軽い読み物に興味はありますか？

He’s looking mad, today. Well, he looks mad every day, that’s his look, mad, but today he looks like he means it. “Scott!” he shouts. It isn’t even 8 AM yet. “Yessir?” I ask. “Scott, do I look like a fool to you?” he asks. “No sir,” I say. “You look mad. That’s your look. Mad.” This was all so much easier back when he was just making rap music. But you try telling him fashion was a bad idea. “I am mad!” he shouts. “My warm brown cotton/nylon Meggings line don’t look warm brown to me. They look cool brown! I can’t sell cool brown cotton/nylon Meggings, Scott! I’m gonna look like a fool!” “You don’t look like a fool,” I try. “You look mad.” But he’s not even listening anymore. “We gotta send it back,” he’s telling himself. “We gotta send the whole shipment back. Why would they send me cool brown? Why would they play me like that?” He drops his sunglasses to his nose and stares me in the eyes. “Scott,” he asks. “Do people not take me seriously?”

Garment manufacturers take the color of the clothing they produce seriously because their clients take the color of their clothing seriously. Achieving correct, consistent color in blended natural and synthetic fibers is inherently difficult. So serious garment manufacturers incorporate objective, spectrophotometric color measurement into their manufacturing process. Because until you put a number on it, there’s no real way to tell what a designer wants when they say warm brown.

Don’t they know those are Meggings? Image Credit: Flickr User fervent-adepte-de-la-mode (CC BY 2.0)

The Ultra-Scan VIS can accurately measure carpet color because it takes texture into account. Image source: Pixabay user Frantisek_Krejci

A hotel chain has hired an interior designer to replace the old carpet design in every guestroom with something that looks more sleek and modern. After sifting through a number of swatches, the designer finds the perfect shade: a simple charcoal grey design that will contrast beautifully against the crisp white comforters and bed sheets that the hotel uses. But in order for the interior designer’s vision to truly come to life, the carpet color needs to be consistent from room to room. Not only does every guest room have to match, the hotel also needs to ensure that the carpeting looks seamless from the entrance of the room to every corner. If the hotel receives rolls of carpeting that vary in color even slightly, it will make every seam more obvious–the hotel will end up with a room that looks more like a patchwork quilt than a chic, modern space (commonly referred to as a “carpet sidematch problem”).1

This is just one of many reasons carpet manufacturers should take accurate color measurements of their products before releasing them on the market. However, it isn’t always easy to measure carpet color, even when you use color measurement tools like spectrophotometers. Because carpeting is soft, uneven and not always entirely opaque, analyzing the color of your samples can be frustratingly complicated. An instrument such as the UltraScan VIS, however, simplifies this process by allowing for optimal measurement methodology and the highest degree of color measurement precision. Unlike many other spectrophotometers on the market, the UltraScan VIS instrument is specifically designed to measure carpeting (among many other sample types), and makes the color quality control process fast, simple and extremely accurate.  

The Challenges of Analyzing Carpet Color

Carpet swatches seem easy to analyze at first glance, especially when designs feature just one solid color. However, carpeting is never truly “solid” in color, even if it appears so to the naked eye. If you look carefully at any carpet swatch, you’ll see that the tiny particles that make up the sample frequently vary in opacity, shape, and color. These three factors pose a number of challenges for manufacturers.   

Challenge #1: Opacity

Opacity is one of the first challenges you’ll come across when you try to measure the color of your sample using a spectrophotometer. Many carpet products are slightly translucent, and this becomes more obvious when you change the backing of your sample. For instance, your slightly translucent carpet sample will look lighter when backed by a light-colored background, but that same sample will appear much darker when backed by a dark-colored background. In order to get an accurate measurement, you have to standardize your sample backing.

Challenge #2: Shape

Carpeting isn’t flat. Rather, the material is flexible, and the tiny threads that make up the sample can shift with even the slightest pressure. The non-homogenous nature of carpeting makes it difficult to measure color unless you use tools specifically designed to handle textured samples. When a color measurement instrument presses into a carpet swatch, it creates a pillowing effect. The tiny carpet particles bend around the instrument’s measurement port, and this in turn can cast shadows that alter the overall color reading. To fix this, you need to take several readings in succession, then average those readings to get an accurate measurement.

Challenge #3: Color

Finally, the color of your sample or the type of dye that you use can cause a few unexpected problems for color measurement instruments. The most common problem that you may come across is the use of fluorescent dye in carpeting. This dye makes the product appear brighter and whiter than it is, and it is frequently used in white carpeting.2 Although this dye makes your products look whiter and potentially more appealing, it also makes your samples more sensitive to UV light. When your sample is exposed to the UV that naturally occurs in your light source, it can alter the overall measurement result, making your product appear lighter. This is why you need to cancel out the impact of UV on your sample or take UV into account when you measure your product’s color.

Pile heights and texture can significantly affect the appearance of your carpet samples. Image Source: Unsplash user Dane Deaner

The Grey Change scale can help detect the amount of fading that occurs in different textiles after they’re washed. Image Source: Max Pixel

A homeowner decided to wash a set of red living room curtains for the very first time, carefully following the cleaning instructions listed on the label. He avoided bleach products and washed the curtains on the delicate cycle setting. But despite his diligence, the color nonetheless faded significantly after washing; his once-red curtains were now a shade of faded pink, and they no longer matched the color scheme of the living room.

This is a common challenge that textile manufacturers face, whether they’re dyeing textiles for curtains, blankets, clothing or any other colorful fabric. If a large-scale textile manufacturer fails to identify problems with fading or color bleeding in its products early on, it could lead to customer dissatisfaction later. Yet there is a solution to this problem. Using the Grey Change and Grey Stain color scales, which are included in the software packaged with some advanced spectrophotometers, textile manufacturers can identify both fading and bleeding early on in the dyeing process. These two color scales are specifically designed to analyze color fastness and dye durability, allowing manufacturers to refine their dyeing processes and invest in the most durable dyes for their products.

The Problem with Some Colorful Textile Dyes

Certain textile dyes are more prone to fading and bleeding than others and environmental factors like exposure to UV rays or frequent washing can significantly alter product color depending on the chemical makeup of the dye.1 This is why textile manufacturers must consider the color fastness of the dye being used for each product, as different types of dyes will have different benefits and downsides.

The term “color fastness” refers to a dye’s durability against fading and bleeding; a dye that has excellent color fastness will be durable and long-lasting, even when exposed to environmental factors that cause color fading or bleeding. A dye with poor color fastness won’t be as durable. For instance, one type of dye that is known for its excellent color fastness is an azoic or naphthol dye.2 These dyes produce bright, bold colors, especially in the red and orange spectrum, and are highly resistant to fading in the wash or even when exposed to bleach. Conversely, acidic dyes tend to be resistant to color fading when they’re exposed to sunlight, but they’re much more prone to fading and bleeding after washing. Here are a few more examples of common textile dyes and their typical color fastness:

• Basic: Excellent light and wash fastness.
• Disperse: Good light and wash fastness, but sensitive to nitrogen gas.
• Direct: Fair lightfastness, but very poor wash fastness.
• Reactive: Great light and wash fastness, but prone to bleeding excess dye unless it’s washed well during manufacturing.
• Mordant: Good light and wash fastness, but only available in a small range of colors.
• Premetallized: Good light and wash fastness, but only available in a small range of colors.
• Sulphur: Fair light and wash fastness.
• Vat: Excellent color and wash fastness. It’s perhaps the most durable textile dye used by manufacturers.
• Fluorescent brighteners: Fair wash fastness, but very poor lightfastness.

While this basic list of color fastness can give you a general idea of which textile dyes will be the best choice for your textile products, the list isn’t foolproof. For example, although sulphur dye is generally fairly resistant against color fading after being washed or exposed to sunlight, some manufacturers have found that certain sulphur-dyed yarns will occasionally fade after about six months of use. This is why it’s important to test your dyes for true color fastness using the Grey Change and Grey Stain scales; every dye reacts differently with each fabric you use, so by testing each new product in advance, you may produce more durable, colorful textiles.

Textile dyes vary in color fastness depending on the chemical makeup of the dye or the type of fabric that a manufacturer uses. Image Source: Shutterstock user Pichit Tongma

Accurate color matching is essential to creating high-quality products in the textile industry. Image Source: Unsplash user Charisse Kenion

If you work in the textile industry, you understand the complexities inherent to creating the perfect hues. From raw materials to processing methods, the final appearance of your textiles depends on a plethora of variables that must be closely monitored in order to produce the colors you want. As such, color quality control is a core component of the product development and manufacturing process, helping you ensure that your products live up to your vision.

However, the textile industry faces unique challenges when it comes to implementing robust color quality control systems. One of the most significant challenges is identifying illuminant metamerism, which can be a serious barrier to color matching. Without the ability to control for this phenomenon, your ability to achieve your desired result is compromised, potentially leading to unnecessary waste and reduced efficiency. As such, investing in technologies that can alert you to illuminant metamerism is essential to producing just the right hues.

Changes in light source can drastically alter how we perceive color. Image Source: Unsplash user tu tu

Conspicuity is the essential function of High Visibility Safety Apparel (HVSA), protecting workers across the nation who depend on being easily seen to prevent accidents. Highway workers, construction crews, airport personnel, firefighters, and many others rely on the enhanced visibility these garments provide when performing their duties in dangerous areas with low visibility conditions.

HVSA can be important in civilian life as well, for bikers, hunters, or anyone outdoors during hunting season.

While garment manufacturers have a stake in the correct coloration of their products, in the case of HVSA, the obligation has actually been codified into law. According to the U.S. Occupational Safety and Health Administration, workers performing dangerous tasks requiring conspicuity, such as roadside workers, must wear garments that conform to the requirements established in ANSI/ISEA 107-2015. The ANSI standards require that a garment’s material must be tested by an accredited laboratory and certified by the manufacturer with a Declaration of Conformity.

Without proper testing and the ability to guarantee that their HVSA meets ANSI standards, manufacturers face significant risks in sending these products to market. To remain competitive, manufacturers must invest in color quality control equipment and processes, including spectrophotometers/colorimeters.

How Do Spectrophotometers Ensure Compliance With High-Visibility Safety Standards?

Color measurement devices that ascertain the exact color of opaque materials by measuring reflected light are known as reflectance spectrophotometers. HVSA manufacturers depend on these solutions to ensure their clothing meets the color standards prescribed in ANSI 107. The extraordinary degree of color measurement accuracy offered by reflectance spectrophotometers makes them essential to determining the color of these garments and a standard part of safety testing.

ANSI/ISEA standards explicitly require the use of spectrophotometers/colorimeters for both color and colorfastness testing of HVSA. While third-party laboratories perform final certification, manufacturers must incorporate spectrophotometric measurement into their own quality control processes to ensure compliance. These devices prevent costly rejections and delays by confirming garments meet color requirements before they're submitted for certification or shipped to distributors.

Manufacturers can use modern spectrophotometers or colorimeters with dedicated color-measurement software to check how closely production colors align with their specified standards. The software expresses color as numerical values, making it easier to monitor small shade differences and document whether batches fall within defined tolerances.

You can also save standards in the device's memory, so technicians can quickly select the framework they need when testing different batches of clothing.

Conspicuity is the essential function of High Visibility Safety Apparel (HVSA), protecting workers across the nation who depend on being easily seen to prevent accidents. Highway workers, construction crews, airport personnel, firefighters, and many others rely on the enhanced visibility these garments provide when performing their duties in dangerous areas with low visibility conditions.

HVSA can be important in civilian life as well, for bikers, hunters, or anyone outdoors during hunting season.

While garment manufacturers have a stake in the correct coloration of their products, in the case of HVSA, the obligation has actually been codified into law. According to the U.S. Occupational Safety and Health Administration, workers performing dangerous tasks requiring conspicuity, such as roadside workers, must wear garments that conform to the requirements established in ANSI/ISEA 107-2015. The ANSI standards require that a garment’s material must be tested by an accredited laboratory and certified by the manufacturer with a Declaration of Conformity.

Without proper testing and the ability to guarantee that their HVSA meets ANSI standards, manufacturers face significant risks in sending these products to market. To remain competitive, manufacturers must invest in color quality control equipment and processes, including spectrophotometers/colorimeters.

How Do Spectrophotometers Ensure Compliance With High-Visibility Safety Standards?

Color measurement devices that ascertain the exact color of opaque materials by measuring reflected light are known as reflectance spectrophotometers. HVSA manufacturers depend on these solutions to ensure their clothing meets the color standards prescribed in ANSI 107. The extraordinary degree of color measurement accuracy offered by reflectance spectrophotometers makes them essential to determining the color of these garments and a standard part of safety testing.

ANSI/ISEA standards explicitly require the use of spectrophotometers/colorimeters for both color and colorfastness testing of HVSA. While third-party laboratories perform final certification, manufacturers must incorporate spectrophotometric measurement into their own quality control processes to ensure compliance. These devices prevent costly rejections and delays by confirming garments meet color requirements before they're submitted for certification or shipped to distributors.

Manufacturers can use modern spectrophotometers or colorimeters with dedicated color-measurement software to check how closely production colors align with their specified standards. The software expresses color as numerical values, making it easier to monitor small shade differences and document whether batches fall within defined tolerances.

You can also save standards in the device's memory, so technicians can quickly select the framework they need when testing different batches of clothing.

Gut sichtbare Kleidung ist für die Sicherheit unter gefährlichen Bedingungen unerlässlich. Bildquelle: Unsplash Benutzer Ricardo Gomez Angel

Arbeitnehmer im ganzen Land sind jeden Tag auf gut sichtbare Sicherheitskleidung angewiesen, wenn sie aufstehen und zu ihrer Arbeitsstelle gehen. Autobahnarbeiter, Bauarbeiter, Flughafenpersonal, Feuerwehrleute, einige Fabrikarbeiter und Telefonisten sind alle auf fluoreszierende Kleidung angewiesen, um von anderen gesehen zu werden und Unfälle zu vermeiden. Praktisch überall, wo Arbeitnehmer ihre Arbeit in gefährlichen Bereichen mit schlechten Sichtverhältnissen verrichten, ist Sicherheitskleidung ein wesentliches Element ihrer täglichen Ausrüstung. Warnkleidung kann auch im zivilen Leben wichtig sein, z. B. für Radfahrer, Jäger oder alle, die während der Jagdsaison im Freien unterwegs sind.

Es ist zwar selbstverständlich, dass Bekleidungshersteller ein Interesse an der korrekten Farbgebung ihrer Produkte haben, aber im Fall von Warnschutzkleidung ist die korrekte Farbgebung sogar gesetzlich vorgeschrieben. Laut der U.S. Occupation Safety and Health Administration müssen Arbeitnehmer, die gefährliche Aufgaben ausführen, die eine hohe Sichtbarkeit erfordern, wie z. B. Straßenarbeiter, Kleidung tragen, die den Anforderungen der Norm ANSI/ISEA 107-2015 entspricht.1 Die ANSI-Normen schreiben vor, dass das Material eines Kleidungsstücks von einem akkreditierten Labor getestet und vom Hersteller mit einer Konformitätserklärung zertifiziert werden muss.2 Ohne ordnungsgemäße Tests und die Möglichkeit, zu garantieren, dass ihre Produkte die ANSI-Normen erfüllen, können die Hersteller keine gut sichtbare Sicherheitskleidung verkaufen, ohne sich einem hohen Risiko auszusetzen. Um auf dem Markt für Sicherheitskleidung wettbewerbsfähig zu sein, müssen die Hersteller in Instrumente und Verfahren zur Farbqualitätskontrolle, einschließlich Spektralphotometer, investieren.

Feuerwehrleute tragen Warnkleidung, um bei der Arbeit sicher zu sein. Bildquelle: Unsplash Benutzer Benjamin Kerensa