Features

Controlling color harmony of multi-component products within a global supply chain is a challenge. The outstanding technical performance of the spectro2go allows the use of digital standards. Thus, everybody aims for the same target. Small parts can easily stand out like a thorn in the side, if their color does not match the other components. The new spectro2go XS with small aperture is especially developed for measurement of small parts.

Color and 60° gloss measurement in one
Exchange of digital standards due to excellent inter-instrument agreement
Balanced and upfront design with large color touchscreen
External checking and calibration standards
Live preview of the measurement spot with integrated camera
Smart high-tech LED illumination for excellent short-term, long-term and temperature stability
10 year warranty on LED light source - no lamp change needed
Professional data analysis with smart-chart combined with WiFi or USB data transfer

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Technical Attributes

Technical Properties

Measuring Capability

Color, Gloss

Color Measurement

Color Geometry

45°c:0°
Sample Port

12 mm
Measuring Area

08 mm
Spectral Range Colorimetric

400 - 700 nm, 10 nm resolution
Measurement Range

0 - 170% remission
Repeatability Color

0.01 ΔE94 (10 consecutive measurements on white)
Reproducibility Color

0.1 ΔE94 (average of 12 BCRA II tiles)
Color Systems

CIELab/Ch, Lab(h), XYZ; Yxy
Color Differences

ΔE*; ΔE(h); ΔECMC; ΔE94; ΔE99; ΔE2000; E2000 PF; ΔE DIN6175-2019
Color Indices

YIE313, YID1925, WIE313, CIE, Berger, Color Strength, Opacity, Metamerism, Grayscale
Illuminants

A, C, D50, D55, D65, D75, F2, F6, F7, F8, F10, F11, UL30, CIE 015:2018 LED Illuminants
Observer

2°, 10°

Gloss Measurement

Repeatability Gloss 0-20

± 0.1 GU
Repeatability Gloss 20-100

± 0.2 GU
Reproducibility Gloss 0-20

± 0.5 GU
Reproducibility Gloss 20-100

± 1.0 GU
Gloss Geometry

60°
Gloss Aperture

5 x 10 mm
Measurement Range Gloss

0 - 100 GU

General

Memory

4.000 Standards and 10.000 Samples
Interface

USB port
Display type or no display without placeholder

3.5 " Color Touchscreen
Languages

English German French Italian Spanish Russian Japanese Chinese
Power supply

Internal rechargeable battery
Power supply

100 - 240 V, 50/60 Hz
Battery

7.2 V, 2350 mAh, 16.92 Wh
Battery Capacity

1200 readings
Weight

0.7 kg
Weight

1.5 lb
Operating temperature

10 - 40 °C
Storing temperature

0 - 60 °C
Operating temperature

50 - 104 °F
Storing temperature

32 - 140 °F
Relative humidity

Up to 85 % non-condensing at 35 °C (95 °F)
Dimensions: L x W x H

8.7 x 11 x 18.8 cm
Dimensions: L x W x H

3.4 x 4.3 x 7.4 in

Standards

DIN EN ISO

11664

ISO

2813 7668

ASTM

D2244 E308 E1164 D523 D2457

DIN

5033 5036 6174 67530

Delivery Content

Spectrophotometer
White calibration standard
Color and gloss checking standard
Certificate
Software with two licensees for download:
smart-lab Color (7083) or smart-process Color (7084)
USB online cable type C/A for data transfer (7078)
External power supply (type A/C/G/I) (7305)
Stylus (7079)
Protective cap (7076), hand strap
Manual
Carrying case
1-day training

Downloads

Product Brochure

Safety Instructions

Safety_Instructions_spectro2guide_295024848_2402.pdf

Short Instructions

Short_Instructions_spectro2guide_295025088_2402.pdf

Operating Manuals

Knowledge

The basic building blocks of color measurement

Visual color perception is influenced by our individual color preferences, which are dependent on personal factors (mood, age, gender etc.), environment (lighting, surrounding etc.) as well as our ability to communicate color and color differences. A color looks different in the department store (cool white fluorescent lighting) than at home (warm, incandescent lighting). In order to guarantee consistent color and appearance under all possible circumstances, it is essential to standardize light source, observer and understand the spectral remission data of the object. This information will be the basis for calculation of colorimetric data as it is used for color communication and color QC in production.

Color Difference Equations for Solid Colors

It is now almost 100 years since, in 1931, the CIE Yxy chromaticity color space was defined by the “International Commission on Illumination (CIE)”. To overcome its limitations of not being uniform, the CIE recommended two alternate color spaces since then: CIELAB (or CIE 1976 L*a*b*) and CIELUV (or CIE L*u*v*). They are based on the opponent color theory of color vision, which says that two colors cannot be both green and red at the same time, nor blue and yellow at the same time. During the last years developments of new color difference equations and color spaces were carried out. Their goal was to improve the correlation between visual perception and instrumentally measured values. Additionally, they wanted to permit the use of a single number tolerance for all colors.

Color Measurement of Fluorescent Colors – a CHALLENGE

The world around us is bright and colorful. Neon colors in particular have been back in trend for several years. The prerequisite for this is the use of fluorescent pigments in the paint, plastic and many other industries. Although these have been widely used for many years, the quality control of fluorescent material still remains a major challenge. The following article describes theoretical background of fluorescence, why a standard spectrophotometer is not suitable for the quality control of fluorescent material and what possibilities the new combination of spectrophotometer and fluorimeter offers - especially with regard to predicting the lightfastness of a material.

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