CA1037474A - Method and apparatus for the treatment of wheat flour - Google Patents
Method and apparatus for the treatment of wheat flourInfo
- Publication number
- CA1037474A CA1037474A CA220,001A CA220001A CA1037474A CA 1037474 A CA1037474 A CA 1037474A CA 220001 A CA220001 A CA 220001A CA 1037474 A CA1037474 A CA 1037474A
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- Prior art keywords
- dough
- vessel
- blades
- rotatable
- gluten
- Prior art date
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Abstract
Abstract of the Disclosure An improved system is described for separating and recovering starch and gluten from wheat flour dough. It includes a known trough-like vessel having a semicircular, at least partly perforated bottom, dough treatment members mounted on a rotatable shaft extending longitudinally within the vessel, means for adding wash liquid to the vessel, means for withdrawing this wash liquid together with extrac-ted starch via the perforations, means for introducing dough at one end of the vessel and means for discharging gluten at the opposite end. The novel feature relates to the treat-ment members which are in the form of rotatable radial blades having angularly inclined faces adapted to lift and advance the dough along the vessel while substantially avoiding pressing the dough against the perforated bottom.
The blades also have sharpened leading edges adapted to co-operate with fixed cutter bars extending transversely across the vessel. These rotatable blades lift the dough which is cut both by a scissors action between the rotatable and fixed blades and by a single knife action involving only the rotating blade to expose a fresh surface for contact with the wash liquid.
The blades also have sharpened leading edges adapted to co-operate with fixed cutter bars extending transversely across the vessel. These rotatable blades lift the dough which is cut both by a scissors action between the rotatable and fixed blades and by a single knife action involving only the rotating blade to expose a fresh surface for contact with the wash liquid.
Description
~.~3~
Background of the Invention Field of the ~nvention .
This invention relates to a process and apparatus for the recovery of starch and gluten from a wheat-flour dough.
Description of the Prior Art Starch has been traditlonally produced by e~traction from tubers and also from corn and rice by disintegrating the tubers or grain and then washing out the starch from the pulp on screens of various designs. The production of wheat starch, on the other hand, requires a totally dl.EEerent process. The reason for thls is the rather special physlca:L
properties of wheat gluten. The gluten tends to swe:Ll dur:Lrlg the mixing process of wlleat ~lour with water and Eorllls ~
network of a cellular pattern in which the gluten forms the cell wall and the starch fills the cells. The hydrated or swollen gluten is very elastic and this property is utilized when leavening the dough for bread baking. When the yeast converts some of the starch granules into alcohol, carbon dioxide is formed and expands the cells. The elastic gluten walls prevent the gas from escaping and a fluffy and easier digestible bread can be baked.
While this is obviously a very beneficial feature of wheat flour in terms of bread production, it is at the same time one of the most serious problems in the utili~ation of wheat flour for the productlon of starch. When separatlng the gluten and starch from the wheat dough, water is used as the vehicle for washing the starch away from the gluten nnd in the unwashed dougll, the gluten is dispersed as n very thln network. While the starch particles have a definlte size and shape, the gluten has neither of these character-~ .
Background of the Invention Field of the ~nvention .
This invention relates to a process and apparatus for the recovery of starch and gluten from a wheat-flour dough.
Description of the Prior Art Starch has been traditlonally produced by e~traction from tubers and also from corn and rice by disintegrating the tubers or grain and then washing out the starch from the pulp on screens of various designs. The production of wheat starch, on the other hand, requires a totally dl.EEerent process. The reason for thls is the rather special physlca:L
properties of wheat gluten. The gluten tends to swe:Ll dur:Lrlg the mixing process of wlleat ~lour with water and Eorllls ~
network of a cellular pattern in which the gluten forms the cell wall and the starch fills the cells. The hydrated or swollen gluten is very elastic and this property is utilized when leavening the dough for bread baking. When the yeast converts some of the starch granules into alcohol, carbon dioxide is formed and expands the cells. The elastic gluten walls prevent the gas from escaping and a fluffy and easier digestible bread can be baked.
While this is obviously a very beneficial feature of wheat flour in terms of bread production, it is at the same time one of the most serious problems in the utili~ation of wheat flour for the productlon of starch. When separatlng the gluten and starch from the wheat dough, water is used as the vehicle for washing the starch away from the gluten nnd in the unwashed dougll, the gluten is dispersed as n very thln network. While the starch particles have a definlte size and shape, the gluten has neither of these character-~ .
- 2 -~ lD3~
istlcs. Wheat gluten is, however, very stick~, tough and plastlc in relation to gluten particles from other flour sources, which property makes it possible ~o collect the wheat gluten in the form of gluten lumps on a screen while the starch i8 washed through the screen by means of a washing liquid.
The above characteristics of wheat flour clough mean that in the separation process two contradictory conditions must be taken into consideration. Thus, on the one hand, the washed gluten particles or strands should accumulate as quickly as possible in order that the gluten losses may be kept small, while on the other hand, the gluten network must be ruptured in order that starch granules embedded in thls network will come into contact wlth the washing liquld. These contradlctory conditlon~ have necessltated labour consu~llng and very langthy and expenslve procedures whll~ obtainillg wheat starch oE rathcr poor quality and yields.
Contlnuous processes have been developed which involve a quite complete dispersion of the dough in wash water and the recovery of the gluten on vibrating or rotating screens having a very fine mesh of 100 microns or finer.
These screens obviously require much cleaning and maintenance and, due to the large screen area requried, the contact between products and air is considerable9 this resulting in -~
undue and unhygienic bacterial action and breakdown especially of the gluten. Moreover, this system requires a comparatively "hard" type of Plour.
A significant advance in the production oE starch and gluten from wheat flour dough is the system described ln Plaven U.S. Patent 3,669,739 issued June 13, 1972. In that sy~tem a wheat flour dough ls simultaneously mPchanically trented and spray washed with a starch absorbing liquid, this liquid ~ 3 -' ' ' '~ ~ ' ' ' ' `' ' ' ~11374~
being quickly removed from the recovery reglon so as to prevent an undue buildup of wash liquid. The dough is subjected to repeated pinching, shreading and cuttlng actlons by the disposition and use of improved scrapers, and spreading members revolving with a rotatable axle extending axially within a perforated semicircular trough-shaped treatment zone. The purpose of thls is to break down the gluten net-work of the dough so that the starch can be washed out and the starch and reformed gluten lumps recovered in different regions.
While that system has many advantages, it also has some qulte severe commerclal dlsadvantages. One of the ma~or disadvantages is that the lumps of dough are s~lb~ectecl to repeated and progressive steps of pushlng and movlng, plnching, cuttlng and shreading operatlons by a plurRllty oE dlEferent axially spaced and circumferentially offset radially extending pushing paddles and cutting sabres, the latter members operating by pinching the dough lumps between the radially outermost edges thereof and the trough bottom. This pushing and pinching of the dough against the perforated screen by the action of the various treatment members tend to cause the dough to block the screen thereby decreasing the efficiency of the system.
It is the object of the present invention to over-come the above disadvantages of the prior art systems.
Summary of Invention This ob~ect is achieved according to the present inventlon by treatlng the wheat flour dough in such a manner that fresh dough surfaces available for contactlng wash water are created continuously be repeated cuttlng or sliclng the dough at a locatlon remote from the screen or perforate member.
, -~3~
In this way, pressing of the dough against the screen as required by the prior art processes is substantially avoided and the attendant disadvantages, especlally the tendency of the screen to become blocked by material being treated, is greatly reduced or even eliminated.
Detailed Description of the Invention The apparatus of the present lnvention has the usual basic features including a trough-like vessel having a substantially semicircular, at least partly perforated bottom, dough treatment members mounted on a rotatable shaft extending longltudinally within the vessel, means for addlng washing liquid to the vessel, means for withdrawing this washlng liquid together wlth extracted starch via tho perforat:Lons, means for introducing dough in one cnd oE the vasse:l and means for discharging gluten at the opposite end. This apparatus is characterized by improved treatment members in the form of rotatable radial blades having angularly inclined faces adapted to lift and advance the dough while substantially avoiding pressing of the dou~h against the perforated bottom. These blades are further characteri~ed by having sharpened leading edges which are adapted to co-operate with fixed cutter bars extending transversely across the vessel. Thus, the dough is lifted by the rotatable blades and is sliced or cut by a scissors action between the rotatable blades and cutter bars to expose a fresh surface for contact with the washing liquld. Mreover, some lumps of dough which have been ralsed by the rotatable blades may slide down the sharpened leading edges thereof towards the shaft and as a consequence are sliced e~en Eurther by the comblned action of their own weight and the said sharpened edges.
.
~374~74 This arrangement very clearly avolds the prior art problems of the dough being pressed against the perforated bottom, thereby clogging the perforations. Any system which relies upon a kind of shredding action for cutting and exposing new surfaces of dough for starch removal will result in some degree of pressing of the dough against the perforated bo~tom and the resultant clogging of the holes.
It has been found that this problem can be avoided only by having the rotatable blades relatively well spaced from the perforated bottom and contouring the faces of these blades solely to lift and advance the dough. The present invention provides substantially no shredding action and a clean cutting action occurs remote from the perforated bottom at the fixed cutter blade and along the length of the rotating bLndcs.
This cutting actlon has the eEEect o exposing a vcry ~ub-stantial area of dough for contact wlth the wash llquid to remove addltional starch. By providing this very distinct cutting actlon, the worklng of the dough especlally agalnst the perforate member is decreased to a minimum whlle the exposure of fresh surfaces for removal of starch is maximized.
The present invention also includes a novel process for separating and recovering starch and gluten from wheat flour dough. According to this process, a substantially continuous flow of wheat flour dough is introduced into one end of an elongated treating zone having a substantially semicircular, at least partly perforated bottom. Within this zone the dough ls sub~ected to repeated and progressive steps of llfting, cuttlng and moving operatlons by a plurallty of rotating radlal blades having angularly disposed Eaces to lift and advance the dough while substantially avoiding pressing of the dough against the perfor~ted bottom. The ' '.: .' :
, . . ~ .
cutting action is provided by means of sharp leading edges on the blades which co-operate with fixed cutter bars so that as the dough is being lifted and advanced, it is also being sliced or cut by a scissors action between the rotating blades and fixed cutter bars to expose a fresh surface.
The rotating blades also provide fresh surfaces via a knife action brought about by raised lumps of dough returning to the trough by sliding along the sharp leading edges of the rotating blades during which the lumps are sliced by the combination of the sharpened edges and their own weight.
During the travel through the treatlng zone the dough is also constlnuously belng contacted wl~h a wash llquld for washing out and removlng stnrch erom the dougll, whlch wasll watar then exits through the bo~om perforatlons. 1~ is, of course, most important to keep the perforations open so that the wash liquid can discharge without accumulating in the treating zone.
Thus, if gluten lumps are moved along the treating zone while submerged in water, they will not have sufficient absorption power to catch and merge with small gluten particles suspended in the wash liquid.
Descrlption of the Preferred Embodiments Certain preferred embodiments of the invention are illustrated by the attached drawings, in which:
Figure l is a general perspective view of the device of the invention;
Figure 2 is an end elevation ln partial sectlon;
Figure 3 is a plan view with portions of the cover removed;
Figure ~ is a plan view showing A complete commercial installation, Figure S is a side elevation of an industrial installation;
and Figure 6 is a perspective vlew of n rotntable blade.
_ 7 ~3~7~
As will be seen from the drawings, the device primarily comprises elongated substantially cylindrical vessels or units 10 mounted in pairs with a common collecting trough or pan 11 for each pair of vessels 10. The vessels are supported by outer frames formed by lower horizontal frame members 13 and upper horizontal frame members 14 fixed between vertical posts 12. Between the pairs of vessels is a central support frame formed by horizontal frame members 15 and 16 fixed between vertical tubular members 21.
Each vessel or unit 10 is in the form of a series of modules in end-to-end relationship and separated by low partition walls or dams. As shown ln Figure 5, each vessel 10 is made up of four modules lOa, lOb, LOc, and l()d o~ eclual length. The support Erame ls also construclte~l ln mocluLo~
corresponding in length with the vessel ~lodule6, The troughs or pans 11 are formed from stainless steel sheeting, each having lower incline panels 17 merging at a central outlet 18. The pans for vessel modules lOb, lOc, and lOd extend the ful~ length of each vessel module, while for the first vessel module lOa the pan extends only under the second half of the vessel module. The first half of vessel module lOa is the dough receiving portion and does not have a perforated bottom. Extending upwardly from the lower panels 17 are removable side wall panels 19 which are hung from and held in place by panel hooks 20. The lower extremities of these side wall panels are retrained behind Prame members 13. Thus, it will be seen that these sicle wall panels 19 can be very quickly and easily removed for cleaning purposes.
~37~7~a A light gauge stainless steel panel 23 is wrapped around each upper central frame member 16 with the lower end edges of the panel 23 being welded to lower central frame member 15. This forms a pair of vertical panels extending longitudinally between vertical tubes 21 and forming back splash panels. Also in this central region are a pair of locking bars 24.
Each unit or vessel 10 has a semicircular perforated bottom 25. This perforated bottom is made up oE stainless steel panels of the modular length. Each panel conveniently has a thickness of about 0.03 inch and the perforations can convenlently be of 0.025 inch diameter with a spacing of 0.05 inch. The units lO are constructed with a series oE
longitudinally spaced semiclrcular T-sh<lped rlbs 2~ sllp~orted at thelr outer ends by Erame me~ crs l~l and at ~hel.r Lnner ends by frame member 15, wlth relnforclng tubes 27 runnlng longitudinally between the ribs 26 for further stiffening. These rlbs and reinforcing tubes are flxed ln posltlon and the perforated stalnless steel panels are then mounted on top of the semicircular ribs and cemented in position to form the semicircular bottom. Thus, if any portion of the device becomes badly fouled or a perforated panel is damaged, a side wall panel 19 can be very quickly removed allowing access to the adjacen~ perforated bottom panel which can also be very quickly serviced or replaced by a new panel. This provides a great saving in down tlme of the devlce.
The top portions of the vessels lO have Eurther semiLclrcular T-cross sectlon ribs 2~ w:Lth one 90 segement of the top portion belng enclosed by an arcuate s~ainless steel panel 29. An lnspectlon window is also provlded ln the upper portlon and this lnspectlon wlndow has a protective screen 30 and a plastlc cover 31. The cover ls held ln posltion by means of clamp members 32 and 32a.
7g~7~L ~
Extending along the length of the top of each vessel 10 is a header tube 33 with downwardly directed orlfices. Wash water is sprayed into vessel 10 through this header. At ~he top of header 33 are a series of upwardly extending tubular connectors 34 which connect to flexible tubing for feeding in the wash water. This wash water may either be fresh water or water which is collected from the pans 11. For instance, the water collected from the pans of modules lOc and lOd may be sprayed into the top of vessel modules lOb and lOc.
The vessels 10 are divided into a series of compart-ments separated by low dams. These dams include radially positioned low partition walls 35 mounted between adJacent vessel modules and partltlon walls 35a mounted at thc middla of each vessel module. The dams extencl upwardly from the bottom of the vessel to a height of about two-thirds of the radius of the vessel.
Bearing members 36 are mounted at the ends of the modules directly above the dam members 35 and these bearings support for rotation a square tubular shaft 37. Mounted on ;
this shaft 37 are a series of blade members 38. Also mounted within the vessels lO are a series of fixed blades 39 for co-operation with the rotatable blades 38. The blades 39 are mounted at their ends in blade holding bars 40 and each blade 39 has a pair of cutting edges 41.
Each rotatable blade 38 has a flat front face 43 and a star-shaped central cut-out 42 for keying o~er the square shaft 37. These blades are spaced along the shaft by means oE square spacers which slide over the square shaft 37. Thus, each modular length of the unit is assembled by sliding a series of blades 38 and square tubular spacers 47 .: ' .' ., -' : . .
.. . . .. . . . .
7gL7~
onto a modular length of square shaft 37 and placing this in a vessel module.
Each blade 38 has a pair of diametrically opposed radial arms and each arm has a sharpened leading edge 44 of concave profile terminating in a projecting tip 4S. The blades also have curvilinear trailing flange portions 46 which curve in a direction generally away from the flat face as shown. The combination of the curved cutting edge 44, the projecting tips 45 and the curved flanges 46 all work together to lift and cut the dough while substantially avoiding any pressing of the against the perforated bottom panels 25 and at the same time adva~cing the dough forwardly through the vessel over each dam 35.
It has also been found to be advantageous Lf n propellor shaped paddle 57 1~ pofJit:Loned ad~acent each dam 35. These paddles trail slightly the cutter blades and serve to deflect dough raised by the immediately adjacent cutter blade over the dam. These are mounted on the shaft in the same manner as the blades 38.
A backwashing header 50 may also be mounted for travel longitudinally along beneath the adjacent pair of vessels 10. This header has a pair of arcuate tubular members 51 with upwardly directed spray nozzles 52. These two tubes 51 are connec~ed at their inner ends to a T-member 53 and this connects to a vertical tubular connector 54 onto which is connected a flexible sanitary hose 55. For travel along beneath the perforated bottom panels, the header tubes 51 are supported on horizontally extending shafts 56.
Backwashing of the perforated panels 25 can also very conveniently be done by slmply removing the sidc panels 19 and spraying the perEorated panels manually wlth hoses.
.. . . ~
As shown in Figure 4, a Lypical commercial installation comprises two pairs of vessels 10. Platforms 58 are provided for servicing and maintaining the vessels, with access stairs 59. The number 60 indicates the location for feeding dough ; into each pair of vessels.
A detailed description of the operation of the system has not been given since this will be readily evident those ; skilled in the art. Thus, the means for feeding in dough, discharging gluten, circulating liquid, etc., are all well known in the art.
' ~ , .
.. . . . . . .
'`. ' ' .: ' ' . , : .
., , ~
istlcs. Wheat gluten is, however, very stick~, tough and plastlc in relation to gluten particles from other flour sources, which property makes it possible ~o collect the wheat gluten in the form of gluten lumps on a screen while the starch i8 washed through the screen by means of a washing liquid.
The above characteristics of wheat flour clough mean that in the separation process two contradictory conditions must be taken into consideration. Thus, on the one hand, the washed gluten particles or strands should accumulate as quickly as possible in order that the gluten losses may be kept small, while on the other hand, the gluten network must be ruptured in order that starch granules embedded in thls network will come into contact wlth the washing liquld. These contradlctory conditlon~ have necessltated labour consu~llng and very langthy and expenslve procedures whll~ obtainillg wheat starch oE rathcr poor quality and yields.
Contlnuous processes have been developed which involve a quite complete dispersion of the dough in wash water and the recovery of the gluten on vibrating or rotating screens having a very fine mesh of 100 microns or finer.
These screens obviously require much cleaning and maintenance and, due to the large screen area requried, the contact between products and air is considerable9 this resulting in -~
undue and unhygienic bacterial action and breakdown especially of the gluten. Moreover, this system requires a comparatively "hard" type of Plour.
A significant advance in the production oE starch and gluten from wheat flour dough is the system described ln Plaven U.S. Patent 3,669,739 issued June 13, 1972. In that sy~tem a wheat flour dough ls simultaneously mPchanically trented and spray washed with a starch absorbing liquid, this liquid ~ 3 -' ' ' '~ ~ ' ' ' ' `' ' ' ~11374~
being quickly removed from the recovery reglon so as to prevent an undue buildup of wash liquid. The dough is subjected to repeated pinching, shreading and cuttlng actlons by the disposition and use of improved scrapers, and spreading members revolving with a rotatable axle extending axially within a perforated semicircular trough-shaped treatment zone. The purpose of thls is to break down the gluten net-work of the dough so that the starch can be washed out and the starch and reformed gluten lumps recovered in different regions.
While that system has many advantages, it also has some qulte severe commerclal dlsadvantages. One of the ma~or disadvantages is that the lumps of dough are s~lb~ectecl to repeated and progressive steps of pushlng and movlng, plnching, cuttlng and shreading operatlons by a plurRllty oE dlEferent axially spaced and circumferentially offset radially extending pushing paddles and cutting sabres, the latter members operating by pinching the dough lumps between the radially outermost edges thereof and the trough bottom. This pushing and pinching of the dough against the perforated screen by the action of the various treatment members tend to cause the dough to block the screen thereby decreasing the efficiency of the system.
It is the object of the present invention to over-come the above disadvantages of the prior art systems.
Summary of Invention This ob~ect is achieved according to the present inventlon by treatlng the wheat flour dough in such a manner that fresh dough surfaces available for contactlng wash water are created continuously be repeated cuttlng or sliclng the dough at a locatlon remote from the screen or perforate member.
, -~3~
In this way, pressing of the dough against the screen as required by the prior art processes is substantially avoided and the attendant disadvantages, especlally the tendency of the screen to become blocked by material being treated, is greatly reduced or even eliminated.
Detailed Description of the Invention The apparatus of the present lnvention has the usual basic features including a trough-like vessel having a substantially semicircular, at least partly perforated bottom, dough treatment members mounted on a rotatable shaft extending longltudinally within the vessel, means for addlng washing liquid to the vessel, means for withdrawing this washlng liquid together wlth extracted starch via tho perforat:Lons, means for introducing dough in one cnd oE the vasse:l and means for discharging gluten at the opposite end. This apparatus is characterized by improved treatment members in the form of rotatable radial blades having angularly inclined faces adapted to lift and advance the dough while substantially avoiding pressing of the dou~h against the perforated bottom. These blades are further characteri~ed by having sharpened leading edges which are adapted to co-operate with fixed cutter bars extending transversely across the vessel. Thus, the dough is lifted by the rotatable blades and is sliced or cut by a scissors action between the rotatable blades and cutter bars to expose a fresh surface for contact with the washing liquld. Mreover, some lumps of dough which have been ralsed by the rotatable blades may slide down the sharpened leading edges thereof towards the shaft and as a consequence are sliced e~en Eurther by the comblned action of their own weight and the said sharpened edges.
.
~374~74 This arrangement very clearly avolds the prior art problems of the dough being pressed against the perforated bottom, thereby clogging the perforations. Any system which relies upon a kind of shredding action for cutting and exposing new surfaces of dough for starch removal will result in some degree of pressing of the dough against the perforated bo~tom and the resultant clogging of the holes.
It has been found that this problem can be avoided only by having the rotatable blades relatively well spaced from the perforated bottom and contouring the faces of these blades solely to lift and advance the dough. The present invention provides substantially no shredding action and a clean cutting action occurs remote from the perforated bottom at the fixed cutter blade and along the length of the rotating bLndcs.
This cutting actlon has the eEEect o exposing a vcry ~ub-stantial area of dough for contact wlth the wash llquid to remove addltional starch. By providing this very distinct cutting actlon, the worklng of the dough especlally agalnst the perforate member is decreased to a minimum whlle the exposure of fresh surfaces for removal of starch is maximized.
The present invention also includes a novel process for separating and recovering starch and gluten from wheat flour dough. According to this process, a substantially continuous flow of wheat flour dough is introduced into one end of an elongated treating zone having a substantially semicircular, at least partly perforated bottom. Within this zone the dough ls sub~ected to repeated and progressive steps of llfting, cuttlng and moving operatlons by a plurallty of rotating radlal blades having angularly disposed Eaces to lift and advance the dough while substantially avoiding pressing of the dough against the perfor~ted bottom. The ' '.: .' :
, . . ~ .
cutting action is provided by means of sharp leading edges on the blades which co-operate with fixed cutter bars so that as the dough is being lifted and advanced, it is also being sliced or cut by a scissors action between the rotating blades and fixed cutter bars to expose a fresh surface.
The rotating blades also provide fresh surfaces via a knife action brought about by raised lumps of dough returning to the trough by sliding along the sharp leading edges of the rotating blades during which the lumps are sliced by the combination of the sharpened edges and their own weight.
During the travel through the treatlng zone the dough is also constlnuously belng contacted wl~h a wash llquld for washing out and removlng stnrch erom the dougll, whlch wasll watar then exits through the bo~om perforatlons. 1~ is, of course, most important to keep the perforations open so that the wash liquid can discharge without accumulating in the treating zone.
Thus, if gluten lumps are moved along the treating zone while submerged in water, they will not have sufficient absorption power to catch and merge with small gluten particles suspended in the wash liquid.
Descrlption of the Preferred Embodiments Certain preferred embodiments of the invention are illustrated by the attached drawings, in which:
Figure l is a general perspective view of the device of the invention;
Figure 2 is an end elevation ln partial sectlon;
Figure 3 is a plan view with portions of the cover removed;
Figure ~ is a plan view showing A complete commercial installation, Figure S is a side elevation of an industrial installation;
and Figure 6 is a perspective vlew of n rotntable blade.
_ 7 ~3~7~
As will be seen from the drawings, the device primarily comprises elongated substantially cylindrical vessels or units 10 mounted in pairs with a common collecting trough or pan 11 for each pair of vessels 10. The vessels are supported by outer frames formed by lower horizontal frame members 13 and upper horizontal frame members 14 fixed between vertical posts 12. Between the pairs of vessels is a central support frame formed by horizontal frame members 15 and 16 fixed between vertical tubular members 21.
Each vessel or unit 10 is in the form of a series of modules in end-to-end relationship and separated by low partition walls or dams. As shown ln Figure 5, each vessel 10 is made up of four modules lOa, lOb, LOc, and l()d o~ eclual length. The support Erame ls also construclte~l ln mocluLo~
corresponding in length with the vessel ~lodule6, The troughs or pans 11 are formed from stainless steel sheeting, each having lower incline panels 17 merging at a central outlet 18. The pans for vessel modules lOb, lOc, and lOd extend the ful~ length of each vessel module, while for the first vessel module lOa the pan extends only under the second half of the vessel module. The first half of vessel module lOa is the dough receiving portion and does not have a perforated bottom. Extending upwardly from the lower panels 17 are removable side wall panels 19 which are hung from and held in place by panel hooks 20. The lower extremities of these side wall panels are retrained behind Prame members 13. Thus, it will be seen that these sicle wall panels 19 can be very quickly and easily removed for cleaning purposes.
~37~7~a A light gauge stainless steel panel 23 is wrapped around each upper central frame member 16 with the lower end edges of the panel 23 being welded to lower central frame member 15. This forms a pair of vertical panels extending longitudinally between vertical tubes 21 and forming back splash panels. Also in this central region are a pair of locking bars 24.
Each unit or vessel 10 has a semicircular perforated bottom 25. This perforated bottom is made up oE stainless steel panels of the modular length. Each panel conveniently has a thickness of about 0.03 inch and the perforations can convenlently be of 0.025 inch diameter with a spacing of 0.05 inch. The units lO are constructed with a series oE
longitudinally spaced semiclrcular T-sh<lped rlbs 2~ sllp~orted at thelr outer ends by Erame me~ crs l~l and at ~hel.r Lnner ends by frame member 15, wlth relnforclng tubes 27 runnlng longitudinally between the ribs 26 for further stiffening. These rlbs and reinforcing tubes are flxed ln posltlon and the perforated stalnless steel panels are then mounted on top of the semicircular ribs and cemented in position to form the semicircular bottom. Thus, if any portion of the device becomes badly fouled or a perforated panel is damaged, a side wall panel 19 can be very quickly removed allowing access to the adjacen~ perforated bottom panel which can also be very quickly serviced or replaced by a new panel. This provides a great saving in down tlme of the devlce.
The top portions of the vessels lO have Eurther semiLclrcular T-cross sectlon ribs 2~ w:Lth one 90 segement of the top portion belng enclosed by an arcuate s~ainless steel panel 29. An lnspectlon window is also provlded ln the upper portlon and this lnspectlon wlndow has a protective screen 30 and a plastlc cover 31. The cover ls held ln posltion by means of clamp members 32 and 32a.
7g~7~L ~
Extending along the length of the top of each vessel 10 is a header tube 33 with downwardly directed orlfices. Wash water is sprayed into vessel 10 through this header. At ~he top of header 33 are a series of upwardly extending tubular connectors 34 which connect to flexible tubing for feeding in the wash water. This wash water may either be fresh water or water which is collected from the pans 11. For instance, the water collected from the pans of modules lOc and lOd may be sprayed into the top of vessel modules lOb and lOc.
The vessels 10 are divided into a series of compart-ments separated by low dams. These dams include radially positioned low partition walls 35 mounted between adJacent vessel modules and partltlon walls 35a mounted at thc middla of each vessel module. The dams extencl upwardly from the bottom of the vessel to a height of about two-thirds of the radius of the vessel.
Bearing members 36 are mounted at the ends of the modules directly above the dam members 35 and these bearings support for rotation a square tubular shaft 37. Mounted on ;
this shaft 37 are a series of blade members 38. Also mounted within the vessels lO are a series of fixed blades 39 for co-operation with the rotatable blades 38. The blades 39 are mounted at their ends in blade holding bars 40 and each blade 39 has a pair of cutting edges 41.
Each rotatable blade 38 has a flat front face 43 and a star-shaped central cut-out 42 for keying o~er the square shaft 37. These blades are spaced along the shaft by means oE square spacers which slide over the square shaft 37. Thus, each modular length of the unit is assembled by sliding a series of blades 38 and square tubular spacers 47 .: ' .' ., -' : . .
.. . . .. . . . .
7gL7~
onto a modular length of square shaft 37 and placing this in a vessel module.
Each blade 38 has a pair of diametrically opposed radial arms and each arm has a sharpened leading edge 44 of concave profile terminating in a projecting tip 4S. The blades also have curvilinear trailing flange portions 46 which curve in a direction generally away from the flat face as shown. The combination of the curved cutting edge 44, the projecting tips 45 and the curved flanges 46 all work together to lift and cut the dough while substantially avoiding any pressing of the against the perforated bottom panels 25 and at the same time adva~cing the dough forwardly through the vessel over each dam 35.
It has also been found to be advantageous Lf n propellor shaped paddle 57 1~ pofJit:Loned ad~acent each dam 35. These paddles trail slightly the cutter blades and serve to deflect dough raised by the immediately adjacent cutter blade over the dam. These are mounted on the shaft in the same manner as the blades 38.
A backwashing header 50 may also be mounted for travel longitudinally along beneath the adjacent pair of vessels 10. This header has a pair of arcuate tubular members 51 with upwardly directed spray nozzles 52. These two tubes 51 are connec~ed at their inner ends to a T-member 53 and this connects to a vertical tubular connector 54 onto which is connected a flexible sanitary hose 55. For travel along beneath the perforated bottom panels, the header tubes 51 are supported on horizontally extending shafts 56.
Backwashing of the perforated panels 25 can also very conveniently be done by slmply removing the sidc panels 19 and spraying the perEorated panels manually wlth hoses.
.. . . ~
As shown in Figure 4, a Lypical commercial installation comprises two pairs of vessels 10. Platforms 58 are provided for servicing and maintaining the vessels, with access stairs 59. The number 60 indicates the location for feeding dough ; into each pair of vessels.
A detailed description of the operation of the system has not been given since this will be readily evident those ; skilled in the art. Thus, the means for feeding in dough, discharging gluten, circulating liquid, etc., are all well known in the art.
' ~ , .
.. . . . . . .
'`. ' ' .: ' ' . , : .
., , ~
Claims (7)
1. In an apparatus for extracting starch and gluten from wheat flour dough, comprising an elongated treatment vessel having a substantially semicircular, at least partly perforated bottom, dough treatment members mounted on a rotatable shaft extending longitudinally within the vessel, means for adding wash liquid to the vessel, means for with-drawing this wash liquid together with extracted starch via the perforations, means for introducing dough at one end of the vessel and means for discharging gluten at an opposite end, the improvement which comprises treatment members in the form of rotatable radial blades having angularly disposed faces adapted to lift and advance the dough while substantially avoiding pressing of the dough against the perforated bottom, said blades also having sharpened leading edges adapted to co-operate with fixed cutter bars extending transversely across the vessel, whereby the dough is lifted by the rotatable blades and is cut by a scissors action between the rotatable blades and fixed bars to expose a fresh surface for contact with the wash liquid.
2. An apparatus according to claim 1 wherein said rotatable blades comprise a series of axially spaced blade members, each including a pair of diametrically opposed radial arms having a common flat leading face parallel to said fixed blades, with each radial arm having a sharpened leading edge and a curvilinear trailing flange portion for lifting and advancing the dough.
3. An apparatus according to claim 2 wherein the sharpened leading edge is of concave configuration.
4. An apparatus according to claim 1 wherein the vessel includes low radial partition means to divide the vessel into predetermined zones.
5. An apparatus according to claim 4 wherein a paddle member is mounted on said rotatable shaft immediately upstream of each partition means, each said paddle member having radial blades angularly pitched relative to said shaft to deflect the dough over the partition means into the next zone.
6. An apparatus according to claim 2, 3 or 5 wherein said rotatable shaft is of rectangular cross-section and said rotatable blades and paddles are positioned thereon by means of rectangular spacer sleeves.
7. A process for separating and recovering starch and gluten from wheat flour dough which comprises the steps of:
introducing a substantially continuous flow of wheat flour dough into one end of an elongated treating zone having a substantially semicircular, at least partly perforated bottom, subjecting said dough to repeated and progressive steps of lifting, cutting and moving operations by a plurality of rotating radial blades having angularly disposed faces to lift and advance the dough while substan-tially avoiding pressing of the dough against the perforated bottom, the cutting operation occuring at a location remote from the perforated bottom and being provided by means of sharp leading edges on the blades which co-operate with fixed cutter bars so that as the dough is being lifted and advanced, it is also being cut by a scissors action between the rotating blades and fixed cutter bars to expose a fresh surface, introducing a wash liquid into and along said treatment zone for washing out and removing starch from the dough and removing said liquid with contained starch particles from the treating zone through the bottom perforations with forming any substantial wash water level in the treating zone.
introducing a substantially continuous flow of wheat flour dough into one end of an elongated treating zone having a substantially semicircular, at least partly perforated bottom, subjecting said dough to repeated and progressive steps of lifting, cutting and moving operations by a plurality of rotating radial blades having angularly disposed faces to lift and advance the dough while substan-tially avoiding pressing of the dough against the perforated bottom, the cutting operation occuring at a location remote from the perforated bottom and being provided by means of sharp leading edges on the blades which co-operate with fixed cutter bars so that as the dough is being lifted and advanced, it is also being cut by a scissors action between the rotating blades and fixed cutter bars to expose a fresh surface, introducing a wash liquid into and along said treatment zone for washing out and removing starch from the dough and removing said liquid with contained starch particles from the treating zone through the bottom perforations with forming any substantial wash water level in the treating zone.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CA220,001A CA1037474A (en) | 1975-02-13 | 1975-02-13 | Method and apparatus for the treatment of wheat flour |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CA220,001A CA1037474A (en) | 1975-02-13 | 1975-02-13 | Method and apparatus for the treatment of wheat flour |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CA1037474A true CA1037474A (en) | 1978-08-29 |
Family
ID=4102288
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CA220,001A Expired CA1037474A (en) | 1975-02-13 | 1975-02-13 | Method and apparatus for the treatment of wheat flour |
Country Status (1)
| Country | Link |
|---|---|
| CA (1) | CA1037474A (en) |
Cited By (1)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN106174448A (en) * | 2016-08-02 | 2016-12-07 | 伊奇森 | A kind of track body of starch cold press device |
-
1975
- 1975-02-13 CA CA220,001A patent/CA1037474A/en not_active Expired
Cited By (1)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN106174448A (en) * | 2016-08-02 | 2016-12-07 | 伊奇森 | A kind of track body of starch cold press device |
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