阅读说明：本技术 层压辊 (Laminating roller ) 是由 G·沃德 于 2020-11-19 设计创作，主要内容包括：一种层压机包括层压辊。所述层压辊的柱形外表面包括反射(例如镀铬)表面区和非反射表面区。非接触式温度传感器在径向上与所述层压辊隔开并且在轴向上与所述层压辊的非反射表面区对齐,以为非反射表面区提供精确的温度测量结果。(A laminating machine includes a laminating roller. The cylindrical outer surface of the laminating roller includes reflective (e.g., chrome plated) surface regions and non-reflective surface regions. A non-contact temperature sensor is spaced radially from the laminating roller and axially aligned with the non-reflective surface region of the laminating roller to provide an accurate temperature measurement of the non-reflective surface region.)

1. A laminating roller for use in a laminator, the cylindrical outer surface of the laminating roller comprising a reflective surface region and a non-reflective surface region.

2. The laminating roller of claim 1, wherein the non-reflective surface region extends completely around the circumference of the cylindrical outer surface.

3. The laminating roller of claim 1 or 2, wherein the non-reflective surface region is located at an axial end of the laminating roller.

4. The laminating roller according to claim 1, wherein the reflective surface region comprises a layer or coating made of a metal or metal alloy and the non-reflective surface region comprises a layer or coating made of a non-reflective material.

5. The laminating roller according to claim 4, wherein the reflective surface region comprises chromium or a chromium alloy.

6. The laminating roller of claim 4, wherein the metal or metal alloy has substantially the same thermal conductivity as the non-reflective material.

7. A laminating machine, comprising:

a laminating roller having a cylindrical outer surface comprising a reflective surface region and a non-reflective surface region; and

a non-contact temperature sensor radially spaced from the laminating roller and axially aligned with a non-reflective surface region of the laminating roller.

8. The laminator of claim 7, wherein the non-contact temperature sensor is an infrared temperature sensor.

9. A method of controlling heating of a laminating roller, the cylindrical outer surface of the laminating roller comprising a reflective surface region and a non-reflective surface region, the method being based on a measured temperature of the non-reflective surface region.

Technical Field

The present invention relates to laminating rollers, and more particularly to heated laminating rollers adapted to be rotatably mounted in a laminator and used to laminate a workpiece, such as for adhering a vinyl coating or other similar coating to a surface of the workpiece.

Background

A laminator typically includes at least one laminating roller, and if the laminating roller is heated, the laminator must be able to control the heating to continuously maintain a user-determined lamination temperature. This typically requires that the temperature of the laminating rollers be accurately measured. The heated laminating roller is typically a chrome plated roller (i.e. the outer surface of which comprises a layer of chrome or chrome alloy), which means that it is relatively wear resistant and has a good heat capacity. This also means that the outer surface of the laminating roller has high reflectivity.

The temperature of the heated laminating roller is typically measured using a contact temperature sensor. The contact temperature sensor is in direct physical contact with the outer surface of the heated laminating roller as the laminating roller rotates and provides a series of temperature measurements that the laminator can use to control heating. The applicant has realised that the temperature measurements provided by such contact temperature sensors are not always accurate. Direct physical contact of the heated laminating roller with the contact temperature sensor may also cause wear of the outer surface of the roller, resulting in shallow pits or channels in the chrome plating which can adversely affect the quality of the laminating process. Contact with the laminating roller can also cause damage or degradation to the contact temperature sensor.

Non-contact temperature sensors are known, such as infrared temperature sensors, which employ one or more photodetectors to detect infrared energy emitted by an object. The photodetector converts the detected infrared energy into an electrical signal. Since the infrared energy emitted by any object is proportional to its temperature, the electrical signal can accurately measure the temperature of the object. Such non-contact temperature sensors have not been used in laminating machines because they suffer from problems when the object whose temperature is to be measured has a highly reflective surface, as is the case when using rotating chrome-plated laminating rollers.

Disclosure of Invention

The present invention aims to solve the above problems and provides a laminating roller for a laminator, the cylindrical outer surface of which comprises reflective surface regions and non-reflective (matte) surface regions.

The reflective surface region may comprise a metal or metal alloy layer or coating, such as, for example, a conventional chrome plated heated laminating roll, wherein the reflective surface region may comprise chromium or a chromium alloy layer.

The non-reflective surface region preferably extends completely along the outer periphery of the cylindrical outer surface of the laminating roller. In one arrangement, the non-reflective surface region may be provided, for example, in the form of a strip or band extending around the laminating roller. The band or strip may be, for example, about 1-2 centimeters (cm) wide.

The non-reflective surface region may be located at an axial end of the laminating roller so that it does not interfere with the laminating process, typically in a middle portion of the laminating roller for contact with the workpiece. The outer surface of the laminating roller also includes a second non-reflective surface region at an opposite axial end of the laminating roller.

The non-reflective surface region can comprise any suitable non-reflective material. The non-reflective surface region may for example comprise a layer or coating made of a non-reflective material. The layer or coating of non-reflective material may be disposed in grooves or channels formed in the outer surface of the laminating roller so that the laminating roller may have a substantially uniform diameter along its entire axial length. The groove or channel may be, for example, about 1-2cm wide. The layer or coating of non-reflective material may also be applied to the outer surface of the laminating roller without grooves or channels if the layer or coating is sufficiently thin. In use, the laminating roller will typically be heated to about 120 ℃, and the non-reflective material must therefore be stable at this temperature and preferably at higher temperatures. Any suitable non-reflective material may be used, including non-reflective paints, which may be of any suitable color, although dark or black colors are preferred.

In use, the laminating roller will be rotatably mounted within a laminating machine that also includes a non-contact temperature sensor (e.g., an infrared temperature sensor). The non-contact temperature sensor is positioned opposite the laminating roller to provide a temperature measurement of the laminating roller, particularly of the non-reflective surface region of the laminating roller. It is thus preferred that the metal or metal alloy capable of defining the reflective surface region has the same thermal conductivity (or heat transfer capability) as that of the substrate of non-reflective material, so that the temperature of the non-reflective surface region measured by the non-contact temperature sensor is substantially the same as the temperature of the reflective surface region which will be in contact with the workpiece during lamination.

The temperature measurements provided by the non-contact temperature sensor will be more accurate than those provided by conventional contact temperature sensors and can be utilized by the laminating machine to improve the heating control of the laminating roller. Problems encountered when using a non-contact temperature sensor with an object having a highly reflective surface can be avoided by intentionally providing the non-reflective surface area of the laminating roller that can be used for accurate temperature measurement. If the non-contact temperature sensor is an infrared temperature sensor, precise heating control can be achieved by measuring the temperature of the non-reflective surface region, particularly the infrared energy emitted by the non-reflective surface region of the laminating roller. The use of a non-contact temperature sensor also prevents any wear on the laminating rollers, since there is no physical contact. The quality of the lamination process is not degraded and the service life of both the laminating rollers and the temperature sensor is greatly extended.

The present invention also provides a laminator comprising a laminating roller as described above and a non-contact temperature sensor radially separated from the laminating roller (i.e., such that there is no physical contact between the sensor and the laminating roller) and axially aligned with the non-reflective surface region of the laminating roller. The non-contact temperature sensor is positioned relative to the laminating roller to provide a temperature measurement of the non-reflective surface area that can be used by the laminator to control heating of the laminating roller.

The non-contact temperature sensor may be an infrared temperature sensor or any other suitable temperature sensor. Suitable infrared temperature sensors may include commercially available infrared thermocouple sensors, infrared thermometers, and infrared pyrometers, for example.

If the outer surface of the laminating roller includes two non-reflective surface regions (e.g., at opposite axial ends of the laminating roller), the laminator can include two non-contact temperature sensors, each of which is radially separated from the laminating roller and axially aligned with a corresponding non-reflective surface region of the laminating roller to provide a temperature measurement of the corresponding non-reflective surface region.

The present invention also provides a method of controlling heating of a laminating roller having a cylindrical outer surface including a reflective surface region and a non-reflective surface region, the method being based on a measured temperature of the non-reflective surface region. The measured temperature may be obtained, for example, using a non-contact temperature sensor, such as an infrared temperature sensor.

Drawings

FIG. 1 is a schematic view of a laminator having laminating rollers according to the present invention.

Detailed Description

The laminator 1 includes a heated laminating roller 2 for contacting a workpiece, such as a sheet to be laminated, by adhering a laminate film in contact with a surface of the sheet.

The cylindrical outer surface 4 of the laminating roller 2 comprises a chrome-plated surface zone 4a which is wear-resistant and highly reflective. A non-reflective (or matte) surface region 4b is provided at one axial end of the laminating roller 2. The non-reflective surface region 4b may comprise a strip or band of suitable non-reflective material disposed in an annular groove or channel (not shown) in the outer surface of the laminating roller 2 such that the outer surface of the non-reflective material is flush with the outer surface of the chrome plated surface region 4 a. The strips or ribbons of non-reflective material are about 1-2 centimeters (cm) wide. Alternatively, the non-reflective surface region 4b may comprise a thin layer or coating of a suitable non-reflective material applied to the axial end portion of the chrome plated region. In other words, the lamination roller 2 is substantially identical to a conventional chromium-plated lamination roller, except for a thin layer or coating of a suitable non-reflective material applied to its outer surface in the form of a strip or band which, as shown, extends completely around the periphery of the lamination roller 2. This can be cost effective because conventional chrome-plated laminating rollers can be used without major modification and if the non-reflective layer or coating applied to the outer surface is sufficiently thin, the lamination quality is not significantly degraded. In one arrangement, the non-reflective material may be a coating having a high opacity, non-reflective matte finish that is capable of withstanding the maximum operating temperature of the laminator (e.g., 120 °) and is suitable for direct application to the outer surface of a conventional chrome-plated laminating roller.

The laminator 1 includes an infrared temperature sensor 6 that is radially spaced from the laminating roller 2 and axially aligned with the non-reflective surface region 4b as shown. The infrared temperature sensor 6 measures the temperature of the non-reflective surface region 4b of the laminating roller 2, and the laminator 1 uses the temperature measurement to control heating of the laminating roller. The non-reflective material defining the non-reflective surface regions 4b is selected to have substantially the same thermal conductivity (or heat transfer capability) as the chrome plated surface regions 4a and/or is applied in a thin layer or coating to bring both regions of the outer surface 4 of the laminating roller 2 to substantially the same temperature. By measuring the infrared energy emitted by the non-reflective surface region 4b using the infrared temperature sensor 6, the temperature of the chrome-plated region 4a contacting the workpiece during lamination can be determined therefrom.