TW201636184A - Non-crosslink masking tape cooling device - Google Patents

Abstract

The present invention provides a non-crosslink masking tape cooling device, which can maintain the production speed of products as before while the size growth of the water tank increases, and does not burden the non-crosslink masking tape to reliably cool the non-crosslink masking tape in a short period of time. The non-crosslink masking tape cooling device (100) includes an areolar cylindrical roller (105). The areolar cylindrical roller (105) is set to be immersed in the coolant (103) of the water tank (102) and free to rotate in cooperation with the speed of conveying the non-crosslink masking tape (101). Accordingly, the non-crosslink masking tape (101) is rolled at the outer periphery of the cylindrical roller while as being conveyed, and immersed in the coolant (103) to be continuously cooled.

Description

Uncrosslinked tape cooling device

The present invention relates to an uncrosslinked tape cooling device for continuously cooling before providing an uncrosslinked adhesive tape obtained through a kneading process and a forming process to a processing process.

When the uncrosslinked rubber obtained by the kneading process is supplied to an extruder or the like to be supplied to the processing process, it is necessary to form the uncrosslinked rubber into a small spherical shape, a tape shape, or the like by a forming process in advance. The shape of the supply such as the machine. In particular, when the uncrosslinked adhesive tape obtained by molding the uncrosslinked adhesive into a tape shape is supplied to an extruder or the like, in order to maintain the quality of the product, it is preferred to maintain the cross-sectional area of the uncrosslinked adhesive tape while fixing. It is supplied to an extruder or the like.

However, since the uncrosslinked tape immediately after the molding is high in temperature and soft, and is easily deformed, when the uncrosslinked tape is supplied to the extruder or the like, when the compressive stress and the tensile stress applied to the uncrosslinked tape are excessively large, The uncrosslinked tape is deformed and cannot be supplied to an extruder or the like while maintaining the cross-sectional area of the uncrosslinked tape. Therefore, when the uncrosslinked tape is supplied to an extruder or the like, it is necessary to convey the uncrosslinked tape at a constant speed to reduce the compressive stress and tensile stress applied to the uncrosslinked tape, and it is required to be cooled rapidly and uniformly. Uncrosslinked tape to suppress deformation of the uncrosslinked tape.

As a method of cooling the uncrosslinked tape, there are known methods such as water cooling and air cooling. Although each method has its own characteristics, the method of immersing the uncrosslinked tape in water cooling of the refrigerant or the like is more efficient than other methods such as air cooling. high. However, when the uncrosslinked tape is immersed in the refrigerant, in order to reduce the chance of contact between the uncrosslinked tape and the foreign matter mixed in the refrigerant, it is necessary to periodically clean the water tank in which the refrigerant is placed and periodically replace the refrigerant.

Prior art literature:

Patent literature

Patent Document 1: Japanese Laid-Open Patent Publication No. 2014-073589

Patent Document 2: Japanese Laid-Open Patent Publication No. 11-058497

In the past, when the uncrosslinked tape is immersed in the refrigerant, the uncrosslinked tape is conveyed by the mesh-shaped conveyor belt, and the water is placed in the water tank in which the refrigerant is placed, thereby uniformly cooling in all directions (for example, refer to the patent) Documents 1, 2), but the time during which the uncrosslinked tape is immersed in the refrigerant, that is, the cooling time of the uncrosslinked tape depends on the entire length of the water tank through which the uncrosslinked tape passes. Therefore, in order to sufficiently ensure the cooling time of the uncrosslinked tape, the growth of the water tank and the conveyor belt cannot be avoided, which requires a large equipment investment and causes a problem that the installation area of the equipment becomes large.

In addition, when the length of the water tank and the conveyor belt are prevented from increasing and the total length of the water tank is stopped to a certain extent, it is necessary to reduce the speed at which the uncrosslinked tape is conveyed, that is, the production speed of the product to ensure the cooling time of the uncrosslinked tape. . In this case, by using a plurality of rows of processes in which a plurality of uncrosslinked adhesive tapes are simultaneously cooled in parallel, it is possible to compensate for a decrease in the production speed of the product, but a complicated apparatus for simultaneously forming a plurality of uncrosslinked adhesive tapes is required. In addition, the adjustment for changing the bandwidth of the uncrosslinked tape is complicated.

Further, when the specific gravity of the uncrosslinked tape is smaller than that of the refrigerant, there is a potential problem that the uncrosslinked tape floats to the liquid surface of the refrigerant to lower the cooling efficiency, so that it is necessary to add pressure to the uncrosslinked tape. The mechanism that causes it to sink to the bottom of the refrigerant poses a risk that the cleaning becomes complicated and the uncrosslinked tape is deformed by the pressurization.

Therefore, an object of the present invention is to provide a non-crosslinked tape cooling device capable of maintaining the production speed of a product while maintaining the growth rate of the water tank while maintaining the growth rate of the water tank, and to apply the uncrosslinked tape without placing a load on the uncrosslinked tape. Reliably cooled in a short time.

The present invention relates to an uncrosslinked tape cooling device comprising a mesh-shaped cylindrical drum which is provided to be immersed in a refrigerant placed in a water tank and which is rotatable freely and which is used for conveying uncrosslinked tape. When the speed is rotated, the uncrosslinked adhesive tape is conveyed while being wound around the outer peripheral surface of the cylindrical drum, and is immersed in the refrigerant to be continuously cooled.

The cylindrical drum is preferably formed by bending a mesh-shaped metal mesh.

According to the present invention, it is possible to provide an uncrosslinked tape cooling device capable of maintaining the production speed of the product while maintaining the growth rate of the water tank while avoiding the growth of the water tank, and not burdening the uncrosslinked tape. The crosslinked tape is reliably cooled in a short time.

100‧‧‧Uncrosslinked tape cooling device

101‧‧‧Uncrosslinked tape

102‧‧‧Sink

103‧‧‧Refrigerant

104‧‧‧ outer perimeter

105‧‧‧Cylinder roller

106‧‧‧Metal plate

107‧‧‧guide roller

401‧‧‧Open roll mixer

402‧‧‧Liquid separating agent tank

403‧‧‧Loading device

404‧‧‧ Container

SW‧‧‧Short-side mesh opening

LW‧‧‧Long side mesh opening

Fig. 1 is a side view showing the uncrosslinked tape cooling device of the present invention; Fig. 2 is a front view showing the uncrosslinked tape cooling device of the present invention; and Fig. 3 is an enlarged view showing a mesh-shaped metal mesh. Fig. 4 and Fig. 4 are schematic views showing a manufacturing apparatus of an uncrosslinked adhesive tape used in the examples.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.

As shown in FIG. 1 and FIG. 2, the uncrosslinked tape cooling device 100 according to the embodiment of the present invention is used for continuous use, for example, before the uncrosslinked adhesive tape 101 obtained by the kneading process and the molding process is supplied to the processing process. A device that performs cooling.

The uncrosslinked tape cooling device 100 is provided with a mesh-shaped cylindrical drum 105 which is immersed in the refrigerant 103 placed in the water tank 102 and rotatably provided and conveys the uncrosslinked tape. When the speed of 101 is rotated, the uncrosslinked tape 101 is conveyed while being wound around the outer peripheral surface 104, and is immersed in the refrigerant 103 to be continuously cooled.

The cylindrical drum 105 has a width in which the uncrosslinked tape 101 is wound in a plurality of rows on the outer peripheral surface 104 over a plurality of turns. Thereby, the number of turns of the uncrosslinked tape 101 wound around the outer circumferential surface 104 of the cylindrical drum 105 can be adjusted to freely change the cooling time of the uncrosslinked tape 101. Therefore, even if the production speed of the product is increased, the cooling time of the uncrosslinked tape 101 can be sufficiently ensured by increasing the number of turns of the uncrosslinked tape 101 wound around the outer circumferential surface 104 of the cylindrical drum 105.

Further, as shown in Fig. 3, the cylindrical drum 105 is preferably formed by bending a mesh-shaped metal mesh 106. Thereby, the contact area of the uncrosslinked tape 101 and the cylindrical drum 105 can be reduced and the contact area of the uncrosslinked tape 101 and the refrigerant 103 can be increased, so that the uncrosslinked tape 101 can be uniformly cooled from all directions. In addition, the contact area between the uncrosslinked tape 101 and the cylindrical drum 105 can be reduced and the frictional force of the uncrosslinked tape 101 not being slid off from the cylindrical drum 105 can be maintained, so that the uncrosslinked adhesive tape 101 can be prevented from sticking to The uncrosslinked tape 101 caused by the cylindrical roller 105 is damaged and broken, and the uncrosslinked tape 101 is stably supported by the cylindrical roller 105.

Further, as the cylindrical drum 105, a plain weave, a twill weave, a punched metal, or the like may be used. However, if a mesh material is used too fine, foreign matter easily enters the mesh, which is difficult. To remove foreign matter. Further, since the outer circumferential surface 104 of the cylindrical drum 105 is a smooth surface, the uncrosslinked tape 101 is liable to slip, and thus the movement of the uncrosslinked tape 101 is unstable, which may cause deformation of the uncrosslinked tape 101.

Therefore, for example, when the uncrosslinked tape 101 having a width of about 40 mm or more and 100 mm or less and a thickness of 5 mm or more and 20 mm or less is cooled, the short side mesh opening SW is about 20 mm or more and 60 mm or less and the long side. The mesh opening LW is a mesh-shaped metal mesh or the like having a mesh opening degree LW of 50 mm or more and 150 mm or less to form a cylindrical drum 105, thereby applying an appropriate grip force to the uncrosslinked tape 101 to make the uncrosslinked tape 101 The stretching action is stable.

Referring again to FIGS. 1 and 2, the uncrosslinked tape cooling device 100 has a plurality of guide rolls 107 which are provided on the cylindrical drum 105 and are wound around the outer peripheral surface of the cylindrical drum 105 in the uncrosslinked tape 101. At 104 o'clock, the adjacent uncrosslinked tapes 101 are prevented from coming into contact with each other. Thereby, even if the uncrosslinked adhesive tape 101 is wound in a plurality of rows on the outer circumferential surface 104 of the cylindrical drum 105 over a plurality of turns, it is possible to prevent the adjacent uncrosslinked adhesive tapes 101 from sticking to each other and stopping the production.

As described above, according to the uncrosslinked tape cooling device 100, the uncrosslinked tape 101 is immersed in the refrigerant 103 by the cylindrical roller 105. Therefore, the uncrosslinked tape 101 can be sufficiently ensured without increasing the size of the water tank 102. The cooling time is not imposed on the uncrosslinked tape 101.

Further, according to the uncrosslinked tape cooling device 100, the number of turns of the uncrosslinked tape 101 wound around the outer circumferential surface 104 of the cylindrical drum 105 is increased, so that the production speed of the product can be maintained while in a short time. The uncrosslinked tape 101 is reliably cooled.

That is, the uncrosslinked tape cooling device 100 can save equipment investment and equipment installation area, and has fewer restrictions on installation places, and can contribute to shortening of manufacturing time. Further, since only one uncrosslinked tape 101 is used, a method of easily adjusting the width and thickness by cutting the cutter from the open roll kneader or the like can be used in the molding of the uncrosslinked tape 101.

Further, even if the specific gravity of the uncrosslinked tape 101 is smaller than that of the refrigerant 103, the uncrosslinked tape 101 can be deposited on the bottom of the refrigerant 103, so that it is not necessary to add a special mechanism. Further, since the uncrosslinked tape cooling device 100 has a simple structure and is easy to clean, the uncrosslinked tape 101 can be cooled inexpensively and simply.

Therefore, according to the present invention, it is possible to provide the uncrosslinked tape cooling device 100, By preventing the growth of the water tank 102, the production speed of the product can be maintained at a higher level than the conventional one, and the uncrosslinked adhesive tape 101 can be reliably cooled in a short time without applying a load to the uncrosslinked adhesive tape 101.

"Embodiment"

Next, a specific embodiment of the present invention will be described.

As shown in Fig. 4, an uncrosslinked chloroprene rubber mixture was introduced into an open roll kneader 401 (roller diameter of 18 inches) having a variable speed motor and a cutting tool, and the roll interval and the cut width were adjusted while cutting. The uncrosslinked tape 101 (thickness: 10 mm, width: 60 mm) was formed into a tape shape.

Thereafter, a cylindrical drum 105 (outer diameter: 796 mm, width: 1219 mm) obtained by bending a metal mesh 106 (short side mesh opening: 40 mm, long side mesh opening: 100 mm) made of stainless steel was used. In the water tank 102 (volume: about 2 m ³ ), cooling water (capacity: 1 m ³ ) as the refrigerant 103 is placed, and the uncrosslinked tape 101 is wound around the outer peripheral surface 104 of the cylindrical drum 105 over six turns. In a plurality of rows, the roller rotation speed of the open roll kneading machine 401 and the drum rotation speed of the cylindrical drum 105 are adjusted while the speed at which the uncrosslinked tape 101 is conveyed is about 10 m/min, and cooling is continuously performed.

Further, the uncrosslinked adhesive tape 101 after cooling is passed through a liquid separating agent (release agent) tank 402 to carry out a release prevention treatment, and thereafter, the uncrosslinked adhesive tape 101 is laminated on the container 404 by the stacking device 403.

By continuously processing the above process at a mass of about 80 kg, a high-quality uncrosslinked tape 101 having a tape length of 100 mm, a thickness of 10 ± 2 mm, and a width of 60 ± 3 mm can be stably obtained.

100‧‧‧Uncrosslinked tape cooling device

101‧‧‧Uncrosslinked tape

102‧‧‧Sink

103‧‧‧Refrigerant

104‧‧‧ outer perimeter

105‧‧‧Cylinder roller

107‧‧‧guide roller

Claims (2)

An uncrosslinked tape cooling device comprising a mesh-shaped cylindrical drum disposed to be immersed in a refrigerant placed in a water tank and rotatable freely, and rotated in conjunction with a speed at which the uncrosslinked tape is conveyed Then, the uncrosslinked adhesive tape is conveyed while being wound around the outer peripheral surface of the cylindrical drum, and is immersed in the refrigerant to be continuously cooled. The uncrosslinked tape cooling device according to the first aspect of the invention, wherein the cylindrical roller is formed by bending a mesh-shaped metal mesh.