KR200261836Y1 - Heating roll within a spring for calender machine - Google Patents

Abstract

The present invention mainly relates to a thermal roll for a calender machine used for calendering work of fibers, vinyl, nonwoven fabric, leather, paper, etc., in particular, penetrating the cylindrical body 12 and the center portion of the body 12 in the longitudinal direction. In the heat roll 10 consisting of a heater heat generating portion 14 for dissipating heat, the heat roll 10 is inserted into a plurality of spaces penetrating in the longitudinal direction on the circumferential surface between the surface of the heat roll 10 and the heater heat generating portion 14. The thermoelectric spring 19 is inserted into the heat transfer pipe 16 and the heat transfer pipe 16 to transfer heat efficiently by promoting convection of the heat transfer liquid 18 filled in the heat transfer pipe 16. A heat roll for a calender machine having a built-in thermoelectric spring, comprising: filling a heat transfer liquid 18 having a high thermal conductivity inside the heat transfer pipe, and inserting a thermoelectric spring 19 between the filled heat transfer solutions 18.The heat transfer efficiency of the roll 10 itself and at the same time the surface temperature according to the position of the surface of the heat roll 10 to be calendered and post-treatment work, ie to wrinkle the surface of the fabric or to change the color of the fabric There is an effect that can be performed simultaneously.

Description

Heat roll for calendar machine with built-in thermoelectric spring {HEATING ROLL WITHIN A SPRING FOR CALENDER MACHINE}

The present invention mainly relates to a heat roll for a calender machine used for calendering work of fibers, vinyl, nonwoven fabric, leather, paper, etc. More specifically, a plurality of spaces are formed along the inner circumferential surface of the heat roll, and the thermal conductivity in the space. By inserting the heat transfer pipe with high heat transfer liquid and thermoelectric spring, it is possible to reduce heat loss during calendering and to change the diameter of the space part at a certain distance, thereby providing convenience in finishing the fabric such as fibers. It relates to a heat roll for a machine.

Commonly referred to as a calender machine is a general-purpose machine that polishes all kinds of fabrics and knit fabrics and narrows them to soften the touch, or in the production of nonwovens and films, the thickness of nonwoven and film surfaces with heat and pressure. It refers to a machine that processes constantly.

Heat roll (Heating roll) is used in the calender machine as described above. The heat roll is heated by embedding a heater in the longitudinal direction in the center or heating the oil heated in the longitudinal direction in the center.

However, such a conventional heat roll is made of steel, which is a single material, and the thickness from the center portion to the surface is so thick that heat transfer from the center portion to the surface is poor, so that the temperature difference between the heater part and the heat roll surface is large, resulting in a shorter heater life. Since the temperature of the heating oil must be higher than necessary, there were many problems of heat loss.

In addition, such a conventional hot roll can only be calendered, and at the same time as the calendering, the post-treatment work, for example, the wrinkles on the surface of the fabric or the surface temperature of the hot roll can be changed depending on the position of the surface. There is a limit that cannot work such as making a change.

The present invention is devised to solve the above problems, the object of the present invention is to form a space by drilling a plurality of holes on the circumferential surface between the center and the surface of the heat roll, the thermal conductivity and thermal conductivity of the high thermal conductivity in the space It is to improve heat transfer efficiency by inserting heat transfer pipe with spring.

In addition, another object of the present invention is to maximize the heat transfer efficiency of the shape of the heat transfer pipe formed in the heat roll along the longitudinal direction to maximize the heat transfer efficiency and different surface temperature according to the surface position of the heat roll at the same time post-treatment The task is to allow the surface of the fabric to be wrinkled or to change the color of the fabric at the same time.

1 is a partial cross-sectional view schematically showing the structure of a heat roll for a calendar machine with a thermoelectric spring according to the present invention,

2 is a right side view schematically showing the structure of a heat roll according to the present invention;

3 is a partial cross-sectional view schematically showing the structure of a heat roll according to another embodiment of the present invention;

Figure 4 is a partial cross-sectional view schematically showing the structure of a heat roll according to another embodiment of the present invention.

<Explanation of symbols for main parts of the drawings>

10: heat roll 12: main body

14: heater heating portion 16: heat transfer pipe

18: thermoelectric solution 19: thermoelectric spring

20: section reduction portion 22: section expansion portion

24: slope

The present invention is a heat roll comprising a cylindrical main body and a heater heat generating portion penetrating in a longitudinal direction in the center of the main body and dissipating heat, wherein the plurality of heat penetrating in the longitudinal direction on the circumferential surface between the surface of the heat roll and the heat generating portion A heat transfer pipe inserted into two spaces and having a heat transfer liquid and a thermal spring incorporated therein, a heat transfer liquid filled inside the heat transfer pipe and having high thermal conductivity, and a heat transfer pipe filled with the heat transfer liquid, and convection and steam effects. It consists of a thermoelectric spring which promotes circulation of a thermoelectric liquid by the.

The convection phenomenon is one of the three transfer processes of heat (the other two are conduction and radiation), and means a phenomenon in which fluid moves upside down due to heat. The whole is heated evenly.

That is, the heat transferred from the lower heater heating portion heats the lower portion of the heat-transfer solution, and when the lower portion of the heat-transfer solution is partially heated to increase the temperature, the portion expands and the density becomes smaller, so buoyancy is raised and rises up. Instead, the lower temperature and higher density come down. By repeating this process, the phenomenon of transferring heat by the movement of the material itself is convection, and as a result, the heat transfer liquid becomes warm from the upper side, that is, the surface portion, thereby achieving efficient heat transfer.

On the other hand, since the expansion coefficient is changed according to the type of the heat transfer liquid, the amount of the heat transfer liquid filled in the heat transfer pipe depends on which heat transfer liquid is filled in the heat transfer pipe. Care should be taken as heat expansion may damage the heat transfer pipe.

When the temperature of the thermal fluid rises due to the convection phenomenon, part of the thermal fluid is converted into a gas, and thus the temperature of the heat transfer pipe starts to rise faster by the steam effect.

In addition, the thermoelectric spring inserted into the thermoelectric fluid serves to promote the convection phenomenon and the steam effect, and the thermoelectric spring and steam whose temperature is increased by being heated move along the wound curve of the thermoelectric spring in the process of rising upward. , The spring serves to promote the convection phenomenon and steam effect of the thermoelectric solution, the thermoelectric spring is made of a material having a higher thermal conductivity than the heat roll body, if necessary, a variety of forms such as spiral coil or grating rather than the spring It can be made into shapes.

On the other hand, the heat transfer liquid is a liquid having high thermal conductivity, water or special oil may be used, heating oil may be used.

As described above, since a heat transfer pipe having a high thermal conductivity and a thermoelectric spring is inserted in the space formed on the circumferential surface of the heat roll, the heat of the heater heat generating part circulated in the center of the heat roll is quickly transferred to the surface of the heat roll.

In addition, the present invention is to ensure that the heat transfer pipe from one end to the other end is provided with alternately continuous cross-sectional reduction portion and the cross-sectional expansion portion at a predetermined distance.

By doing the above, the heat conduction is good at the cross-sectional enlargement part and the heat conduction is not good at the cross-section reduction part. As a result, the surface temperature of the heat roll can be localized when viewed in the longitudinal direction of the heat roll. You can perform post-processing tasks such as tasks or color change tasks.

Hereinafter, with reference to the exemplary drawings will be described in detail a preferred embodiment of the present invention.

1 is a partial cross-sectional view schematically showing the structure of a thermal roll for calendar machine with a thermoelectric spring according to the present invention, Figure 2 is a right side view schematically showing the structure of a thermal roll according to the present invention, Figure 3 is 4 is a partial cross-sectional view schematically showing a structure of a heat roll according to another embodiment, and FIG. 4 is a partial cross-sectional view schematically showing a structure of a heat roll according to another embodiment of the present invention.

As shown in Figures 1 and 2, the heat roll 10 according to the present invention has a cylindrical body 12, the end surface of the main body 12 so that the heat roll 10 can be installed This reduced installation part 11 is formed.

Heater heat generating portion 14 is formed in the center portion of the body 12 of the heat roll 10 in the longitudinal direction, the heat generating portion 14 continuously generates heat to heat the heat roll 10 at a constant temperature Keep it at

On the circumferential surface between the surface of the heat roll 10 and the heater heat generating portion 14, a plurality of spaces penetrate in the longitudinal direction, the heat transfer pipe 16 made of a material having a higher thermal conductivity than the body 12 Is inserted.

The heat transfer pipe 16 is made of a material having high thermal conductivity, such as copper or aluminum, so as to transfer heat more efficiently, and may set an appropriate number according to the diameter of the heat roll 10. As an embodiment of the present invention, As shown in Fig. 2, 12 were installed, and the number of the heat transfer pipes 16 can be adjusted as needed.

The heat transfer pipe 16 forms a structure in which both ends are sealed after the thermoelectric solution 18 is filled in the state in which the thermoelectric spring 19 is inserted. In one embodiment of the present invention, the thermoelectric spring 19 is made of a metal having high thermal conductivity such as copper or aluminum, and a pair is vertically symmetric in a state where the pair is inserted into the heat transfer pipe 16.

That is, the lower portion of the heat-transfer solution 18 is partially heated by the heat transferred from the lower heater heat generating portion 14, so that the temperature is increased, so that the portion expands and the density becomes smaller, so that buoyancy is raised and rises instead. The lower temperature and lower density come down. By repeating this process, the phenomenon of transferring heat by the movement of the material itself is convection. As a result, the heat-transfer solution 18 is warmed up from the upper part, that is, from the surface of the heat roll 10, thereby achieving efficient heat transfer.

On the other hand, since the expansion coefficient is changed according to the type of the heat transfer liquid 16, the amount of heat transfer liquid 18 to be filled in the heat transfer pipe 16 is to fill any heat transfer liquid 18 to the heat transfer pipe 16. If the amount is too large, the heat transfer solution 18 is excessively heat-expanded, the heat transfer pipe 16 may be damaged, so care should be taken.

When the temperature of the heat transfer liquid 18 rises due to the convection phenomenon, part of the heat transfer liquid 18 is converted into gas, so that the temperature of the heat transfer pipe 16 starts to rise faster by the steam effect.

In addition, the thermoelectric spring 19 inserted into the thermoelectric solution 18 serves to promote the convection phenomenon and the steam effect, and the thermoelectric spring 18 and the steam whose temperature has risen by being heated are heated in the process of rising upward. Since the acceleration moves along the wound curve of the spring 19 as the whirlwind is generated, the thermoelectric spring 19 plays a role of promoting convection and steam effects of the thermoelectric solution 18.

As described above, since the heat transfer liquid 18 having a high thermal conductivity is filled in the heat transfer pipe 16, the heat of the heat generating part 14 circulated in the center of the heat roll 10 is quickly transferred to the heat roll 10. It is transferred to the surface, resulting in higher thermal efficiency.

On the other hand, as shown in Figure 3, the heat transfer pipe 16 may be provided so that the cross-sectional reduction portion 20 and the cross-sectional enlargement portion 22 alternately and at a predetermined distance from one end to the other end. have. By doing the above, the heat conduction is good in the cross-sectional enlargement section 22 and the heat conduction is not performed properly in the cross-sectional reduction section 20. As a result, when the surface temperature of the heat roll 10 is viewed in the longitudinal direction of the heat roll 10, You can make a difference.

Therefore, for example, when the fiber is reduced to a certain temperature, for example, the fiber shrinks when the temperature is more than a certain temperature, the heat roll 10 according to the present invention is calendered to make the fiber glossy and to keep the fiber yarns at the same time. In the region where the surface temperature of the high (10) is high, the fibers are shrunk in the longitudinal direction so that the fibers of the corrugated design can be produced without any post-work separately. According to the number of the cross-sectional enlargement portion 22 will be able to be wrinkled several lines. In addition, dyeing the surface of the fiber, the color is changed according to the temperature coating and then calendering by the heat roll (10) calendering is made to make the fiber gloss and to keep the interval of the fiber yarn and At the same time, in the region where the surface temperature of the heat roll 10 is high, the color of the fiber may be changed to give various color changes to the fiber, so that the fiber of various colors can be produced without any post-work separately.

On the other hand, as shown in Figure 4, the inclined surface 24 may be formed between the cross-sectional reduction portion 20 and the cross-sectional enlarged portion 22. By doing the above, it is possible to reduce the temperature change between the cross-sectional enlargement section 22 and the cross-sectional reduction section 20 to smooth the color change of the fiber.

Although the embodiments of the present invention have been described in detail as described above, the scope of the present invention is not limited thereto, and the scope of the present invention extends to an embodiment substantially equivalent to the embodiment of the present invention.

According to the present invention, a plurality of holes are formed on the circumferential surface between the central portion and the surface of the heat roll body 10 to form a space, and convective phenomena of the heat-transfer liquid 18 and the heat-transfer liquid 18 with high thermal conductivity are formed in the space. By inserting a heat transfer pipe 16 with a built-in thermoelectric spring 19 for promotion, there is an effect of increasing the heat transfer efficiency of the heat roll itself.

In addition, according to the present invention, the heat transfer efficiency of the heat transfer pipe 16 formed in the heat roll 10 may be different in the longitudinal direction, so that the surface temperature may be changed according to the position of the heat roll surface while increasing the heat transfer efficiency. At the same time as the calendar work, the post-treatment work, that is, to wrinkle the surface of the fabric or to change the color of the fabric can be performed simultaneously.

Claims (3)

In the heat roll consisting of a cylindrical main body and a heater heat generating portion which penetrates longitudinally through the central portion of the main body and generates heat continuously, The heat transfer pipe is sealed in a state in which the thermal fluid and the thermoelectric spring are embedded, and are filled in a plurality of spaces penetrating in the longitudinal direction on the circumferential surface between the surface of the heat roll and the heater heat generating portion, and the inside of the heat transfer pipe. A thermoelectric spring having a constant expansion coefficient and a thermoelectric spring inserted into a heat transfer pipe filled with the thermal fluid and for promoting circulation of the thermal fluid by convection and steam effects. Thermal roll for calendar machine with spring. The method of claim 1, The heat transfer pipe is a heat roll for a calendar machine with a built-in thermoelectric spring, characterized in that the end of the end portion and the end portion is enlarged in succession alternately with a predetermined distance from one end to the other end. The method of claim 2, And a sloped surface formed between the section reduction portion and the section expansion portion.