KR101461266B1 - Auxiliary coextuding apparatus for window profile and profile manufacturing apparatus having the same - Google Patents

Abstract

A mail extruder (10) melts a resin material to form a profile (P), presses the melt to die (30), forms a surface skin layer (S) on the profile A secondary extruder (100) for pressurizing and feeding a resin composition for co-extrusion for pressure to one side of the die, the auxiliary extruder including a connector (110) for vertically changing a feeding direction of the resin composition for coextrusion, Curved portions 113 and 114 are formed between the inlet 111 and the outlet 112 for smoothly changing the feeding direction of the resin composition. The auxiliary extruder for producing window profile co-extrusion of the present invention has an effect such that the flow path is improved to prevent the internal resin composition from being carbonized or excessive energy for transferring the resin composition is consumed, and the reality is added to the pattern of the window profile.

Description

FIELD OF THE INVENTION [0001] The present invention relates to a coextruder for coextrusion of a window profile and a profile manufacturing apparatus including the coextruder,

The present invention relates to a manufacturing facility for producing a window profile having a texture of natural wood by utilizing a coextrusion technique, and more particularly, to a method of manufacturing a window profile by extruding a component to which a wood powder is added onto a surface of a profile, The present invention relates to a shape of a secondary extruder for biaxial extrusion as an apparatus for manufacturing a window profile that realizes a textured pattern of natural wood.

As shown in FIG. 1, the extrusion process for producing a profile of a window according to the prior art is performed by using a hopper 2 of an extruder 1 to form a pellet made of a thermoplastic resin or a compound Is heated by a heater in a heating cylinder in the extruder 1 to be melted in a gel state and simultaneously is conveyed by the rotation of the screw and is extruded into the die 3 at the previous stage. Then, the molten resin is extruded through the die 3 in a state of having a predetermined shape, and then passes through the calibrator 4 and the cooling device 5.

The calibrator 4 is a facility that allows the profile P passing through the die 3 to be molded into a product of the correct dimensions and intended shape while maintaining the shape of the outer surface. Therefore, by allowing the calibrator 4 to be immediately adjacent to immediately after passing through the die, it is preferable that the profile passed through the die is allowed to enter the calibrator immediately without deforming the shape. After passing through the cooling device 5, the product passed through the calibrator 4 is cooled and then pulled by a constant force through the drawer 6. Thereafter, the product is cut into a predetermined size while passing through the cutting device Window profile products are completed in the first place.

In order to have a variety of textures and patterns on the top or side exposed to the outside during the construction of the window profile, a decorative film (sheet paper) of a synthetic resin material is attached so as to have a wood texture rather than a synthetic resin texture.

However, in order to attach a separate film or sheet to the extruded profile of the window, it is necessary to separately move to the place where the profile wrapping facility is installed, and to separately wrap the extruded profile on the wrapping device. And it is difficult to repair it when boiling occurs when it is wrapped, transported, processed, or constructed, and since the adhesive is used for lapping, the user environment is disadvantageous.

In order to overcome this, a double extrusion (coextrusion) method was used to extrude a double profile of a window profile. The double extrusion is a method in which a PVC or other raw material is extruded and attached to one side of a profile by using a secondary extruder in a state where the profile is extruded to have a constant shape by using an extruder as described above.

In this case, however, the appearance of the surface of the PVC profile was not natural, and the surface of the PVC profile was also discolored to deteriorate the appearance.

An embossing roll (not shown) is arranged between the die 3 and the calibrator 4 to improve the reality on the surface of the profile so as to form a pattern of the surface of the embossing roll on the surface of the profile extruded from the die . However, as described above, since the calibrator 4 must be positioned immediately adjacent to immediately after passing through the die, the diameter of the embossing rolls disposed therebetween was limited. The length of the circumference of the embroidery roll is also limited because the size of the diameter is limited, and consequently, the repetition period of the pattern repeatedly formed on the surface of the profile is shortened and the reality is deteriorated.

The present invention provides an apparatus for producing a profile of a channel of a secondary extruder for forming a skin layer of a profile surface of a profile manufacturing facility for producing a window profile that realizes a sense of natural wood texture and gives a luxurious feeling, .

The present invention is characterized in that the mail extruder 10 melts a resin material for forming a profile P and pressurizes and feeds the resin material to the die 30 to form a resin composition for coextrusion for forming a surface skin layer S on the profile, The auxiliary extruder includes a connector 110 vertically changing the feeding direction of the resin composition for coextrusion, and the inlet 111 and the outlet 112 of the connector are connected to each other, Wherein curved portions (113, 114) for smoothly changing the feeding direction of the resin composition are formed between the extruded extruders.

The present invention also provides a method for producing a surface skin layer (S), which comprises a main extruder (10) for pressurizing and feeding a molten resin material, a die (30) for discharging the resin material into a profile of a predetermined shape, And a secondary extruder (100) for pressurizing and feeding the resin composition to one side of the die, wherein the die (30) is provided with a resin composition for co-extrusion introduced from the auxiliary extruder, Wherein the pressurizing space is provided with a pressurizing space for applying pressure, and the pressurizing space is provided with a flow guide for dividing the flow of the resin composition for co-extrusion.

The flow guide of the pressurized space may be arranged along a conveying direction of the resin composition for co-extrusion. The auxiliary extruder may include a connector 110 vertically changing a conveying direction of the resin composition for co-extrusion, Between the inlet 111 and the outlet 112, curved portions 113 and 114 for changing the feeding direction of the resin composition may be formed.

Further comprising: a calibrator (70) for keeping the shape of the outer surface of the die discharged from the die, and a cooling device (90) for cooling the profile passed through the calibrator, wherein the resin composition for co- The present invention provides a profile manufacturing apparatus.

According to the window profile of the present invention, the skin layer is integrally formed on one side of the profile by co-extrusion to show a fine texture of the natural wood texture and an advantageous effect of giving a luxurious feeling is produced. Further, the flow path of the secondary extruder is improved, so that the internal resin composition is carbonized, excessive energy consumption for transferring the resin composition is prevented, and the reality of the pattern of the window profile skin layer is increased.

1 is a schematic view of a facility for producing a window profile according to the prior art,
2 is a schematic view of an apparatus for producing a window profile according to an embodiment of the present invention,
3 is a cross-sectional view of a profile produced by coextrusion according to the present invention,
Figure 4 is a section of a profile produced by extruding into a production facility according to the present invention,
5 is a perspective view of an embossing roll according to the present invention,
6 is a cross-sectional view and a surface enlarged view of the embossing roll of the present invention,
7 is a cross-sectional view and a surface enlarged view of the embossing roll according to the prior art,
FIG. 8 is a co-extrusion apparatus for producing a window profile according to the present invention, which is viewed from a direction different from that of FIG. 2,
Fig. 9 is a sectional view of the die and the embossing roll in Fig. 8,
10 is a perspective view of a disk of a cooling device among co-extrusion facilities according to the present invention,
11 is a cross-sectional view of the auxiliary extruder connector of the coextrusion equipment according to the present invention,
Figure 12 is a cross-sectional view of a connector according to the prior art,
13 is a view in which patterns are formed in a profile in a co-extrusion facility,
FIG. 14 is a view showing profile patterns formed in the coextrusion equipment according to the present invention,
Figure 15 is a view of an actual product produced using coextrusion according to the present invention.

Hereinafter, an embodiment of the present invention will be described with reference to the accompanying drawings.

FIG. 2 is a schematic view of a co-extrusion facility for producing a window profile according to an embodiment of the present invention. 2, a pellet of a thermoplastic resin material such as polystyrene (PS), polyethylene (PE), polypropylene (PS), polyvinyl chloride (PVC) When the material is charged, it is heated by a heater serving as a heating means in the main extruder 10 to be dissolved in a gel state and transported forward by the rotation of the screw. Thereafter, the profile P is extruded in a state of being shaped through the die 30 placed in front of it, and then passed through the calibrators 70 and 80 and the cooling device 90, and the pulling machine 99 and the cutter It is similar to the conventional technique, so a detailed explanation should be avoided.

By allowing the calibrator 70 to be immediately adjacent to immediately after passing through the die, it is preferable that the profile passed through the die is allowed to enter the calibrator immediately without deforming the shape. The profile P is preferably subjected to surface cooling by the surface cooling device 60 before entering the calibrator. If it is inserted directly into the calibrator without cooling the surface of the profile, there may be a problem that the embossed pattern expressed on the profile surface is damaged due to the surface friction between the profile forming resin and the inner metal surface in the calibrator. At this time, it is preferable to use air as the cooling medium. That is, in the surface cooling apparatus, the air is uniformly injected toward the profile toward the molding site to rapidly cool the profile surface.

The coextrusion equipment of the present invention is further provided with a secondary extruder (100) for coextrusion. 3 shows a die 30 and a secondary extruder 100 according to the present invention. The die 30 comprises a main extrusion die 30a and a co-extrusion die 30b. The main extrusion die 30a serves to extrude the gelled resin into the hopper 20 in order to form a profile. The co-extruding die 30b is attached to the front of the main extrusion die 30a and passes through a coextrusion skin layer (see S in Fig. 4) on one side of the profile passed through the main extrusion die 30a, For this purpose, the resin composition for co-extrusion fed from the auxiliary extruder 100 is injected into the upper side of the co-extrusion die 30b. That is, the resin composition for co-extrusion discharged from the auxiliary extruder 100 is attached to the side surface of the profile passed through the main extrusion die 30a to form the skin layer S, .

Figure 4 shows a section of a profile produced by coextrusion according to the invention. It can be seen that the skin layer S is integrally formed by co-extrusion on the surface of the ordinary window profile P. Although the skin layer is formed on the upper surface and both side surfaces of the profile in the drawing, the skin layer formation is not necessarily limited to this shape, and may be formed on a part or the entire surface of the upper surface of the profile, if necessary.

When the skin layer is formed by coextrusion in this way, various colors can be realized by making various materials constituting the skin layer, and a post process such as attaching the sheet after the profile is produced by integrating the profile and other materials through extrusion Not only the cost is reduced but also the workability of the product is improved and the adhesive is not used, so that it can be an eco-friendly method and has an advantageous effect against surface scratching.

 In the present invention, the resin composition for coextrusion comprising the skin layer (S) contains wood powder to enhance the texture of natural wood to enhance the reality.

The resin composition for co-extrusion comprises a first raw material forming a base color, a second raw material forming a mid tone color, and a third raw material forming a high tone color.

The first raw material of the present invention is a base raw material and is characterized by including wood powder so that the skin layer of the profile represents the texture of natural wood. The specific composition of the first raw material is approximately 70% of PVC raw material, 10-15% of talc, 15-20% of wood powder, a small amount of inorganic pigment excellent in weatherability, and a small amount of weathering additive.

The second raw material is a raw material for forming midtones and is made of highly polymerized PVC having a higher melting point than the first raw material (base raw material), a resin such as ASA, PMMA, or PE, and a medium- Pigments and other lubricants.

The third raw material is a high tone color pigment, which is composed of a high polymerization degree PVC having a higher melting point than the first raw material (base raw material), a high-tone inorganic pigment having excellent weather resistance, such as ASA, PMMA, PE, And other lubricants.

The first raw material, the second raw material, the third raw material, etc. of the resin composition for co-extrusion according to the present invention are mixed with each other to form a single color, Each of the second and third raw materials is represented by midtones and high tones so that respective colors can be distinguished from each other, thereby realizing a natural color superior in reality.

The melting point of the first raw material is about 160 to 165 DEG C and the melting point of the second raw material is about 175 to 185 DEG C so that the color of each raw material of the resin composition can be distinguished. The melting point should be about 175 ° C to 185 ° C.

The auxiliary extruder 100 heats the resin composition for co-extrusion and presses the co-extruded resin composition by the co-extrusion die 30b. If the melting point of the resin composition is the same, The color of each color is not distinguished and appears as a mixed color. To prevent this, each melting point is made different. That is, if the interior of the auxiliary extruder is heated to about 160 ° C to 180 ° C, the base material having the lowest melting point first melts and gels. However, the second raw material and the third raw material are discharged from the auxiliary extruder into the co- In this process, a pattern is formed in which the midtones of the second raw material and the third raw material of the high tone flow naturally between the base raw materials.

In addition, the resin composition for co-extrusion may further include functional raw materials such as an anionic powder or a fragrance to release environmentally friendly anions into the room to realize a forest environment in an indoor environment provided with a window profile, .

FIG. 5 is a perspective view of the embossing roll 50 according to the present invention, and FIGS. 6 (a) and 6 (b) are a cross-sectional view and an enlarged view of the embossing roll 50, respectively.

The embossing roll 50 according to the present invention has a diameter larger than that of the conventional embossing roll so that the surface of the embossing roll 50 has two single corners so that the continuity of the pattern is excellent, 51, and a concave-convex pattern is formed on the surface thereof. 6 (a), the surface of the embossing roll 50 is formed with two steps in the shape of the concavities and convexities. That is, the first protrusions 53 formed relatively large and the second protrusions 55 formed relatively small on the first protrusions 53 are provided. The first protrusions 53 and the second protrusions 55 are formed in an irregular shape instead of a predetermined regular shape (a cross section of a conventional embossing roll shown in FIGS. 7A and 7B and a surface shape The depth D of the first protrusion 53 is formed to be larger than the depth d of the protrusion formed on the conventional embossing roll so that the actual feeling of the pattern More.

The embossing roll 50 of the present invention not only enlarges the projections formed on the surface, but also has a large diameter RD. When the diameter of the embossing roll is increased, the circumference of the embossing roll surface is also enlarged. As a result, the length of the embossing pattern formed on the profile becomes longer while the embossing roll is rotated one time. .

However, the diameter of the embossing roll 50 disposed between the die 30 and the calibrator 70 is limited. This is because the interval between the die 30 and the calibrator 70 is limited as described above. For this purpose, the present invention has been devised as shown in FIGS. 8 to 9.

  FIG. 8 shows a part of the co-extrusion equipment for producing a window profile according to the present invention, which is viewed from a direction different from that of FIG. 2 for explanation, and the auxiliary extruder is omitted. 9 is a sectional view of the die 30 and the embossing roll 50 in Fig.

8 to 9, the gap G between the die 30 and the calibrator 70 is set such that the lower gap G1 is relatively small and the gap G2 above is relatively large for mounting the embroidery roll 50 to be. The die 30 is rounded so that the curved surface portion 35 is formed on the side on which the embossing roll 50 is mounted so that the embossing roll 50 can be mounted Provide space. That is, a curved surface portion 53 corresponding to the shape of the outer circumferential surface of the embossing roll 50 is formed on the exit side surface of the die 30 of the present invention on which the profile P is discharged. Therefore, even when the diameter RD of the embossing roll 50 is larger than the conventional one, the embossing roll 50 can be mounted without an excessive increase in the gap G between the die and the calibrator. Although a curved surface portion of approximately semicircular shape is shown in the drawing, a curved surface portion having a proper shape such as an arc shape having a central angle of 90 degrees in view of the shape of the embossing roll may be formed.

8, the calibrators 70 and 80 may be composed of a dry calibrator 70 and a water calibrator 80, or may be of a dry type or a submerged type. In the cooling device 90, a plurality of disks 93 are arranged inside the water tank in the profile advancing direction. In order to cool the passing profile but maintain the shape, discs having a hollow center are arranged side by side.

Fig. 10 shows one of the disks 93 of the cooling device 90 according to the present invention. The disk 93 has a hollow centered at the center thereof through which the profile P passes, and a roller 95 is disposed on the upper side. The rotary shaft of the roller 95 is fixed at an appropriate position above the disc 93 and rotates while contacting the upper side of the passing profile. On the upper side of the profile P, a skin layer S formed by coextrusion is formed, and an emboss pattern is formed by the embossing roll 50. [

Since the disk of the conventional cooling device does not have the same configuration as the roller 95 of the present invention, the profile passes through the upper surface of the profile and the hollow surface of the disk to each other, and as a result, the embossed pattern formed on the profile side It was crushed and damaged.

The present invention provides a roller that rotates at the position of the disc in contact with the profile side surface, thereby changing the surface contact to a line contact and thus preventing the embossed pattern formed on the profile side from being damaged.

3, the skin layer is co-extruded on the upper side of the profile by using the auxiliary extruder 100. As shown in FIG. The auxiliary extruder that co-extruded PVC or other raw materials was modified in the existing profile manufacturing facility to improve the auxiliary extruder flow path.

The auxiliary extruder 100 of the present invention forms a skin layer S on one side of the profile P by applying a predetermined pressure to the resin composition for co-extrusion onto the co-extrusion die 30b. As shown in the figure, the auxiliary extruder 100 conveys the resin composition for co-extrusion in the substantially horizontal direction, and after the direction of the feeding of the resin composition for co-extrusion is bent by about 90 degrees by the connector 110, And flows into the upper side of the co-extrusion die 30b. The portion of the auxiliary extruder for vertically changing the feeding direction of the resin composition for co-extrusion is a connector 110, and Fig. 11 is a sectional view of the connector 110 according to the present invention. The connector 110 is provided with an inlet 111 through which the resin composition for coextrusion is introduced in the horizontal direction and an outlet 112 through which the resin is discharged in a vertical direction after the direction is changed, and curved portions 113 and 114 . The inner diameter of the passage is reduced as it goes from the inlet 111 to the outlet 112 through the curved portion so that the feeding speed of the resin composition increases and the feeding pressure also increases. By the curved portions 113 and 114, the feeding direction of the resin composition for co-extrusion can be naturally changed from horizontal to vertical.

12 is a cross-sectional view of the connector according to the prior art, in which the direction of the transfer of the internal transfer material is changed so as to be abruptly changed from horizontal to perpendicular. As a result, the transported material, which has been traveling in the horizontal direction, strikes directly against the vertical wall, and there is a problem that the transported material is carbonized or the raw material to be transported is piled up and the transporting pressure is increased. The present invention solves these problems by smoothly curving the transfer direction changing portion of the connector.

FIG. 13 is a view showing a pattern formed in a profile in a co-extrusion facility, and FIG. 14 is a view showing profile patterns formed in a co-extrusion facility according to the present invention.

The resin composition for co-extrusion is discharged from the auxiliary extruder 100, flows into the die 30 from the upper side of the die 30, and then flows into the coextrusion pressurizing space 38 inside the die. Thereafter, the resin composition for co-extrusion is applied to the upper surface or the upper surface or the side surface of the profile P passing through the die and running in the transverse direction to form the skin layer S of the profile. At this time, the second raw material or the third raw material of the resin composition naturally forms a pattern.

13, when the coextrusion pressurizing space 38 in the die 30 is formed as a single space, the resin composition applied on the surface of the profile P in the inner compartment 38 has a central portion So that the pattern S1 of the whirlpool pattern is generated intensively in the central portion of the upper surface of the profile, resulting in a problem that the pattern of the pattern becomes artificial.

In order to solve this problem, in the present invention, the coextrusion pressurizing space 38 is formed into a plurality of compartments as shown in Fig. To this end, a flow guide 39 is disposed in the coextrusion pressurizing space 38 for guiding the transferred resin composition into a separate space. The resin composition which has been pressurized by the auxiliary extruder 100 and then introduced into the coextrusion pressurizing space 38 which is the inner space of the die is guided and moved to the separate space by the flow path guide 39, Is prevented. Therefore, the pattern S2 formed on the skin layer S of the profile is uniformly formed on the upper surface of the profile, and the natural pattern of the stripe shape is evenly formed.

The pattern S2 formed on the skin layer S of the profile P produced according to the co-extrusion equipment of the present invention is formed by the second raw material and the third raw material of the resin composition, (39), and the naturalness of the pattern is expressed in the irregular pattern, and the reality is enhanced.

Claims (6)

delete A die (30) for discharging the resin raw material into a profile of a predetermined shape; and a resin composition for coextrusion for forming a surface skin layer (S) And an auxiliary extruder (100) for pushing and conveying the one side of the auxiliary profile extruder
The die 30 is provided with a pressurizing space 38 for accommodating the resin composition for co-extrusion introduced from the auxiliary extruder and applying pressure to the surface of the profile,
The pressurizing space (38) includes a flow guide (39) for dividing the flow of the resin composition for co-extrusion,
The auxiliary extruder 100 includes a connector 110 vertically changing the feeding direction of the resin composition for co-extrusion. A curve between the inlet 111 and the outlet 112 of the connector changes the feeding direction of the resin composition, Portions 113 and 114 are formed,
Wherein the inner diameter of the passage is reduced as it goes from the inlet (111) to the outlet (112) through the curved portions (113, 114), thereby increasing the feeding speed and the feeding pressure of the resin composition.
3. The method of claim 2,
And the flow path guide of the pressurized space is arranged along the conveying direction of the resin composition for co-extrusion. delete 3. The method of claim 2,
Further comprising: a calibrator (70) for maintaining the shape of the outer surface of the die discharged from the die; and a cooling device (90) for cooling the profile passed through the calibrator.
6. The method of claim 5,
Wherein the resin composition for co-extrusion comprises wood powder.

Images