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An in-depth look into the continuous bread baking system, a mechanized approach to bread production that replaced bulk fermentation. The article covers the equipment used, the process of dough development, and the differences between continuous and conventional bread. It also discusses the advantages and disadvantages of continuous baking and its impact on the baking industry.
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B. L. D'Appolonia
Bread baking is an art which has been recog nized for many years. The final test for quality evaluation of hard red spring or hard red winter wheat varieties is the bread baking test. To be ac ceptable quality-wise, a new variety of wheat must
Dr. D'Appolonia is assistant professor , Department of Cereal Chemistry and Technology.
January - February, 1972
undergo numerous quality determinations. Such measurements would include properties related to the kernel itself, milling evaluation, physical dough characteristics and bread baking properties. The last of these measurements, bread baking proper ties, is of extreme importance from a quality stand point. A potential new variety of wheat must be capable of producing a loaf of bread of acceptable quality according to certain specified industry standards.
Commercial bread baking has undergone sev eral advances in the past 15-20 years. Conventional baking can be divided basically into two different procedures: the straight dough, or the sponge and dough procedure. Both of these processes depend on bulk fer mentation; that is, yeast fermentation. The straight dough procedure differs from the sponge and dough procedure in that all of the ingredients are mixed at the outset to form a dough suitable to pro duce a loaf of bread. This dough is then allowed to ferment for a definite period of time prior to going through the make-up equipment, into the pan to rise, and then into the oven to bake. The sponge and dough process involves two steps. The first step, called the “ sponge” , involves mixing 60- per cent of the total flour with yeast and water to form a mass of dough but not to develop the gluten. The “ sponge” is then allowed to ferment for a per iod of from 4-12 hours. The second step involves returning the sponge to the mixer, adding the re maining ingredients, and mixing to form a homo geneous mass of developed dough. This dough then goes through the make-up equipment, into the pans and then into the oven. Many advances have taken place in convention al baking, including the use of high speed hori zontal mixers as well as developments in other pieces of machinery, such as dividers, rounders, overhead proofers and molders. In addition to ad vances in the process itself, research has been con ducted on the use of such ingredients as emulsifi ers, yeast foods, dough conditioners, enzyme sup plements, and oxidizing and reducing agents in bread baking. Such ingredients serve specific pur poses and help produce a loaf of bread acceptable to the general public.
The Continuous Bread Baking Process The introduction in the early 1950’s of the continuous bread baking system in the United Sta tes has resulted in further mechanization and ac celerated bread production. The primary difference between continuous baking and conventional baking is that in the for mer the dough undergoes a rapid mechanical de velopment which replaces the bulk fermentation of the conventional bread system. Commercially in the United States, two con tinuous bread systems are in operation, the Do- Maker and the Amflow units. Both of these proces ses are designed to feed continuously the necessary ingredients of the baker’s formula to a mixing de vice. At this stage, the ingredients are mixed to gether to form a homogenous mass of dough which then passes on to a dough pump which delivers the
dough to the developing apparatus. The developer is the most important part of the system. Here the mechanical development is obtained to produce a dough of proper structure and gas retention proper ties. From the developer, the dough is continuously extruded and divided into the proper weight into the pans moving on a conveyor below the divider. The mechanical details of these two processes differ, but both operate in a continuous manner. At the Department of Cereal Chemistry and Technology, a laboratory model continuous baking system has been installed and currently is in oper ation. This system is a laboratory scale of the com mercial DoMaker system. Since the laboratory unit is employed to evaluate different samples of flour, there is not a continuous flow of ingredients that is found in commercial practice. In this respect, the system is batchwise since a transfer of broth and premixed dough takes place by hand for each var iety under test. Mechanical development of the dough, however, is achieved and every attempt is made to approximate commercial conditions. The present discussion centers on the continu ous baking equipment in the Department of Cereal Chemistry and Technology. The three basic elements of this system are:
Fig. 3. Continuous unit showing cylinder and developer head.
The premixed dough is next transferred to the cylinder of the continuous unit which is shown in Figure 3. Beneath the cylinder is the developer head. Here the dough undergoes rapid mechanical development. Water pressure is used to force the piston (shown in Figure 3) down through the cylin der forcing the dough through an orifice into the development chamber. The development chamber, which contains the two impellers, is surrounded by a water jacket for temperature control. The speed of rotation of the impellers can be varied from 100 revolutions per minute (r.p.m.) to 300 r.p.m. and the speed utilized will depend on the strength of a particular flour. When dough begins to extrude from the nozzle, the developer is started and run at 250 r.p.m. until the torque curve reaches a peak at which time the speed is reduced quickly to oper ating r.p.m. During the course of extrusion of one sampled dough can be extruded at two different speed settings. Figure 4 shows the dough being extruded and placed into the bread pan. The dough is cut after so many seconds since the pump speed is regulated to deliver so much dough in so many seconds. Figure 5 shows the controls snd recorder for the developing unit. A graphic recording, therefore, is obtained during the high speed mixing period. When the dough has been extruded into the pans, the pans are placed in a proofer with con
trolled temperature and relative humidity and the dough allowed to rise for 55 minutes before being placed in the oven to bake. Figure 6 shows the finished loaves of bread after removal from the oven. The type of bread produced by means of con tinuous baking or, in other words, by mechanical development differs considerably from bread made using conventional baking techniques. This differ ence is apparent in external as well as internal characteristics. The grain of the continuous pro duced bread is very fine and uniform. This pro perty can be noted in Figure 7. The appearance per haps can best be described by utilizing the expres sion “ angel cake” appearance. The fine and uni form crumb of this bread, however, lacks the strength and resiliance of the crumb of convention al bread and, for this reason, has been considered a disadvantage by many people. One of the principle reasons for establishing such a system in the Department of Cereal Chem istry and Technology was the fact that currently in the United States, about 50 per cent of the com mercial bread produced is made by the continuous bread process. The mixing requirements and strength of a particular flour can be determined using such a system. The two measurements relat ed to mixing obtained from the unit include “ peak Farm Research
Fig. 5. Continuous unit recorder and controls. January- February, 1972
Oxidation — I 90 P P M Bromate 112 Iodate Peak Time (A) — 32 sec. Optimum Dev’t — 150 R.P.M. Cysteine — 0 P.P.M.
170 P.P.M. Bromate 0xldUon-{ l4 P .P .M. Iodate Peak Time (A) — 21 sec. Optimum Dev’t — 120 R.P.M. Cysteine — 75 P.P.M.*
Fig. 8. Mixing curves obtained from continuous unit for variety Chris with and without addition of cysteine.
Red River 68. In this particular study, the effect of cysteine, a reducing agent, on dough properties was investigated. Without the addition of cysteine, the peak time for Chris was 32 seconds with an opti mum development of 150 r.p.m, For Red River 68, without cysteine, the peak time was 165 seconds
and the optimum development was above 250 r.p.m. The addition of cysteine reduced the peak time and optimum development, but in the case of Red River 68 with 150 p.p.m. cysteine, the peak time and op timum development were still higher than Chris without cysteine.
Red River 68
Oxidation ISO[12 P.P.M. Iodate^ P.P.M. Bromate Peak Time (A) — 185 aec. Optimum Dev’t — Above 250 R.P.M. Cycteine — 0 P.P.M.
Oxidationion — | 70 P.P.M. Bromate14 P.P.M. Iodate Peak Time (A) — 78 aec. Optimum Dev’t — Above 250 R.P.M. Cysteine — 75P.P.M.
[70 P.P.M. Bromate [ 14 P.P.M. Iodate Peak Time (A) — 47 sec. Optimum Dev’t — 220 R.P.M. Cysteine— 150 P.P.M.
Fig. 9. Mixing curves obtained from continuous unit for variety Red River 68 with and without addition of cysteine.
January - February, 1972 27
[0] Higher Fig. 10. External appearance of continuous bread made from Chris and Red River 68 with and without addition of cys teine.
The loaves of bread produced on the continu ous unit for Chris and Red River 68 is shown in Figure 10. The extremely bumpy loaves for Red River 68 indicate underdevelopment which indi cates the high mixing requirements essential for this particular variety of wheat. At a level of cys teine of 150 p.p.m., the development requirements were reduced; however, the bread obtained was still inferior to that of Chris. Pertaining to wheat quality evaluation, the continuous baking unit equipment to date has been utilized to evaluate the Crop Quality Council sam ples. These samples are analyzed for quality by a number of cereal laboratories, and recommenda tions are made pertaining to each sample. In most cases, evaluation of these samples at this time de termines whether a new variety should be released or not. Mixing requirement is the primary quality property investigated with the use of the continu ous baking equipment. Also, the properties of the finished loaf of bread are examined. The continuous baking equipment, in addition to being used for quality evaluation purposes, will also be used to conduct basic and applied research in relation to baking.
The baking process has undergone many changes over the years. At one time, the process was considered by many to be essentially an art; with today’s technological advances, baking can no longer be regarded simply as an art. Today’s mo dern qualified bakery superintendent is well aware of the scientific implications involved in the baking process. Many studies have taken place since the intro duction of the continuous baking process on a com mercial scale in the early 1950’s. The initial prob lem of flavor with this type of bread has been a topic of considerable discussion and research. Research in baking continues. Work on “ no time” doughs has been undertaken. Such a system would eliminate bulk fermentation and be replaced by chemical development. Work is also being con ducted to utilize the fermentation type of bread system in conjunction with rapid mechanical de velopment. Finally, one must realize that the loaf of bread on the grocer’s shelf has been the result of a com bined team effort involving the plant breeder, plant pathologist, cereal chemist, farmer, miller, baker, as well as many other people too numerous to men tion. 28 Farm Research