Flourpedia.com - Medium to high protein
content, hard endosperm, white bran. Used in Asian noodles, whole wheat or high
extraction flour applications, pan breads and flat breads.
52 samples Collected by state
and private inspection agencies; commercial wheat handlers; Plains Grains,
Inc.; and state wheat commissions.
The Wheat Marketing Center (WMC) conducted the quality analyses. The
Federal Grain Inspection Service (FGIS) graded the samples
Official grade factors were
determined on each sample. Non-grade factors and functionality tests were
conducted on 6 composite samples categorized by growing region and protein
ranges of <11.5%, 11.5% to 12.5% and >12.5%.
The growing regions are
highlighted on the map on page 23. The methods are described in the Analysis
Methods section of this blog.
HARVEST SURVEY
The 2017 hard white wheat (HW) crop was grown primarily in Colorado,
Kansas, Idaho and Nebraska. Other states including California, Montana, North
Dakota and South Dakota had limited production.
U.S. Wheat Associates estimates
2017 Hard white wheat production at 883,300 metric tons (MT), down slightly from 2016's
898,600 MT reported by USDA
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| Hard White Wheat Production |
WHEAT AND GRADE DATA
All six composites graded U.S. No. 1 with test weight ranging from
61.4 to 65.2 lb/bu (80.7 to 85.7 kg/hl).
The ranges of values found in the
composites are: dockage from 0.1 to 0.7%; wheat moisture from 7.7% to 11.1%;
wheat protein from 10.4% to 13.3% (12% mb); wheat ash from 1.45% to 1.57% (14%
mb); kernel hardness from 59.4 to 72.3; and kernel diameters from 2.67 to 2.93
mm.
The thousand kernel weights (TKW) of Pacific Northwest (PNW) low- and high-protein
composites and California low- and high-protein composites are 32.9 g or
higher, while the TKW of Southern Plains low- and medium-protein composites are
29.0 g and 29.7 g, respectively.
Falling number values are 299 sec or higher
for all composites, indicating mostly sound grain.
FLOUR, DOUGH AND BAKING DATA
Buhler laboratory mill straight-grade flour extractions range from
71.1% to 74.5%, L* values (whiteness) from 91.3 to 92.0, flour protein from
9.1% to 12.4% (14% mb), and flour ash from 0.39% to 0.46% (14% mb). These
values are within the historical ranges of Hard White Wheat flour.
Flour wet gluten contents range from 19.0% to 31.3% depending on flour
protein content. Amylograph peak viscosities are between 345 BU and 929 BU,
which show good starch pasting properties for most samples that are suitable
for Asian noodle application.
Starch damage values are in the range of 3.8% to
5.3%. Lactic acid SRC values are 117% to 159%, indicating medium to strong
gluten strength.
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| Farinograms, alveograms and extensograms graphs of Hard White Wheat |
Farinograph absorptions range from 56.9% to 66.0% and stability times
from 7.9 min to 17.1 min, exhibiting the typically medium to strong dough
characteristics of Hard White Wheat.
Hard White Wheat farinograph water absorption is usually between that
of HRW and HRS depending on protein content, and stability time is longer,
indicating more tolerance to overmixing. The ranges of alveograph values are: P
values 83 mm to 197 mm; L values 58 mm to 96 mm; and W values 212 to 439 (10-4 J).
Extensograph data at 135-min resting show that maximum resistance is in the
range of 646 BU to 1180 BU, extensibility from 11.8 cm to 18.6 cm and area from
108 cm2 to 225 cm2.
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| Farinograms, Alveograms and Extensograms of PNW Low and High Hard White Wheat |
Most samples show good baking performance relative to protein content,
with bake absorptions in the range of 62.0% to 71.1%, loaf volumes of 762 cc to
953 cc and crumb grain and texture scores of 5.0 points to 7.5 points.
NOODLE EVALUATION
Hard White Wheat flours and a control flour were evaluated for both Chinese raw
noodles (white salted) and Chinese wet noodles (yellow alkaline).
For Chinese
raw noodles, the L* values at 0 hr of production and after 24 hr of storage at
room temperature are acceptable for all samples except for the California
high-protein composite, which has a L* 24 hr value of 70.5 (72 is the minimum
value at 24 hr).
The sensory color stability score is close to acceptable for
most samples (7.0 is the control noodle).
Cooked noodle texture is softer for
California high-protein composite and Southern Plains low-protein composite due
to low amylograph peak viscosity and For Chinese wet noodles, sensory color
stability scores are acceptable for PNW composites and Southern Plains
composites.
The cooked noodle hardness values of all Chinese wet noodles
indicate acceptable texture. Overall, this year's Hard White samples will produce
noodles with more acceptable color and texture if low ash patent flour is used.
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| Harvest Data Hard White Wheat 2017 |
STEAMED BREAD EVALUATION
Hard White Wheat flours were evaluated for Asian steamed breads in comparison with a
control flour.
Results show most samples are acceptable for steamed breads
except for the Southern Plains low- and medium-protein composites, which
indicate slightly low total product scores.
The specific volumes are similar
for all samples except for the California high-protein composite because its
dough was a slightly strong for steamed bread expansion. Blending 10% to 25% of
SW flour with high protein Hard White Wheat flour would improve overall steamed bread quality.
SUMMARY
This year’s samples show good quality performance in milling, dough
rheological properties and end products, including pan breads, Asian noodles
and steamed breads. PNW low- and high-protein composites and California
high-protein composite have very good bread baking potential.
For Asian noodle
applications, most samples have good noodle color and color stability in both
raw noodle and wet noodle and produce noodles of acceptable texture.
For
steamed breads, it is recommended that high protein Hard White Wheat flour be blended with a
small portion of SW flour to improve product quality by avoiding steamed bread
shrinkage.
Title : Hard White Wheat (US Wheat Associates 2017 Crop Quality)
Originally Publish At : www.uswheat.org
Originally Publish At : www.uswheat.org
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