KR20230139719A - Coating apparatus - Google Patents

Abstract

The present invention relates to a coating device.
The coating device according to the present invention is a coating device including a transfer unit for transporting a substrate in one direction, an application unit for applying a coating material to the substrate, and a drying unit for drying the coating material, wherein the drying unit includes a nozzle that emits hot air. , a first temperature sensor measuring the temperature of the hot air and a second temperature sensor measuring the surface temperature of the coating material applied to the drying unit, and the temperature of the hot air measured by the first temperature sensor and the second temperature sensor. The temperature of the hot air measured by the first temperature sensor can be adjusted based on the temperature difference between the surface temperature of the coating material in the drying area measured by .

Description

Coating device {COATING APPARATUS}

The present invention relates to a coating device, and more specifically, to a coating device for coating a lithium secondary battery separator film.

Additionally, the present invention relates to a lithium secondary battery separator film using such a coating device.

In a lithium secondary battery, the electrode assembly includes a negative electrode plate, a positive plate, and a separator. The separator is interposed between the negative and positive plates to electrically insulate them while allowing lithium ions to move. Such separators are manufactured by, for example, coating a substrate made of polyethylene, polypropylene, polyethylene terephthalate, etc. with a coating material made of barium sulfate, alumina, boehmite, etc. The coating device used for this includes an application unit that applies the coating material to the substrate, a drying unit that dries the coating material, etc. In the drying section, hot air is often used to dry the coating material, but if the residence time is reduced to increase speed, a problem may occur in which the coating material is not sufficiently dried. However, if you recklessly increase the temperature of the hot air to solve this problem, heat wrinkling may occur due to surface drying and solidification. This causes quality deterioration due to deterioration of planarity. Therefore, a technology is needed that can prevent non-drying of the coating material and prevent surface drying and solidification.

The purpose of the present invention is to provide a coating device that can prevent non-drying of the coating material.

Another object of the present invention is to provide a coating device that can prevent surface drying and solidification.

Another object of the present invention is to provide a lithium secondary battery separator film using such a coating device.

The coating device according to the present invention is a coating device including a transfer unit for transporting a substrate in one direction, an application unit for applying a coating material to the substrate, and a drying unit for drying the coating material, wherein the drying unit includes a nozzle that emits hot air. , including a first temperature sensor disposed upstream of the hot air discharge port of the nozzle that measures the temperature of the hot air and a second temperature sensor that measures the surface temperature of the coating material applied in the drying unit, the first temperature sensor and the second temperature The combination of sensors can coat the separator film for a lithium secondary battery provided at least one pair in the drying unit.

Additionally, the drying unit may be defined as an internal space having an inlet and an outlet, and the second temperature sensor may be defined and disposed as an outlet of the drying unit.

In addition, a means for adjusting the temperature of the hot air measured by the first temperature sensor may be provided based on the difference between the temperature of the hot air measured by the first temperature sensor and the surface difference of the applied coating material measured by the second temperature sensor.

Additionally, the present invention provides a lithium secondary battery separator film using the above-described coating device.

The coating device according to the present invention determines that non-drying of the coating material may occur when the temperature difference between the surface of the applied coating material increases by measuring the temperature of the hot air measured by the first temperature sensor and the second temperature sensor, and the temperature of the hot air is By increasing the temperature, non-drying of the coating material can be prevented.

In particular, if the second temperature sensor is disposed inside the drying furnace outlet, non-drying of the film surface coating material exiting the drying furnace can be more reliably prevented.

In addition, this prevents the temperature of the hot air from becoming excessively high, thereby preventing heat wrinkling due to surface drying and solidification.

1 is a configuration diagram of a coating device according to an embodiment of the present invention.
Figures 2 and 3 show changes in the ratio of the amount of steam to the difference between the temperature of the hot air and the internal temperature of the drying unit in the coating device according to an embodiment of the present invention.

With reference to the drawings, a coating device according to an embodiment of the present invention, particularly a coating device that can be used to coat a lithium secondary battery separator film, will be described in detail.

1 is a configuration diagram of a coating device according to an embodiment of the present invention.

Referring to Figure 1, the coating device includes a transfer unit 100, an application unit 200, and a drying unit 300.

The transport unit 100 serves to transport the substrate in one direction. The method of the transfer unit 100 is not particularly limited as long as it can properly transfer the substrate in one direction. For simple understanding, for example, the transfer unit 100 may be configured as a conveyor belt.

The applicator 200 serves to apply a coating material to the substrate. The method of the application unit 200 is not particularly limited as long as it can properly apply the coating material to the substrate, so a detailed description thereof will be omitted.

The drying unit 300 is disposed downstream of the application unit 200 based on the transfer direction of the transfer unit 100 and serves to dry the coating material. For this purpose, the drying unit 300 defines the internal space of the drying unit 300 and includes an inlet 311 and an outlet 312, a hot air providing means 320 for providing hot air, and an extension from the hot air providing means 320. a main duct 330, a nozzle 340 connected to the main duct 330 to emit hot air toward the substrate and coating material, and a first temperature sensor that measures the temperature of the hot air provided upstream of the hot air discharge port of the nozzle ( 350) and a second temperature sensor 360 that measures the surface temperature of the coating material applied to the drying unit 300.

Additionally, the drying unit may be composed of a plurality of drying chambers. When the drying unit is composed of a plurality of drying chambers, it is preferable that at least one pair of the first temperature sensor and the second temperature sensor combination are provided in at least the most upstream drying room and the most downstream drying room.

The hot air providing means 320 is not particularly limited as long as it can change the mixing ratio of heated air and outside air, and can change the heating temperature of the heated air.

It includes a fan 321 for introducing outside air, an outside air duct 322 extending from the fan 321, a steam generation means 323 for generating high temperature steam, and a steam duct 324 extending from the steam generation means 323. And, the outdoor air duct 322 and the steam duct 324 may be joined into the main duct 330. Therefore, by providing outdoor air corresponding to room temperature and steam corresponding to high temperature, the temperature of the hot air can be adjusted by adjusting the amount of outdoor air and the amount of steam. In other words, as the amount of outside air becomes relatively larger or the amount of steam becomes relatively smaller, the temperature of the hot air decreases, and as the amount of outside air becomes relatively smaller or the amount of steam becomes relatively larger, the temperature of the hot air decreases. The temperature of the hot air increases.

A plurality of nozzles 340 may be provided and arranged at specific intervals along the transfer direction of the transfer unit 100.

The location of the first temperature sensor 350 is not particularly limited as long as it can properly measure the temperature of the hot air upstream of the hot air discharge port, but is preferably located adjacent to the nozzle 340 in order to more accurately measure the temperature of the hot air. Preferably, it may be placed inside the nozzle 340, and more preferably, may be placed at the center of the inside of the nozzle 340. Additionally, a plurality of first temperature sensors 350 may be provided and each may be arranged for different nozzles 340. Therefore, measurement accuracy and reliability can be improved by using the average temperature of the hot air measured by the plurality of first temperature sensors 350.

As long as the second temperature sensor 360 can properly measure the surface temperature of the coating material of the drying section 300, the placement location is not particularly limited to either the inside or the outside of the drying section, but the coating material is placed in the area exiting the outlet 312. To prevent non-drying, a point or outlet 312 is located adjacent to the outlet 312, preferably between the first and second closest nozzles 340 to the outlet 312. It may be placed at a corresponding point between the first closest nozzle 340 and the outlet 312. Additionally, a plurality of second temperature sensors 360 may be provided and disposed at different points. Therefore, measurement accuracy and reliability can be improved by averaging the internal temperature of the drying unit 300 measured by the plurality of second temperature sensors 360. In addition, the second temperature sensor is preferably a non-contact thermometer such as a radiation thermometer in order to prevent the quality of the surface of the coating material from deteriorating when measuring the surface temperature of the coating material. In addition, the second temperature sensor 360 is disposed adjacent to the surface of the coating material at the outlet 312, thereby preventing heat wrinkling due to surface drying and solidification.

The drying unit 300 adjusts the temperature of the hot air in consideration of the temperature of the hot air measured by the first temperature sensor 350 and the surface temperature of the coating material of the drying unit 300 measured by the second temperature sensor 360. do. More specifically, the temperature of the hot air is adjusted based on the difference between the temperature of the hot air measured by the first temperature sensor 350 and the surface temperature of the coating material of the drying unit 300 measured by the second temperature sensor 360. . For example, assuming that the temperature of the hot air is constant, the lower the film surface temperature of the drying unit 300, the more heat is consumed to dry the coating material, and the more heat is required to sufficiently dry the coating material. It can mean. Accordingly, the drying unit 300 is operated when the difference between the temperature of the hot air measured by the first temperature sensor 350 and the surface temperature of the coating material of the drying unit 300 measured by the second temperature sensor 360 is greater than a preset range. The temperature of the hot air can be controlled to increase for a preset time. For example, when the difference between the temperature of the hot air measured by the first temperature sensor 350 and the surface temperature of the coating material of the drying unit 300 measured by the second temperature sensor 360 becomes greater than a preset range, the difference increases. The temperature of the hot air may increase stepwise (see Figure 2) or increase continuously (see Figure 3).

For example, in the following implementation conditions, the difference between the temperature of the hot air measured by the first temperature sensor 350 and the surface temperature of the coating material of the drying unit 300 measured by the second temperature sensor 360 will be 10°C or more. It was found that non-drying of the coating material occurred from this point on.

○ Material: polyethylene, polypropylene, polyethylene terephthalate, etc.

○ Coating materials: barium sulfate, alumina, boehmite, etc.

○ Application thickness: 1-10 μm

○ Application width: 300-2,000 mm

○ Transfer speed of transfer unit 100: 30-200 m/min

○ Area of main duct (330): 0.01-1 m ²

○ Pressure of main duct (330): 10-1000 Pa

In this case, if the difference between the temperature of the hot air measured by the first temperature sensor 350 and the surface temperature of the coating material of the drying part 300 measured by the second temperature sensor 360 is greater than 0℃ and less than 10℃, It operates under set normal operating conditions (i.e., the amount of outdoor air and the amount of steam are kept constant at preset values, respectively), and the temperature of the hot air measured by the first temperature sensor 350 and the second temperature sensor 360 are measured. If the difference in the surface temperature of the coating material of the drying unit 300 measured by is 10°C or more and less than 15°C, the amount of steam is increased by 10% compared to normal operating conditions, and the temperature of the hot air measured by the first temperature sensor 350 is increased by 10%. If the difference between the surface temperature of the coating material of the drying unit 300 measured by the second temperature sensor 360 is 15°C or more and less than 20°C, the amount of steam is increased by 20% compared to normal operating conditions, and the first temperature sensor ( If the difference between the temperature of the hot air measured by 350) and the surface temperature of the coating material of the drying unit 300 measured by the second temperature sensor 360 is 20°C or more, the amount of steam can be increased by 30% compared to normal operating conditions. there is. More preferably, the difference between the temperature of the hot air measured by the first temperature sensor 350 and the surface temperature of the coating material of the drying part 300 measured by the second temperature sensor 360 is greater than 0℃ and less than 5℃. When operating under preset normal operating conditions and the difference between the temperature of the hot air measured by the first temperature sensor 350 and the surface temperature of the coating material of the drying unit 300 measured by the second temperature sensor 360 is 5°C or more. From there, you can gradually increase the amount of steam.

In this way, the difference between the temperature of the hot air measured by the first temperature sensor 350 and the surface temperature of the coating material of the drying unit 300 measured by the second temperature sensor 360 is greater than the preset range (for example, 0-10°C). It is determined that non-drying of the coating material may occur if it becomes large, so non-drying of the coating material can be prevented by increasing the amount of steam for a preset time to increase the temperature of the hot air.

The coating device described above is only one of the coating devices according to various embodiments of the present invention. The technical idea of the present invention is not limited to the above embodiments, and as described in the claims, includes all modifications that can be easily made by a person skilled in the art to which the present invention pertains.

100: transfer unit
200: Applicator
300: Drying unit
311: entrance
312: exit
320: Means of providing craze
321: fan
322: External air duct
323: Steam generation means
324: Steam duct
330: main duct
340: nozzle
350: first temperature sensor
360: Second temperature sensor

Claims (4)

A transport unit for transporting the substrate in one direction,
an applicator for applying a coating material to at least a cross section of the substrate; and
A coating device including a drying unit for drying the coating material,
The drying part
A nozzle that emits hot air,
It includes a first temperature sensor disposed upstream of the nozzle hot air discharge port for measuring the temperature of the hot air and a second temperature sensor for measuring the surface temperature of the coating material applied to the drying unit,
A coating device, wherein the base material having at least one pair of the first temperature sensor and the second temperature sensor in a drying unit is a lithium secondary battery separator film. According to paragraph 1,
The drying unit is defined as an internal space having an inlet and an outlet, and the second temperature sensor is disposed adjacent to the outlet through which the substrate is discharged from the drying unit. According to claim 1 or 2,
Hot air temperature control means for adjusting the hot air temperature measured by the first temperature sensor based on the difference between the temperature of the hot air measured by the first temperature sensor and the surface temperature of the coating material of the drying area measured by the second temperature sensor. A coating device equipped with a. A lithium secondary battery separator film coated with the coating material by the coating device according to claim 1.