means is further installed.

It is achieved by a dry oven for polyester high-elastic cushion material manufacturing, characterized in that the support fixing plate is formed fixedly installed at the lower portion of the lower pressing means spaced apart from the predetermined intervals.

The upper pressing means and the lower pressing means is achieved by a dry oven for producing a polyester high elastic cushion material, characterized in that to adjust the thickness of the laminate by adjusting the vertical interval by a cylinder or gear.

The interval between the upper pressurizing means and the lower pressurizing means is achieved by a dry oven for producing a polyester high-elastic cushion material, characterized in that the horizontal or the inlet side is wider and the gap is narrower toward the outlet.

A guide for guiding the stack to be fed into the housing toward the center is provided by a dry oven for producing a polyester high elastic cushion material, characterized in that the guide is installed in the inlet and the outlet or through the housing. .

The guide is achieved by a dry oven for producing a polyester high elastic cushion material, characterized in that vibrated by a vibration device.

It is achieved by a dry oven for producing a polyester high-elastic cushioning material characterized in that it is wrapped by a mesh member to the outside of the guide.

It is achieved by a dry oven for producing a polyester high-elastic cushion material characterized in that the mesh member is cooled by air via the outside of the housing.

Polyester high-elastic cushioning material characterized in that the length of the upper pressing means and the lower pressing means is installed longer than the installation length of the housing and the cooling means so that the upper pressing means and the lower pressing means pass through the housing and pass through the interior of the cooling means. By means of a manufacturing dry oven.

It is achieved by a dry oven for producing a polyester high-elastic cushion material, characterized in that the housing and the cooling device are spaced apart to form a space between the housing and the cooling device.

It is achieved by a dry oven for producing a polyester high elastic cushion material, characterized in that the compression roller is further installed in the space.

In the present invention as described above, when the thickness of the laminate made of laminated short fibers is installed, the pressure plates formed with a plurality of through holes are spaced apart at regular intervals, so that the high temperature heat that is heated by the gaps and the holes between the pressure plates and the pressure plates is transferred to the center of the laminate. Pressurization efficiency is increased, and the pressure plates are rotated at regular intervals, so that the pressure plates are easily rotated, such as a laminate pressurized at the same time, and a pressure plate is formed in a sliced plate form, and cooling at the rear end is also performed. As the tissue is cooled in a state in which the laminate is pressed by the apparatus, the restoration is not made, and thus the elastic force is increased, and the pressure plate and the laminate are cooled to facilitate separation, thereby obtaining an excellent quality cushioning material.

1 is a manufacturing process showing a general method of manufacturing a plush.
Figure 2 is an exemplary view showing a structure of a dry oven for producing a polyester high-elastic cushion material applied technology of the present invention.
Figure 3a is a perspective view showing the structure of the pressing means which is the main part of the present invention.
Figure 3b is a front view showing the structure of the pressing means which is the main part of the present invention.
Figure 4a is an installation state showing a state in which the guide is further installed when supplying the stack.
4b and 4c illustrate another embodiment of the guide.
Figure 5 is a front example showing the operating state of the upper pressing means that is the main portion of the present invention
Figure 6a is a side view showing another embodiment of the upper pressing means and the lower pressing member which is the technical subject of the present invention.
6b to 6e is an exemplary view showing another embodiment of a dry oven for producing a polyester high-elastic cushioning material applied technology of the present invention.
7 and 8 are exemplary views showing yet another embodiment of the present invention.
9 is a plan view showing another embodiment of a guide.
10 is an exemplary view showing a moving flow of heat supplied into the housing in the present invention.

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

2 is an exemplary view showing a structure of a dry oven for producing a polyester high elastic cushion material to which the technique of the present invention is applied. Accordingly, the structure of the dry oven 1 for producing a polyester high elastic cushion material according to the present invention is a heater capable of supplying high temperature heat. Means 11 are provided to form a space for receiving high temperature heat from the heater means 11 therein, and the upper and lower portions of the inner space of the housing 10 having the inlet and the outlet on the side are not shown. The upper pressurizing means 20 and the lower portion of the chain 12 rotated by a motor and the pressure plate 13 connected to the chain 12 and formed in a rectangular shape and provided with a plurality of through holes are provided at regular intervals. Pressing means 30 is installed.

On the other hand, it is installed on the outlet side of the housing 10 is a structure consisting of a cooling device 40 for cooling the laminate in a compressed state so that restoration is not made. In this case, the length of the upper pressurizing means 20 and the lower pressurizing means 30 is such that the upper pressurizing means 20 and the lower pressurizing means 30 pass through the housing 10 and pass through the inside of the cooling means 40. It is preferable to be installed longer than the installation length of the 10 and the cooling means 40.

The reason for this is to maintain the compressed state by allowing the tissue to be cooled in the compressed state because the heat-compressed laminate can be restored when the temperature and the compressive force are heated while being discharged out of the housing 10.

The upper pressurizing means 20 or the lower pressurizing means 30 is an interval between the upper pressurizing means 20 and the lower pressurizing means 30 using a conventional cylinder or gear as shown in the accompanying drawings. And position can be adjusted to control the thickness of the laminate.

The method and shape of the gap adjusting method of the upper pressing means 20 and the lower pressing means 30 is used to adjust the horizontal or inlet side so that the interval is wider and the gap is narrower toward the outlet.

As shown in FIG. 4A, a guide 50 that pushes and guides the stack supplied into the housing 10 toward the center may be further installed at the inlet side and the outlet side front end. The reason why the guide 50 is installed at the inlet end is to prevent the density of the side surface as the short fibers formed and formed by the carding means spread out into the empty space on the side surface.

On the other hand, the guide 50 installed at the tip of the inlet side and the outlet side of the housing 10 may be formed integrally as shown in Figure 4b attached to the housing 10 to be installed through. In addition, as shown in Figure 4c is a guide 50 installed on the tip of the inlet side and the outlet side of the housing 10, that is, in the structure of FIG. The sides of the stack can be pressed and aligned. The vibration device uses a cam drive that is generally used, and the configuration and operation of the vibration device will be omitted.

As shown in FIG. 9, it may be configured to be wrapped by the mesh member 51 to the outside of the guide 50. The mesh member 51 may be installed and used as a fixed type, but it is preferable to change the structure so that the mesh member 51 can be moved by the rotating roller 52. The mesh member 51 is to prevent the laminate 50 consisting of short fibers from being melted by heating the guide 50 by the heat of the housing 10.

Meanwhile, as shown in FIG. 6A, the upper pressurizing means 20 and the lower pressurizing means 30 may be installed by using a mesh net 60 to prevent a slim between the stack and the pressing plate 13. It may be. At this time, the mesh net 60 is connected to the pressing plate 13, it is preferable to install so as to surround the entire upper pressure means 20 and the lower pressure means (30).

In addition, as shown in Figure 6b the upper pressing means 20 is a mesh member (60a) is rotated by a motor drive, the lower pressing means 30 is connected to the chain 12 and made of a rectangular shape It is possible to install and use a plurality of pressure plates 13 having a plurality of through holes at regular intervals.

As shown in FIG. 6C, the mesh member 60a may be moved out of the housing 10 and then changed into a structure such that the mesh member 60a is cooled by air. have.

Meanwhile, as shown in FIG. 6D, both the upper pressurizing means 20 and the lower pressurizing means 30 may be used by replacing the mesh member 60a, and as shown in FIG. 6E, the upper pressurizing means ( The structure of 20) is used to support the pressing force when pressing the laminate by further installing a support fixing plate 13a fixedly installed with a plurality of through holes.

7 and 8 are views illustrating another embodiment of the present invention. Preferably, the housing and the cooling device are configured to be spaced apart. More preferably, the compression roller 70 is disposed between the spaced housing and the cooling device. You can also install and use it.

The use state of the present invention having the structure as described above is first supplying a stack of laminated short fibers into the housing 10. In this case, as shown in FIG. 4A, the guide 50 is installed to guide the stack supplied into the housing 10, so that the density of the side surface becomes weaker when stacking short fibers formed by the carding means. To prevent this, it plays a role of gathering to the center part.

Meanwhile, as shown in FIG. 4B, the guide 50 installed at the tip of the inlet side and the outlet side of the housing 10 may be integrally formed and installed to penetrate the housing 10. As shown in FIG. 4C, a vibration device is connected to the guide 50 installed at the tip of the inlet and outlet of the housing 10 to vibrate the guide 50 to press and align the side of the stack. You can.

When the laminate is supplied into the housing 10, a high temperature heat is supplied to the inside of the housing 10 by the heater means 11 so that the laminate is heated by the high temperature heat, and thus the heated laminate is muddy. It softens softly and becomes the state which is easy to pressurize.

In addition, as a method of supplying high temperature heat into the housing 10, as illustrated in FIG. 10, hot air supplied by a burner may be moved through a fan to be supplied into the housing. The use of the fan has the advantage of forcibly circulating the heat inside the housing, where the heat flow direction of the air temperature can be moved from bottom to top or top to bottom.

The heated laminate is supplied into the housing 10 and is supplied between the upper pressing means 20 and the lower pressing means 30, which are spaced apart from each other, to be compressed. The upper pressurizing means 20 and the lower pressurizing means 30 can be moved up and down by a normal cylinder or gear, etc., so that the position can be adjusted.

Since the position adjustment of the upper pressurizing means 20 and the lower pressurizing means 30 uses a conventional method, description of the position adjusting method will be omitted. Meanwhile, the method of adjusting the gap between the upper pressing means 20 and the lower pressing means 30 and the adjusting form, that is, the pressing method of the laminate are as shown in FIGS. 2A and 5A, and the horizontal or inlet side has a wider gap and toward the outlet side. It can be compressed by adjusting to form a narrow gap.

The laminate compaction is made by the pressure plate 13 as shown in Figure 3a attached to the pressure plate 13 is connected to the chain 12 is rotated by the driving force of the motor not shown in the form of a rectangular laminated Pressurization can be performed easily, moving water.

The pressure plate 13 has a plurality of through-holes are formed so that the hot heat is transmitted to the laminate through the through-holes during compression, and the hot heat is also transmitted at a spaced interval between the pressure plate 13 and the pressure plate 13. Heat the stack.

The high temperature heat movement supplied to the inside of the housing 10 is blown to a fan when heat is supplied by the burner as shown in FIG. 10. Pressurized when delivered and the laminate is softened by heat.

As shown in FIG. 6A, the upper pressurizing means 20 and the lower pressurizing means 30 may further include a mesh net 60 to prevent slimming. The mesh net 60 is for easily moving the stack simultaneously moving in the horizontal direction while being pressed in the vertical direction by the pressure plate 13 connected to the chain (12). It also has the effect of keeping the yarn out of the way.

Meanwhile, the stack having passed through the housing 10 is cooled by the cooling device 40 while being moved in a pressurized state. The cooling device 40 may be restored when the heated and compressed laminate is discharged out of the housing 10 and the heating temperature and the pressing force are terminated, so that the tissue is quenched in the compressed state to maintain the compressed state.

In addition, as shown in Figure 6b the upper pressing means 20 is a mesh member (60a) is rotated by a motor drive, the lower pressing means 30 is connected to the chain 12 and made of a rectangular shape It is possible to install and use a plurality of pressure plates 13 having a plurality of through holes at regular intervals.

As shown in FIG. 6C, the mesh member 60a may be moved out of the housing 10 and then changed into a structure such that the mesh member 60a is cooled by air. have.

Meanwhile, as shown in FIG. 6D, both the upper pressurizing means 20 and the lower pressurizing means 30 may be used by replacing the mesh member 60a, and as shown in FIG. 6E, the upper pressurizing means ( The structure of 20) is used to support the pressing force when pressing the laminate by further installing a support fixing plate 13a fixedly installed with a plurality of through holes.

7 and 8 are views showing still another embodiment of the present invention. The housing 10 and the cooling device 40 are preferably spaced apart from each other, and more preferably, the spaced apart housing 10 is provided. And a compression roller 70 may be installed between the cooling device 40 and the cooling device 40.

The reason why the housing 10 and the cooling device 40 are spaced apart is that when the high-temperature housing 10 and the low-temperature cooling device 40 are attached to each other, the high and low temperatures are moved to each other, and thus the effect and characteristics of the device. It is because it can lower.

Meanwhile, as shown in FIG. 8, a compression roller 70 is installed between the spaced housing 10 and the cooling device 40 to release high-temperature heat into the atmosphere and at the same time the cooling device ( In order to prevent the deformation of the laminate during movement of the laminate compressed by 40), the installation of the pressing roller 70 is used and the pressing roller 70 is the installation length of the upper pressing means 20 and the lower pressing means 30 is It is sufficient if the length of the housing 10 is the same as the length of the outlet side or extends to the extent that it does not interfere with the pressing roller 70.

As shown in FIG. 9, it may be configured to be wrapped by the mesh member 51 to the outside of the guide 50. The mesh member 51 may be installed and used as a fixed type, but it is preferable to change the structure so that the mesh member 51 can be moved by the rotating roller 52. The mesh member 51 is to prevent the laminate 50 consisting of short fibers from being melted by heating the guide 50 by the heat of the housing 10.

In the present invention as described above, when the thickness of the laminate made of laminated short fibers is installed by a plurality of pressure plates 13 formed with a plurality of holes spaced apart at regular intervals, the gap between the pressure plate 13 and the pressure plate 13 is heated by the through holes. High temperature heat is transmitted to the center of the stack to increase the pressurization efficiency, and since the press plate 13 is rotated at regular intervals and rotates, it is easily rotated like the laminate pressurized at the same time. As the tissue is cooled in the state in which the laminate is pressed by the cooling device 40, the restoration is not performed, and thus the elastic force is increased, and the pressure plate and the laminate are cooled to facilitate separation, thereby obtaining a cushion material having excellent quality.

1: dry oven 10: housing
11 heater means 12 chain
13: pressure plate 13a: base fixing plate
20: upper pressing means 30: lower pressing means
40: cooling device 50: guide
51: mesh member 52: roller
60a: mesh member 70: crimping roller

Claims (15)

A housing having a space for receiving high temperature heat therein and having an inlet and an outlet at its side;
An upper pressurizing means and a lower pressurizing means installed in the housing inner space and rotating by a motor drive;
Drying oven for polyester high-elastic cushion material, characterized in that made of a cooling device installed on the outlet side of the housing to prevent the restoration by cooling the laminate in a pressurized state. The method of claim 1,
The upper pressurizing means and the lower pressurizing means are connected to the chain and made of a rectangular shape, the drying oven for producing a polyester high-elastic cushion material, characterized in that a plurality of pressure plates formed with a plurality of holes are installed at regular intervals. The method of claim 1,
The upper pressing means is a mesh member that is rotated by the motor drive, the lower pressing means is connected to the chain is made of a rectangular shape and a plurality of pressing plates formed with a plurality of through holes are formed a plurality of polyester at regular intervals Dry oven for producing high-elastic cushioning materials. The method of claim 1,
The upper pressurizing means and the lower pressurizing means are dry oven for producing a polyester high elastic cushion material, characterized in that the mesh member is rotated by the motor drive. The method of claim 1,
The upper pressing means and the lower pressing means is a dry oven for producing a polyester high elastic cushion material, characterized in that to adjust the thickness of the laminate by adjusting the vertical interval by a cylinder or gear. The method of claim 1,
Drying oven for producing a polyester high-elastic cushioning material, characterized in that the interval between the upper pressing means and the lower pressing means is horizontal or inlet side is wider and the gap is narrower toward the outlet. The method of claim 1,
Polyester high-elastic cushioning material characterized in that the length of the upper pressing means and the lower pressing means is installed longer than the installation length of the housing and the cooling means so that the upper pressing means and the lower pressing means pass through the housing and pass through the interior of the cooling means. Dry oven for manufacturing. 4. The method according to any one of claims 1 to 3,
Drying oven for producing a polyester high-elastic cushioning material, characterized in that the mesh member surrounding the whole or part of the upper pressing means and the lower pressing means is further installed. The method of claim 1,
Drying oven for producing a polyester high-elastic cushioning material, characterized in that the guide for guiding the stack to be supplied to the inside of the housing to push toward the center is provided in the inlet and outlet or the guide is installed through the housing. The method of claim 9,
Drying oven for producing a polyester high elastic cushion material, characterized in that the guide is vibrated by a vibration device. The method according to any one of claims 3 and 4,
Drying oven for producing a polyester high-elastic cushioning material, characterized in that for cooling the air through the mesh member to the outside of the housing. The method of claim 1,
Drying oven for producing a polyester high-elastic cushion material, characterized in that the housing and the cooling device spaced apart to form a space between the housing and the cooling device. The method of claim 1,
Dry oven for polyester high-elastic cushioning material, characterized in that the compression roller is further installed in the space. The method according to any one of claims 9 and 10,
Drying oven for producing a polyester high elastic cushion material, characterized in that the guide is wrapped by a mesh member. 5. The method of claim 4,
Drying oven for polyester high-elastic cushioning material, characterized in that the support fixing plate is formed fixedly installed in the lower portion of the lower pressing means spaced apart by a predetermined interval.

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