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‘ This is to certify that the

1' thesis entitled

.- THE RELIABILITY OF SEVERAL I‘OM'IULAS FOR THE
CALCULATION Ol‘ WEIGHT PER GALLON OF ICE
CHEM MIXES OF VARYING COMPOSITIONS

I presented by

Kenneth Terry Scott.
has been accepted towards fulfillment

\ of the requirements for

M. S. degree mm

1' Major prof ssor

“L Date—NW

0-169

‘V.’

*—

 

ra-

 

.THE RELIABILITY OF SEVERAL FORMULAS FOR THE
CALCULATION OF WEIGHT PER GALLON OF
ICE CREAM MIXES OF VARYING

COMPOSITIONS

BY

KENNETH TERRY SCOT T

w

A THESIS

Submitted to the School of Graduate Studies of Michigan
State College of Agriculture and Applied Science
in partial fulfillment of the requirements
for the degree of

MASTER OF SCIENCE

Department of Dairy

1951

1 HESIS

ACKNOWLEDGMENTS

The writer wishes to express his sincere appreciation
to the following:

Dr. Earl Weaver, Professor and Head of the Department
of Dairy, for placing the facilities of the department at the
writer’s disposal;

Dr. J. A. Meiser, Jr., Assistant Professor of Dairy,
under whose direction this investigatiOn was performed, for his
helpful planning and guidance in carrying out this work and in-
valuable assistance in the preparation of this manuscript;

Professor P. 5. Lucas, Associate Professor of Dairy,
for his helpful suggestions throughout the course of this inves-

tigation.

2684.01.

TABLE OF CONTENTS

INTRODUCTION . . . . . . . .

REVIEW OF LITERATURE . .

Regulations Governing Standards for Ice Cream .

Measurement of Overrun . . . . . . . .
Methods of Calculating Weight per Gallon of
NIixes . . . . . . . .

PLAN OF EXPERIMENT . . .

GENERAL PROCEDURES . . . . . . . .
Composition of the Mixes . . . . . . .
Calculation of the Mixes
Mix Ingredients . . . . . .

Analysis of Mixes . . . . . . . . . .

Determination of Specific Gravity and Actual
Weight per Gallon of the Mixes

Calculation of Specific Gravity and Weight
per Gallon by Formulas . . . . . .

Calculation of Maximum Overrun . . .

Page

10
12
12
12
13

13

14

15

19

 

I a Jun" SIC»

iv

Page

EXPERIMENTAL . . . . . . . . '. . . . . 21
Variation of Weight per Gallon in the Mixes . . . 21
Maximum Overrun . . . . . . . . . . . . 31
DISCUSSION . . . . . . . . . . . . . . . 35
SUMMARY AND CONCLUSIONS . . . . . . . . 39

LITERATURECITED............ 41

 

TABLE

II.

III.

IV.

VI.

VII.

LIST OF TABLES

Page

Weights per Gallon of Eight per cent

Butterfat Mixes . . . . . . . . . . Z3
Weights per Gallon of Ten per cent

Butterfat Mixes . . . . . '. . . 7 . . 25
Weights per Gallon of Twelve per cent

Butterfat Mixes . . . . . . . . . . 27
Weights per Gallon 'of Fourteen per cent

Butterfat Mixes . . . . . . . . . . 29
Maximum Overrun for Eight and Ten

per cent Butterfat Mixes . . . . . . . 32
Maximum Overrun for Twelve and Fourteen

per cent Butterfat Mixes . . . . . . . 33

Average Difference in Weight per Gallon
Values Calculated by Formula Proposed
by Frandsen, _e_t_ a_l_. (1951) from the
Values Determined by Analytical

Methods............36

 

'J. 7.7 .___ 1", —!

TABLE Page
VIII. Average Difference in Weight per Gallon
Values Calculated by Formula Proposed
by Hunziker (1949) from the Values
Determined by Analytical Methods . . . 36
IX. Average Difference in Weight per Gallon

Values Calculated by Formula Proposed

 

by Turnbow, at 11: (1947) from the i
Values Determined by Analytical

Methods............37

IN TRODUC T ION

Today the ice cream industry is faced with regulations
governing the weight of packaged ice cream. The weight of
total food solids and total milk solids of packaged ice cream
have also become included in many regulations. Such regula-
tions were unknown to pioneers of the ice cream industry.

Act Number 208 (1951) recently passed by the Sixty—
sixth Legislature of the State of Michigan controls the commer-
cial production, packaging, and sale of ice cream and related
products in this state. This act placed a minimum weight of
four and five-tenths pounds per gallon on packaged ice cream.
It also required a minimum of 12 per cent milk fat; total food
solids in the proportion of not less than one and six-tenths
pounds per gallan; and total milk solids in the propOrtion of
not less than nine-tenths pounds per gallon of the finished
product. Regulations; such as these have limited the percent—
age of overrun which may be incorporated into the finished
product. Thus, the weight per gallon of a mix must be ob-

tained in order to calculate the maximum overrun which will

2
permit ice cream manufacturers to produce an ice cream that
will meet legal requirements.

Ice cream is a product of variable composition. Unlike
milk, the composition of ice cream is subject to the whims and
fancies of the manufacturer as well as of the consumer. Since
ice cream is heterOgeneous, one would expect the weight per
gallon of mixes to vary depending upon the percentage of the
mix constituents. This variation is due to differences in spe-
cific gravity or weight per unit volume of the ingredients used
in the mix.

Numerous investigators have determined the specific
gravity and weight per gallon of the ingredients commonly used
in the preparation of mixes, but there is a lack of knowledge
concerning the specific gravity and weight per gallon of mixes
of varying compositions.

It was the purpose of this study to determine, if pos-
sible, the Specific gravity and actual weight per gallon of nu—
merous mixes of varying compositions by analytical methods.
Then it was sought to determine the reliability of pr0posed
formulas which have been reported in the literature for cal-

culating the Specific gravity and weight per gallon of any mix

for which the composition is known. It was hoped that these
findings will be of value to the commercial ice cream manu—
facturer in the processing of ice cream to meet various regu-

lations which are now in effect.

REVIEW OF LITERATURE

Regulations Governing Standards for Ice Cream

Standards governing the composition of commercially—
produced ice cream first appeared in the literature during the
years 1915 to 1919. Fisk (1919) listed the standards for dairy
products which were in effect in each state at this time. ' Many
states were found to have no standards whatsoever for ice
cream.

Federal and state standards in effect in 1924 for milk,
butter, and ice cream are listed by Dahle (1927). Most states
had a standard for the minimum butterfat content of ice cream
which varied from seven to 14 per cent. In some instances
there were regulations concerning the minimum percentages of
total solids and total milk solids of the ice cream.

State standards for ice cream compiled by Sommer
(1938) show that all states had limitations for the minimum
butterfat content. The number of states with a minimum per-
centage of total solids or milk solids content for ice cream at

'this time had increased to 10, including Michigan which required

a minimum of one and six—tenths pounds of total food solids
per gallon of finished ice cream. In four states there were
regulations necessitating a minimum weight of four and twenty-
five hundredths pounds per gallon; three states with a minimum
weight of four and five—tenths pounds per gallon; and one state
with a minimum weight of four and seventy—five hundredths
pounds per gallon.

Ice cream standards for 1941, as reported by Turnbow,
Tracy and Raffetto (1947), placed an increased emphasis on
weight per gallon requirements. Only nine states were re—
ported with a requirement of one and six-tenths pounds of total
food solids per gallon; but, 12 states had a weight per gallon
requirement of four and five—tenths pounds per gallon; three
states had a requirement of four and twenty-five hundredths
pounds per gallon; and one state had a requirement of four
and seventy-five hundredths pounds per gallon.

In Michigan, Act Number 208 (1951) was recently passed
by the Sixty-sixth Legislature. This act, which became effec—
tive September 28, 1951, regulates the commercial production,
packaging, and sale of ice cream and related products in this

state. A minimum weight of four and five-tenths pounds per

6
gallon is placed on packaged ice cream. This legislation still
retains the minimum milk fat content of 12 per cent for plain
ice cream, total food solids in the pr0portion of not less than
one and six-tenths pounds per gallon and total milk solids in
the prOportion of not less than nine-tenths pounds per gallon
of the finished product. In the past the only regulations gov-
erning the weight of packaged ice cream in this state were the
above requirements for total food solids and total milk solids.
Thus, this new act will affect the percentage of overrun per—
mitted for ice cream in a new way. Now the maximum per—
centage of overrun permitted in ice cream will be dependent
upon the weight of the mix per gallon rather than the total

food solids and total milk solids content of the mix.

Mea surement of Ove r run

Mechanical methods for measuring overrun reported by
Turnbow, gt El- (1947) include small candy scales and overrun
scales such as the Mojonnier, De Raef, Torsion, and Toledo.

In order to determine the amount of overrun permis-
sible in finished ice cream and yet meet certain weight per

gallon requirements, the following formula as listed by Burke

7
(1933), Sommer (1938), Turnbow, gt _a_l. (1947), and Lucas and
Meiser (1950) is used:

Weight of mix per unit volume -—

Weight of ice cream per unit volume x _ Per cent
Weight of ice cream per unit volume overrun

 

Thus, it is necessary to know the weight per gallon of
a mix to calculate the overrun permitted in any ice cream
which must meet certain weight per gallon standards.

Tables providing the composition and weight per gallon
of dairy products as well as other ingredients used in com-
pounding ice cream mixes have been compiled by Dahle (1927),
Heller (1927), Tracy (1928), Burke (1933), and Lucas, gt a1.
(1950). Variations in weights per gallon of the same products
at a given temperature are often apparent in these tables.

Information concerning the weight per gallon. of mixes
of varying compositions is of a more limited nature or non—
existent. Baer (1927) reported the weight per gallon of sev—
eral mixes of varying compositions. These weights were based
on the total solids content of the mixes with the weight per
gallon of each mix dependent upon the percentage of milk fat
included in the total solids. Heller (1927) listed the calculated

weight per gallon of mixes of varying compositions. His table

provides limited information since only a few mixes of dif-
ferent compositions are listed. Turnbow, e_t a_l. (1947) also
reported the weight per gallon of mixes of varying compositions
but no explanation as to the method used in determining these

value 5 wa 5 given.

Methods of Calculating Weight per Gallon of Mixes

From the literature reviewed concerning the calculation
of the weight per gallon of ice cream mixes, it is apparent
that Sommer (1921) proposed one of the first, if not the first,
formula for calculating what he terms the theoretical weight

per gallon of mixes. His formula is as follows:

 

100 x 8 34 _ weight per gallon
2. fat + 2o snf* + 20 water ° - of mix.
0.93 1.58 1.00

It is assumed in this formula that butterfat has a specific
gravity of 0.93; serum solids, 1.58; and water, 1.00.

Heller (1927) proposed a method for calculating the
weight per gallon of mixes of varying compositions based on
the same principle as that employed by Sommer (1921). Hun—
ziker (1949) reported a similar formula for calculating the

specific gravity of sweetened condensed milk although he adopted

 

* Includes serum solids, sugar, and gelatin.

9
slightly different specific gravity values for use in the formula.
The specific gravity values adOpted by him are as follows:
milk fat, 0.93; milk solids—not-fat, 1.608; and sucrose, 1.589.

Turnbow, e_t fl. (1947) listed a formula for calculating
the weight per gallon of mixes and condensed milk products.
This formula is as follows:

1. Specific gravity 8
(4.87 x % sugar) + (4.41 x 7. msnf) - (0.88'x 7. fat)

- 6.26 -— (T°c - 5)(o.0003)
1,000

2. Weight in pounds per gallon a: Specific gravity x 8.34.
No explanation concerning the source of the many correction
factors used in this formula could be found.

Frandsen and Nelson (1950) reported a formula for the
calculation of the approximate weight per gallon of any mix for

which the composition is known. His formula is as follows:

8.33585
% fat(l.07527) + (7o t.s. - 7o fat)(0.6329) + % water

 

lbs. per gal. mix.
The principle of this formula is based on the specific gravity
of the mix constituents, but the method employed for the cal-
culation of the final result varies from the method prOposed

by Sommer (1921).

PLAN OF EXPERIMENT

From the previous discussion, the need for knowledge
concerning the weight per gallon of mixes of varying composi—
tions has been clearly established. A review of literature dis-
closed only limited information regarding the specific gravity
from which the weight per gallon of the mixes could be calcu-
lated. Most of the available information had to do with only
the specific gravity and weight per gallon of ingredients used
in compounding mixes.

It was the purpose of this study to determine, if pos-
sible, the specific gravity, weight per gallon, and maximum
overrun permitted for mixes of various compositions which
are commonly used in the commercial ice cream industry.
Because mixes are subjected to many varied procedures of
processing, it was apparent that the scope of this study must
be limited to the facilities available on a laboratory scale.
With the above point in mind, the following experimental pro—
cedure was planned:

1. Preparation of mixes.

ll
2. Determination of specific gravity and weight per
gallon.
3. Calculation of Specific gravity and weight per
gallon.
4. Comparison of actual weights per gallon and cal-
culated weights per gallon.

5. Calculation of maximum overrun.

GENERAL PROCEDURES

The following procedures were followed throughout the
experiments. In cases where the procedures listed below were
modified, the modifications are explained under the proper head—

ings in the remainder of the study.

Composition of the Mixes

A series of mixes containing eight, 10, 12, and 14 per
cent butterfat was prepared in 1,000-gram quantities. The milk
solids—not-fat content ranged from eight to 13 per cent; whereas,
the sugar content ranged from 14 to 16 per cent. All mixes
prepared contained three—tenths per cent of a 275 bloom strength
gelatin. Because of their voluminous nature the detailed com-
positions of the 48 mixes included in this study are listed in
Tables I through IV which appear in the Experimental section

that follows.
Calculation of the Mixes

The serum point method was used to calculate the amount

of cream and condensed milk needed for each mix.

13

Mix Ingredients

Heavy sweet cream, 36 per cent, supplied the fat for
the mixes in this experiment. Additional milk solids—not—fat
was supplied by plain condensed Skim milk. Sucrose was used
as the sweetening agent, while the stabilizer consisted of a 275
bloom strength gelatin. The mixes were heated to pasteuriza-
tion temperatures, 1550—160o F. , and homogenized using a
Manton-Gaulin laboratory model homOgenizer with 2,500 pounds
of pressure on the first stage and no pressure on the second
stage. Following homogenization, the mixes were cooled by
placing them under refrigeration at temperatures of 330 to

34° F.
Analysis of Mixes

After the mixes had been homogenized to insure uniform
dispersal of the mix constituents and cooled to approximately
340 F. , they were analyzed for total solids and fat by the Mo—
jonnier method as outlined in Mojonnier and Troy (1925). Trip-
licate analyses for total solids were made. An arithmetical
average was obtained using the two results which were in

closest agreement. This average was then recorded as the

14
final result for total solids. Duplicate determinations were
made for fat. An arithmetical average was obtained and this
value recorded.

Since it was found to be extremely difficult to prepare
mixes that would conform exactly to the desired composition,
a range of variation from the desired composition was set up
for fat and total solids content of the prepared mixes. Mixes
exhibiting variations of more than 0.2 per cent from the de-
sired content for either fat or total solids were discarded and
new mixes prepared that met this standard.

Determination of Specific Gravity and Actual Weight
per Gallon of the Mixes

After the results of the Mojonnier analysis showed each
mix to be within the limitations as set forth for fat and total
solids content, a lO-milliliter sample of each mix was taken.
The mix samples were held in a water bath at 140—150 C. to
insure a uniform temperature at the time of weighing. Each
sample was then placed in a previously-weighed lO-milliliter
volumetric flask and the difference between the weight of the
flask and the total weight of the flask and sample recorded.

Samples of each mix were weighed until two weights were

15

obtained which differed by less than 0.001 gram. An arith-
metical average weight was taken using these two samples.

The specific gravity for each sample was determined
by dividing the weight of the sample by the weight of an equal
volume of water. All calculations were made on a Friden
calculator and the results recorded to include the first three
decimal places.

The weights per gallon of the mixes were obtained by
multiplying the specific gravity by 8.337, the weight of one
gallon of water at 150 C., as listed by The Handbook of Chem-
istry and Physics (1943). These calculations were also made
on a Friden calculator. The results in this case were re-
corded to include only the first two decimal places.

Calculation of Specific Gravity and Weight
per Gallon by Formulas
Hunziker (1949) lists the following formula for calcu-

lating the Specific gravity of sweetened condensed milk:

 

100 specific gravity
2, fat 2, msnf Z, sugar 2 of sweetened
+ + + % water condensed milk

5 . r. sp. gr. sp. gr.
p g at 600 F.

16
By using the modification which is listed below, this
formula was used to calculate the specific gravity of each mix.
100

2o fat + in msnf + 20 sugar + E stgalb. + % water

sp. gr. sp. gr. sp. gr. Sp.

specific gravity of mix at 600 F.

The values which Hunziker (1949) adepted for use in the
Specific gravity formula are: milk fat, 0.93, as reported by
Richmond (1920) and Fleischmann (1908); milk solids-not-fat,
1.608, an average of the results reported by Richmond (1920)
and Fleischmann (1908); sucrose, 1.589, as reported by Browne
and Zerban (1941).

Since sweetened condensed milk contains no stabilizer,
a specific gravity value for gelatin had to be incorporated in
the formula. Larson and Lucas (1940) obtained a specific
gravity of 1.5384 for a gelatin suspension which was subse-
quently included in the formula pr0posed by Hunziker (1949).

Although the above specific gravity values were utilized
throughout the experiment, it is interesting to note that nurner—
ous investigators do not agree as to the Specific gravity of

mix constituents. The following table records their findings:

17

 

 

Aoooovwmmm A

Goosoomo .H Aooomvomom A

80333 .2 80383 4

Gomsowmm 4 |

800333 .H Gooamws .2

8003mm. .o
Aoomsoma .o
Eoflsoow .o

803:; .o

38: Seam s 98.8

8g: 308232

2.3: 5:3

3.8: «mama

“ova: mdodd ow Comamd

 

5330

omonosm v.52

warm

 

manogfimsou x32 mo 3ng0 330on

m .H cumwfim oz:

 

 

18
The formula proposed by Turnbow, e_t 9.1; (1947) and
used in this study is as follows:
1. Specific gravity =
(4.87 x % sugar) + (4.41 x 70 msnf) — (0.88 x 7o fat)

— 6.26 — (TOC - 5)(o.ooo3)
1,000

2. Weight in pounds per gallon = Specific gravity x 8.34.
The formula proposed by Frandsen, St 532- (1950) and
used in this study is as follows:

8.33585
% fat(l.07527) + (7. t.s. - % fat)(0.6329) + 7. water

lbs. per gal. mix.

The weights per gallon of the mixes were calculated
using the above formulas in order to obtain a comparison of
the values. The fat and total solids values used in these
formulas are those obtained by the Mojonnier analysis. Since
the sugar and gelatin were weighed independently of the mix
these values were assumed to be those originally calculated.
The percentage milk solids—not—fat was determined by Subtract-
ing the total per cent of sugar, fat, and gelatin from the total
solids as determined by Mojonnier analysis.

All calculations involving the use of these formulas were

made on a Friden calculator. The results that include Specific

l9
gravity values were recorded to include only the first three
decimal places; whereas, the weight per gallon of each mix

was recorded to include only the first two decimal places.
Calculation of Maximum Overrun

According to the standards set forth by Act Number 208
(1951), ice cream to be legally sold in Michigan must meet the
following requirements:

1. Shall weigh not less than four and five—tenths pounds

per gallon;

2. V Shall contain:

a. Not less than 12 per cent of milk fat;

b. Total food solids in the proportion of not less
than one and six-tenths pounds per gallon and
total milk solids in the prOportion of not less
than nine—tenths pounds per gallon of finished
product.

These requirements do not pertain to fruit, nut, or chocolate
ice cream.
The maximum overrun, which permits the finished

product to meet the above requirements, for the series of

20
mixes containing 12 and 14 per cent fat was calculated using
the following formula:

Weight of mix per unit volume —-

Weight of ice cream per unit volume x 100 __ Per cent
Weight of ice cream per unit volume - overrun

 

This is the formula for the calculation of overrun that is listed

by Turnbow, e_t a_l_. (1947), Sommer (1938), and others.

EXPERIMENTAL

Variation of Weight per Gallon in Mixes

Since it is known that ice cream mixes are of a heter-
ogeneous nature, one would expect the weight per unit volume
or weight per gallon to vary according to the composition. The
amount of variation in weight is a result of the differences in
specific gravities of the constituents which are used in com-
pounding the mix. To determine the variation in weight per
gallon produced by various percentages of mix constituents, the
following experiment was conducted.

Mixes containing from eight to 14 per cent butterfat
were prepared in the laboratory. The milk solids-not—fat
content of these mixes was varied from eight to 13 per cent
to determine the effect of this component on the weight per
gallon of each mix. The variation in sugar content of the
mixes ranged from 14 to 16 per cent because most commer-
cially-prepared mixes contain a similar amount of sugar. The
amount of gelatin utilized in each mix was three-tenths per

cent. This constituent was not varied because it is present

22
in all mixes in such quantities that its effect upon the weight
per gallon is of minor importance.

A total of 48 mixes of varying compositions were pre-
pared for this study. The specific gravity and weight per gallon
of each mix was determined in the laboratory by previously-
described methods. Since it would take too much space to de-
scribe all the variations in mixes included, the composition of
each mix as determined by Mojonnier analysis and the results
of the analytical determinations for specific gravity and weight
per gallon are recorded in Tables I, II, III, and IV.

These tables also include the calculated values for the
weight per gallon of the mixes as obtained by the formulas
proposed by Hunziker (1949), Frandsen, _e_t_ _a_1_§ (1951), and Turn-—
bow, gt a_l. (1947). Formula calculations were based on the
compositions of the mixes as determined by Mojonnier analysis.

Due to the limited Space available for listing the data in
tabular form, the following abbreviations are utilized throughout

the subsequent table 5:

A_ - Values obtained by analytical techniques.

E: - Values obtained using the formula proposed by Frand—
sen, gt 31. (1950).

{-1 -'Values obtained using the formula proposed by Hunziker
(1949).

I - Values obtained using the formula prOposed by Turn-

bow, 91 a_1. (1947).

TABLE I

WEIGHTS PER GALLON OF EIGHT PER CENT
BUTTERFAT MIXES

23

 

 

 

Meth- Mix 7o 79 % % Sp. Lbs. Difference

od* No. Fat Msnf Sugar T.S. Gr. 5:: from A.
A 1 8.00 9.95 14.0 32.25 1.085 9.04

F 1.091 9.09 +0.05
H 1.092 9.10 +0.06
T 1.098 9.15 +0.11
A 2 8.03 10.90 14.0 33.23 1.090 9.08

F 1.094 9.12 +0.04
H 1. 096 9. 13 +0. 05
T 1.102 9.19 +0.11
A 3 8.08 11.83 14.0 34.21 1.096 9.13

F 1.098 9.15 +0.02
H 1.100 9.17 +0.04
T 1.106 9.22 +0.09
A 4 8.09 13.01 14.0 35.40 1.100 9.17

F 1.104 9.20 +0.03
H 1.106 9.22 +0.05
T 1.112 9.27 +0.10
A 5 7.81 10.13 15.0 33.24 1.090 9.08

F 1.096 9.13 +0.05
H 1.097 9.14 +0.06
T 1.104 9.20 +0.12
A 6 7.93 11.10 15.0 34.33 1.096 9.13

F 1.099 9.16 +0.03
H 1.102 9.18 +0.05
T 1.108 9.24 +0.11

I

24

TAB LE I (Continue (1)

 

 

Lbs.

 

Meth- Mix “/6 7o ‘7. 70 Sp. Difference
od* No. Fat Msnf Sugar T.S. Gr. 5:: from A.

A 7 7.91 12. 11 15.0 35.21 1.098 9.15

F 1. 104 9.20 +0.05
H 1.105 9.21 +0.06
T 1.113 9. 28 +0.13
A 8 8.04 12.97 15.0 36.31 1.104 9.20

F 1.108 9.23 +0.03
H 1.110 9.25 +0.05
T 1.116 9.30 +0. 10
A 9 8.17 9.82 16.0 34.29 1.094 9.12

F 1.098 9. 15 +0.03
H 1.100 9. 17 +0.05
T 1.107 9.23 +0. 11
A 10 8.15 10.97 16.0 35.42 1.097 9. 14

F 1. 104 9.20 +0.06
H 1.105 9.21 +0.07
T 1.112 9.27 +0.13
A 11 8.12 11.98 16.0 36.40 1.102 9.18

F 1.108 9.23 +0.05
H 1.110 9.25 +0.07
T 1.117 9.31 +0. 13
A 12 8. 13 13.01 16.0 37.44 1.107 9.22

F 1.112 9.27 +0.05
H 1. 115 9.29 +0.07
T 1. 121 9.34 +0. 12

* A, Obtained by analytical methods; _I_‘_, Calculations by
Frandsen's, e_t. 31. (1950) formula; H, Calculations by Hunziker's
(1949) formula; I, Calculations by Turnbow's, e_t 31. (1947)

formula.

WEIGHTS

PER GALLON OF TEN PER CENT

TABLE II

BUTTERFAT MIXES

 

 

 

Meth- Mix 7o 76 % % Sp. Lbs. Difference
od* No. Fat Msnf Sugar T.S. Gr. 5:: from A.

A 13 9.98 10.00 14.0 34.28 1.084 9.03

F 1.088 9.07 +0.04
H 1.090 9.08 +0. 05
T 1.097 9.14 +0.11
A 14 10.08 10.74 14.0 35.12 1.089 9.07

F 1.092 9. 10 +0.03
H 1.094 9. 12 +0. 05
T 1.100 9.17 +0.10
A 15 10.14 11.99 14.0 36.43 1.093 9.11

F 1.097 9. 14 +0.03
H 1.099 9. 16 +0.05
T 1.105 9.21 +0. 10
A 16 10.13 12.92 14.0 37.35 1.097 9.14

F 1. 102 9. 18 +0.04
H 1.103 9.19 +0.05
T 1. 109 9.24 +0. 10
A 17 9.85 10.30 15.0 35.45 1.086 9.05

F 1.094 9. 12 +0.07
H 1.096 9.13 +0.08
T 1.103 9.19 +0.14
A 18 10.00 10.87 15.0 36.17 1.092 9.10

F 1. 100 9. 17 +0.07
H 1. 102 9. 18 +0.08
T 1.105 9.21 -+0. 11

f

TABLE II (Continue (1)

26

 

 

 

Meth- Mix ‘70 7o ‘7. % Sp. Lbs. Difference

od* No, Fat Msnf Sugar T.S. Gr. 5:: from A.
A 19 9.95 12.02 15.0 37.27 1.096 9.13

F 1.102. 9.18 +0.05
H 1.104 9.20 +0.07
T 1.111 9.26 +0.13
A 20 10.05 12.78 15.0 38.13 1.100- 9.17

F 1.105 9.21 +0.04
H 1.107 9.22 +0.05
T 1.114 9.29 +0.12
A 21 9.98 10.02 16.0 36.30 1.091 9.09

F 1.098 9.15 +0.06
H 1.099 9.16 +0.07
'r 1.107 9.23 +0.14
A 22 10.01 11.07 16.0 37.38 1.097 9.14

F 1.102 9.18 +0.04
H 1.104 9.20 +0.06
T 1.111 9.26 +0.12
A 23 10.12 11.94 16.0 38.36 1.101 9.17

F 1.106 9.22 +0.05
H 1.108 9.23 +0.06
T 1.115 9.29 +0.12
A 24 9.93 12.95 16.0 39.18 1.106 9.22

F 1.111 9.26 +0.04
H 1.113 9.27 +0.05
T 1.120 9.34 +0.12

 

 

* A, Obtained by analytical methods; _F__, Calculations by
Frandsen's, gt 11. (1950) formula; _I_-i_, Calculations by Hunziker's
(1949) formula; I, Calculations by Turnbow's, e_t 31. (1947)

f ormula.

TABLE III

WEIGHTS PER GALLON OF TWELVE PER CENT
BUTTERFAT MIXES

27

 

 

Lbs.

 

Meth- Mix % 7o ‘76 ‘76 Sp. Difference
od* No. Fat Msnf Sugar T.S. Gr. 5:: from A.

A 25 12. 01 10.04 14.0 36.35 1.082 9. 02

F 1.087 9.06 +0.04
H 1.089 9.07 +0.05
T 1.095 9.13 +0. 11
A 26 12.04 11.10 14.0 37.44 1.086 9.05

F 1.092 9. 10 +0.05
H 1.093 9. 11 +0.06
T 1.100 9.17 +0. 12
A 27 11.97 11.98 14.0 38.25 1.091 9. 09

F 1.096 9. 13 +0.04
H 1.097 9. 14 +0.05
T 1. 104 9. 20 +0. 11
A 28 11.97 13.13 14.0 39.40 1.095 9.12

F 1. 100 9.17 +0.05
H 1. 103 9.19 +0.07
T I. 109 9.24 +0. 12
A 29 11.80 10.07 15.0 37. 1.7 1.085 9. 04

F 1.092 9.10 +0.06
H 1.093 9. 11 +0.07.
T 1.100 9.17 +0.13
A 30 11.95 10.99 15.0 38.24 1.091 9.09

F ' 1.096 9.13 +0.04
H 1.097 9.14 +0.05
T 1. 104 9.20 +0. 11

 

TABLE III (Continued)

28

 

 

 

Meth- Mix % 79 7o % Sp. Lbs. Difference

od* No. Fat Msnf Sugar T.S. Gr. (‘3’: from A.
A 31 12.10 11.84 15.0 39.24 1.095 9.12

F 1.099 9.16 +0.04
H 1.101 9.17 +0.05
T 1.108 9.24 +0.12
A 32 12.13 12.95 15.0 40.38 1.101 9.17

F 1.104 9.20 +0.03
H 1.106 9.22 +0.05
r 1.113 9.28 +0.11
A 33 12.01 10.08 16.0 38.39 1.092 9.10

F 1.096 9.13 +0.03
H 1.098 9.15 +0.05
'r 1.105 9.21 +0.11
A 34 12.00 11.17 16.0 39.47 1.097 9.14

F 1.100 9.17 +0.03
H 1.103 9.19 +0.05
'1' 1.110 9.25 +0.11
A 35 12.03 12.01 16.0 40.34 1.101 9.17

F 1.104 9.20 +0.03
H 1.107 9.22 +0.05
T 1.114 9.29 +0.12
A 36 12.01 13.11 16.0 41.42 1.106 9.22

F 1.110 9.25 +0.03
H 1.112 9.27 +0.05
T 1.118 9.32 +0.10

 

 

* A, Obtained by analytical methods; E, Calculations by
Frandsen's, _e_t_ 31. (1950) formula; _1_-I__, Calculations by Hunziker's
(1949) formula; _T_, Calculations by Turnbow's, e_t a_l. (1947)
formula.

29

 

 

 

TABLE IV
WEIGHTS PER GALLON OF FOURTEEN PER CENT
BUTTERFAT MIXES
Meth— Mix % % 7o % Sp. Lbs. Difference
od* No. Fat Msnf Sugar T.S. Gr. 38:. from A.

a .
A 37 13.80 8.24 14.0 36. 34 1.071 8.92
F 1. 078 8.98 +0. 06
H 1.079 8.99 +0.07
T 1.086 9.05 +0. 13
A 38 14.06 9.14 14.0 37.50 1.076 8.97
F 1.081 9.01 +0.04
H 1.083 9.02 +0.05
T 1.089 9.08 +0. 11
A 39 14.04 10.00 14.0 38.38 1.080 9.00
F 1.085 9.04 +0. 04
H 1.087 9.06 +0.06
T 1.093 9.11 +0. 11
A 40 14.07 11.11 14.0 39.48 1.086 9.05
F 1.090 9. 08 +0. 03
H 1.092 9.10 +0.05
T 1.098 9. 15 +0. 10
A 41 14.02 7.80 15.0 37.12 1.073 8.94
F ' 1.080 9.00 +0. 06
H 1.081 9.01 +0.07
T 1.088 9.07 +0. 13
A 42 13.82 9.16 15.0 38.28 1.079 8.99
F 1.086 9. 05 +0.06
H 1.087 9.06 +0.07
T 1.095 9. 13 +0. 14

 

TABLE IV (Continued)

30

 

 

Lbs.

 

Meth- Mix '76 % 7o 70 Sp. Difference
od* No. Fat Msnf Sugar T.S. Gr. 5:: from A.

A 43 13.89 10.19 15.0 39.38 1.084 9.03

F 1.091 9.09 +0.06
H 1.092 9.10 +0.07
T 1.099 9.16 +0. 13
A 44 14.16 11.03 15.0 40.49 1.088 9.07

F 1.094 9. 12 +0.05
H 1.096 9. 13 +0.06
T 1.102 9.19 +0.12
A 45 14. 12 7.89 16.0 38.31 1.080 9.00

F 1.085 9.04 +0.04
H 1.086 9.05 +0.05
T 1.094 9. 12 +0. 12
A 46 14.20 8.99 16.0 39.49 1.083 9.02

F 1.090 9.08 +0.06
H 1.091 9.09 +0.09
T 1.098 9.15 +0. 13
A 47 14.07 10.03 16.0 40.40 1.090 9.09

F 1.094 9.12 +0.03
H 1.096 9.13 +0.04
T 1.103 9.19 +0. 10
A 48 14.04 10.95 16.0 41.29 1.095 9. 12

F 1.098 9. 15 +0.03
H 1.100 9. 17 +0.05
T 1. 107 9.23 +0. 11

 

 

* A, Obtained by analytical methods; E, Calculations by

Frandsen's, e_t a_1. (1950) formula; I_-I_, Calculations by Hunziker's

(1949) formula; _T_, Calculations by Turnbow’s, _e_t a_1. (1947)

formula.

31

Maximum Ove r run

Maximum overrun in this study refers to the amount of
air which can be incorporated into an ice cream mix and still
meet the legal minimum weight in the State of Michigan of four
and five-tenths pounds per gallon. Today maximum overrun is
of vital importance to the commercial ice cream manufacturers
since the industry is faced with regulations governing the weight
per gallon of finished ice cream. To provide the industry with
overrun information for mixes of varying compositions, Tables
V and VI have been prepared.

Table V gives the specific gravity, weight per gallon,
and the maximum overrun for various mixes containing eight
and 10 per cent butterfat. This table is of little importance
to the commercial ice cream manufacturers in Michigan be—
cause the butterfat content of the mixes listed is below the
minimum requirement of Act Number 208 (1951). In states
that have lower minimum butterfat requirements, this informa—
tion should be of value.

Table VI contains the same information as Table V
except that the various mixes listed contain 12 and 14 per

cent butterfat; thus, the overrun information provided in this

MAXIMUM OVERRUN FOR EIGHT AND TEN

TABLE V

PER CENT BUTTERFAT MIXES*

32

 

 

 

Mix' 7 7o 7» % Sp: ”’5' M 7’"

N . F t M nf s T.S. G . 9"" ammum
o a S ugar r Gal. Overrun
1 '8.0 10.0 14.0 32.30 1.091 9.09 102.0
2 8.0 11.0 14.0 33.30 1.094 9.12 102.6
3 8.0 12.0 14.0 34.30 1.099 9.16 103.5
4 8.0 13.0 14.0 35.30 1.104 9.20 104.4
5 8.0 ‘10.0 15.0 33.30 1.094 9.12 102.6
6 8.0 11.0 15.0 34.30 1.099 9.16 103.5
7 8.0 12.0 15.0 35.30 1.104 9.20 104.4
8 8.0 13.0 15.0 36.30 1.109 9.24 105.3
9 8.0 10.0 16.0 34.30 1.099 9.16 103.5
10 8.0 11.0 16.0 35.30 1.104 9.20 104.4
11 8.0 12.0 16.0 36.30 1.109 9.24 105.3
12 8.0 13.0 16.0 37.30 1.112 9.27 106.0
13 10.0 10.0 14.0 34.30 1.088 9.07 101.5
14 10.0 11.0 14.0 35.30 1.093 9.11 102.4

15 10.0 12.0 14.0 36.30 1.098 9.15 103.3
16 10.0 13.0 14.0 37.30 1.102 9.18 104.0
17 10.0 10.0 15.0 35.30 1.093 9.11 102.4
18 10.0 11.0 15.0 36.30 1.098 9.15 103.3
19 10.0 12.0 15.0 37.30 1.102 9.18 104.0
20 10.0 13.0_ 15.0 38.30 1.106 9.22 104.8
21 10.0~ 10.0 16.0 36.30 1.098 9.15 103.3
22 10.0 11.0 16.0 37.30 1.102 9.18 104.0
23 10.0 12.0 16.0 38.30 1.106 9.22 104.8
24 10.0 13.0 16.0 39.30 1.111 9.26) 105.7

 

 

formula prOposed by Frandsen, _e_t a_1. (1951).
include 0.30 per cent gelatin.

*Maximurn overrun refers to the overrun which produces
finished ice cream that will weigh 4.5 pounds per gallon.
culations for weight per gallon of the mixes are based upon the
The total solids

Cal-

TABLE VI

PER CENT BUTTERFAT MIXES*

33

MAXIMUM OVERRUN FOR TWELVE AND FOURTEEN

 

 

 

Mix 7. 7» s % Sp. Lbs" 7°
No. Fat Msnf Sugar T. S. Gr. per Max1mum
Gal. Overrun
25 12.0 10.0 14.0 36.30 1.087 9.06 101.3
26 12.0 11.0 14.0 37.30 1.091 9.09 102.0
27 12.0 12.0 14.0 38.30 1.096 9.13 102.8
28 12.0 13.0 14.0 39.30 1.100- 9.17 103.7
29 12.0 10.0 15.0 37.30 1.091 9.09 102.0
30 12.0 11.0 15.0 38.30 1.096 - 9.13 102.8
31 12.0 12.0 15.0 39.30 1.100 9.17 103.7
32 12.0 13.0 15.0 40.30 1.104 9.20 104.4
33 12.0 10.0 16.0 38.30 1.096 9.13 102.8
34 12.0 11.0 16.0 39.30 1.100 9.17 103.7
35 12.0 12.0 16.0 40.30 1.104 9.20 104.4
36 12.0 13.0 16.0 41.30 1.109 9.24 105.3
37 14.0 8.0 14.0 36.30 1.076 8.97 99.3
38 14.0 9.0 14.0 37.30 1.081 9.01 100.2
39 14.0 10.0 14.0 38.30 1.085 9.04 100.8
40 14.0 11.0 14.0 39.30 1.090 9.08 101.7
41 14.0 8.0 15.0 37.30 1.081 9.01 100.2
42 14.0 9.0 15.0 38.30 1.085 9.04 100.8
43 14.0 10.0 15.0 39.30 1.090 9.08 101.7
44 14.0 11.0 15.0 40.30 1.094 9.12 102.6
45 14.0 8.0 16.0 38.30 1.085 9.04 100.8
46 14.0 9.0 16.0 39.30 1.090 9.08 101.7
47 14.0 10.0 16.0 40.30 1.094 9.12 102.6
48 14.0 11.0 16.0 41.30 1.098 9.15 103.3

 

 

formula preposed by Frandsen, §_t_ a_1. (1951).
include 0.30 per cent gelatin.

* Maximum overrun refers to the overrun which produces
finished ice cream that will weigh 4.5 pounds per gallon.
culations for weight per gallon of the mixes are based upon the
The total solids

Ca1—

34
table applies to ice cream meeting the requirements of Act
Number 208 (1951).

The total food solids and the total milk solids require—
ments per gallon do not have to be considered in these calcu-
1ations since it was found that any mix containing a minimum
of 12 per cent fat, 10 per cent serum solids, and 14 per cent
sugar which is frozen into ice cream weighing four and five-
tenths pounds per gallon will exceed these requirements. The
same holds true for the series of mixes containing 14 per cent
fat.

The calculations for specific gravity and weight per gal—
1on of the mixes included in these tables were made using the
formula prOposed by Frandsen, e_t_ a_1. (1951) since previous ob-
servation from this study found it to be the most accurate of
the formulas included in this investigation. All calculations
for maximum overrun were made as described under General

Procedures.

 

DISCUSSION

In the early part of this investigation, it was established
that the weight per gallon of ice cream mixes varied. Further
study indicated a range in weight variation between eight and
ninety—seven hundredths pounds per gallon for a mix containing
14 per cent fat, eight per cent milk solids—not—fat, 14 per cent
sugar, and three—tenths per cent gelatin to nine and twenty-
seven hundredths pounds per gallon for a mix containing eight
per cent fat, 13 per cent milk solids-not—fat, 16 per cent sugar,
and three-tenths per cent gelatin.

It was also noted that the mix which weighed nine and
twenty-seven hundredths pounds per gallon contained 37.30 per
cent total solids whereas the mix which weighed eight and
ninety—seven hundredths pounds per gallon contained 40.30 per
cent total solids. Thus, the weight per gallon of ice cream
mixes does not always increase as the percentage total solids
is increased.

Observations made from the studies concerning the de—
termination of weight per gallon of a mix Show that there is

close agreement between the results of the analytical method

36

of determination and the calculated results obtained using the

formula preposed by Frandsen, gt a_1. (1951) and Hunziker

(1949).

A comparison of the arithmetical differences of these

calculated weights per gallon from the analytical determinations

are listed in the following tables:

TABLE VII

 

 

Average Difference in Weight per Gallon Values Calculated by
Formula Proposed by Frandsen, 51 94. (1951) from the

Values Determined by Analytical Methods

 

 

Lbs./Gal.

1. Mixes containing 8 per cent fat +0.040

2. Mixes containing 10 per cent fat +0.046

3. Mixes containing 12 per cent fat +0.039

4. Mixes containing 14 per cent fat +0.043
Combined average difference for all mixes +0.043

 

 

TAB LE VIII

 

 

Average Difference in Weight per Gallon Values Calculated by
Formula Preposed by Hunziker (1949) from the

Values Determined by Analytical Methods

 

 

Lbs./Ga1.

1. Mixes containing 8 per cent fat +0.056

2. Mixes containing 10 per cent fat +0.060

3. Mixes containing 12 per cent fat +0.054

4. Mixes containing} 14 per cent fat +0.059
Combined average difference for all mixes +0.05?

 

 

37
A comparison of the results obtained when calculating
the weight per gallon of the mixes used in this investigation
by the formula prOposed by Turnbow, §_t_ a_1. (1947) indicated
that this formula gave consistently higher results than those
resulting from the formulas pr0posed by Frandsen, at El. (1951)
and Hunziker (1949). A summary of these findings is as fol-
lows:

TABLE IX

 

 

Average Difference in Weight per Gallon Values Calculated by
Formula Proposed by Turnbow, e_t a_1. (1947) from the
Values Determined by Analytical Methods

 

Lbs. /Gal.

 

l. Mixes containing 8per cent fat . . . . +0.113

2. Mixes containing 10 per cent fat . . . . +0. 117
3. Mixes containing 12 per cent fat . . . . +0. 114
4. Mixes containing 14 per cent fat . . . . +0.119
Combined average difference for all mixes . . . +0.116

 

 

Since the primary purpose of this study was to find the
most accurate formula for the calculation of weight per gallon
of ice cream mixes, it can be stated that the formula pr0posed
by Frandsen, _e_t a_1. (1951) is the most accurate of those in-

cluded in this investigation. Therefore this formula was used

38
in the calculation of weight per gallon of the mixes included in
the maximum overrun tables.

Of the mixes studied, the maximum overrun which per-
mits finished ice cream to weigh four and five—tenths pounds
per gallon varied from a minimum of 99.3 per cent for the
mix that weighed eight and ninety—seven hundredths pounds per
gallon to a maximum of 106.0 per cent for the mix that weighed
nine and twenty-seven hundredths pounds per gallon. Since a
larger percentage of overrun can be incorporated into the mix
containing eight per cent fat and still meet the weight per gal—
lon requirement of four and five—tenths pounds, it is evident

that Act Number 208 penalizes the manufacturer of high fat

mixe s.

SUMMARY AND CONCLUSIONS

1. The weight of ice cream mixes studied varied from
eight and ninety-seven hundredths pounds per gallon to nine and
twenty-seven hundredths pounds per gallon depending upon the

composition.

2. Weights per gallon of ice cream mixes calculated
by the formulas prOposed by Frandsen, e_t 11. (1951), Hunziker
(1949), and Turnbow, _e_t_ 31. (1947) do not agree for mixes of

the same compo siti on.

3. Arithmetical averages of the values obtained using
the formula proposed by Turnbow, _e_t a_1. (1947) exhibited the

greatest deviation from the analytical values.

4. Values calculated by the formulas prOposed by Frand—
sen, gjg a_1. (1951) and Hunziker (1949) were in close agreement.
Frandsen's, §_t_ a_1. (1951) formula appeared to be the more ac-
curate of the two since it was within forty-three thousandths

pounds of the analytical results.

40
5. The range for maximum overrun varied from 99.3
per cent for a 14 per cent fat, eight per cent milk solids—not-
fat, 14 per cent sugar, and three—tenths per cent gelatin mix
to 106.0 per cent for an eight per cent fat, 13 per cent
milk solids—not—fat, 16 per cent sugar, and three-tenths per

cent gelatin mix.

6. Manufacturers of high fat content mixes are penal—

ized by Act Number 208.

7. Increasing the total solids content of ice cream

mixes does not guarantee an increase in the weight per gallon.

8. Tables are presented which give the weight per gal—
lon and maximum overrun for mixes which contain from eight
to 14 per cent fat with variations in milk solids—not—fat and

sugar.

LITERATURE CITED

1951. Act No. 208. Public Acts of 1951, State of

Michigan.
Baer, A. C.
1927. The Preparation and Processing of Ice Cream
Mix. The Olsen Publishing Co. , Milwaukee,
Wis. I

Bailey, D. E.
1919. Study of the Babcock Test for Butterfat in Milk.
Jour. Dairy Sci., 2: 331-373.

Browne, C. A., and F. W. Zerban.
1941. Physical and Chemical Methods of Sugar Anal-
ysis. 3rd Ed. John Wiley and Sons, Inc.,
New York, N. Y.

Burke, H. D.
1933. Practical Ice Cream Making and Practical Mix
Tables. The Olsen Publishing Co., Milwaukee,
Wis.

Dahle, C. D.
1927. A Manual for Ice Cream Makers. The Loyless
Publishing Co., Atlanta, Ga.

Fisk, W. W.
1919. The Book of Ice Cream. The Macmillan Co.,
New York, N. Y.

Fleischmann, W.
1908. Lehrbuch der Milchwirtschaft. 4th Ed. (Orig-
inal not seen).

Frandsen, J. H., and D. H. Nelson. ,
1951. Ice Cream and Other Frozen Desserts. lst Ed.
Published by J. H. Frandsen, Amherst, Mass.

10.

11.

12.

13.

14.

15.

16.

17.

18.

19.

42

1943. Handbook of Chemistry and Physics. 27th Ed.
Chemical Rubber Publishing Co. , Cleveland,
Ohio.

Heller, B.
1927. Heller's Guide for Ice-Cream Makers. 7th Ed.
B. Heller and Co., Chicago, Ill.

Hunziker, O. F.
1949. Condensed Milk and Milk Powder. 7th Ed.
Published by the author, La Grange, Ill.

Lange, N. A.
1934. Handbook of Chemistry. Handbook Publishers,
Inc., Sandusky, Ohio.

Larson, R. A., and P. 5. Lucas.
1940. A Method for Calculating the Baurne Reading
of Condensed Ice Cream Mixes. Jour'. Dairy
Sci. 23: 229-244.

Lucas, P. S., and J. A. Meiser, Jr.
1950. The Chemical and Physical Control of Dairy
Products. A Laboratory Manual. Michigan
State College Press, East Lansing, Mich.

Mojonnier, T., and H. C. Troy.
1925. The Technical Control of Dairy Products. 2nd
Ed. Mojonnier Brothers Co., Chicago, 111.

Richmond, H. D.
1920. Dairy Chemistry. 3rd. Ed. (Original not seen).

Sharp, P. F., and R. H. Hart.
1936. The Influence of the Physical State of the Fat
on the Calculation of Solids from the Specific
Gravity of Milk. Jour. Dairy Sci. 19: 683-695.

Sommer, H. H.
1921. Methods of Calculating Ice Cream Mixes. Jour.
Dairy Sci., 4: 401-415.

20.

21.

22.

43

 

1938. The Theory and Practice of Ice Cream Making.
3rd. Ed. Published by the author, Madison,
Wis.

Tracy, P. H.
1928. Standardization of Ice Cream Mixes. Univ.
Ill. Agr. Expt. Sta. Cir. 323.

Turnbow, G. D., P. H. Tracy, and L. A. Raffetto.
1947. The Ice Cream Industry. 2nd Ed. John Wiley
and Sons, Inc., New York, N. Y.

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