Food processing device

The invention pertains to a food processing device having a mixing drum which is disposed on a support frame such that it slightly clears the floor. A horizontal tool shaft is eccentrically disposed in the drum. The mixing drum has a hinged front cover. A transport blade is disposed in the center of the front cover, and is embodied as an angled piece and provided with its own motor. To permit the device to be cleaned simply, quickly, and reliably, a special arrangement and sliding guide is provided for the outlet slide of the mixing drum. Easily-removable fasteners and seals are provided for the transport blade, the tools, and the tool shaft which bears the tools. The fasteners and seals facilitate rinsing out in the vicinity of a passage through the wall. Furthermore, a flap which closes off a feed opening on top can be provided. The flap comprises transparent material, has a contoured inner side and is removably fastened on a pivoting axis parallel to the axis of the drum.

BACKGROUND OF THE INVENTION 
The invention pertains to a food processing device having a drum which is 
disposed on a support frame such that it slightly clears the floor. The 
drum has an inlet on top, an outlet slide on the bottom, and a hinged 
front cover. An angled transport blade having its own motor is centrally 
located in the front cover. The horizontal arm of the transport blade, 
which has a scraping edge, lies against the inner wall of the shell of the 
drum. A horizontal tool shaft is overhung in the drum parallel to and 
below the drum axis. The horizontal tool shaft carries interchangeable 
tools for chopping, slicing, grating, stirring, mixing, blending, 
emulsifying, and/or kneading. The tool shaft extends through the rear wall 
of the drum and is connected for rotation to a main motor which is 
likewise disposed on the support frame. 
An embodiment of this generic type is disclosed in U.S. Pat. No. 4,010,932. 
By disposing the tool shaft toward the bottom and off center, 
less-than-full quantities can still be processed by the tools. Thorough 
mixing is also achieved. The drum can hold, for example, approximately 150 
liters, so that up to 100 kg of material can be processed. Since the 
invention pertains to a food processing device, the ease with which the 
machine can be cleaned takes on special significance. 
SUMMARY OF THE INVENTION 
The object of the invention is thus to provide an improvement of the 
equipment described above in the introduction in such a way that the 
outlet slide, transport blade, and tool shaft in particular can be cleaned 
simply, quickly, and reliably. 
In accordance with the above object there has been provided a food 
processing device, comprising a drum having a top, a bottom, an inner 
wall, a hinged front cover, a rear wall and a central horizontal axis; a 
stand for support the drum; a transport blade for scraping the inner wall 
of the drum, and centrally rotatingly disposed in the front cover; a drive 
shaft for supporting the transport blade; a horizontal tool shaft for 
carrying a tool, overmounted in the drum and disposed below the central 
horizontal axis; a first central access opening in the front cover for 
containing the shaft of the transport blade; wherein the first access 
opening is of greater diameter than the shaft of the transport blade; a 
first sliding sealing ring disposed around the shaft of the blade for 
rotatingly supporting the shaft of the transport blade; a second 
off-center access opening for containing the tool shaft, and disposed in 
the rear wall of the drum, wherein the second access opening is of greater 
diameter than the tool shaft; a second sliding sealing ring for rotating 
supporting the tool shaft; first and second means for causing one of said 
first and second sliding sealing rings to move radially outward to create 
a seal. 
Preferably, the device also comprises a third discharge opening disposed in 
the bottom of the drum, a discharge structure surrounding the discharge 
opening, and a one-piece plastic outlet slide arranged to cover the 
discharge opening and having ledges for sealing against the discharge 
structure. 
The device also preferably comprises a guide for slidably guiding the 
outlet slide, and including two holding and tightening fixtures attached 
to the discharge structure; and a horizontal, detachable guide bar 
corresponding to each holding and tightening fixture, and for displaceably 
holding the outlet side below the ledge means. 
Further objects, features and advantages of the present invention will 
become apparent from the detailed description of preferred embodiments 
which follows when considered with the attached sheets of drawing.

DESCRIPTION OF THE PREFERRED EMBODIMENTS 
The objects of the invention are attained by the following features. 
(a) The outlet slide comprises plastic, is of one piece, and is embodied 
such that a side of the slide which faces the inside of the drum is 
contoured. The slide has a margin comprising four strips which seal 
against a discharge structure. The discharge structure surrounds the 
discharge opening on the bottom and is securely connected to the drum. 
(b) The guide for the outlet slide comprises two guide bars, each of which 
hangs detachably on a holding and tightening fixture affixed to the 
discharge structure. The guide bars are disposed in the direction of 
displacement and attached below two reinforcing strips on the outlet 
slide. 
(c) For easy disassembly and cleaning or rinsing, both the central access 
opening, provided in the hinged front cover for the transport blade drive 
shaft, and the off-center access opening for the tool shaft, provided in 
the rear wall, have significantly larger diameters than the shafts which 
pass through them. A sliding seal ring is pressed into the resulting 
toroidal space. Tightening a tightening nut on the shaft causes the 
sliding seal ring to move radially outward, thus creating a seal. 
It is preferred that the discharge structure have sealing surfaces 
corresponding to the strips on the outlet slide. The sealing surfaces 
comprise steel, are only a few millimeters wide, and are raised only a few 
tenths of a millimeter. It is also advantageous that the holding and 
tightening fixture for each guide bar comprise a corner piece fastened to 
the discharge structure. The vertical section of this corner piece enters 
a longitudinal groove on a clamping plate fastened to the guide bar. The 
clamping plate has an upwardly-projecting threaded bolt which projects 
through a slot in the corner piece. The slot is open to the side. The free 
end of the bolt carries a tightening nut which presses on the corner piece 
through a cup spring. 
Firstly, merely loosening the two tightening nuts makes it possible to 
remove the outlet slide simply and quickly. Secondly, the arrangement of 
cup springs makes it possible to achieve a definite contact pressure 
between the sealing surfaces and the reinforcing strips on the outlet 
slide. This configuration ensures a reliable seal and simultaneously 
guarantees that the outlet slide can slide without binding or snagging. 
The sealing surface embodiment just described ensures sufficient surface 
pressure and minimizes wear. The sealing, wear, and sliding properties are 
optimal when the outlet slide comprises polyamide. This material further 
makes it possible to clean the slide simply and reliably. 
It is advantageous that each of the sliding seal rings for the transport 
blade and tool shafts comprise two identical steel rings with a rubber 
sleeve. According to the invention, the transport blade, along with a 
bearing which rests on the sliding seal ring, is inserted onto the drive 
shaft. The drive shaft is a splined shaft which projects through the front 
cover. The transport blade is removably secured by a large cap nut. The 
cap nut screws onto a threaded bolt which is fastened to the face of the 
splined shaft. The cap nut is pressed against the bearing by an annular 
sealing gasket. It is advantageous that the tightening nut which rests on 
the sliding sealing ring on the tool shaft be a bayonet ring. It is a 
simple matter to remove the transport blade from the splined shaft by 
loosening the cap nut. 
Loosening the cap nut releases the sliding seal ring which then can 
likewise be removed simply from the splined shaft. Loosening the nut opens 
up the toroidal space described above, through which it is possible to 
simply and reliably rinse the interior of the drum clean. The rinse water 
runs off the outside of the drum. The sliding sealing ring on the tool 
shaft can be released in the same manner by loosening the aforementioned 
bayonet ring. After removal of the sliding sealing ring, it is possible to 
rinse the interior of the drum clean from the inside out through the 
resulting toroidal space. 
The inlet on top of the drum can be disposed on the drum shell slightly 
below the shell's highest point facing the operator side. This makes the 
device easy to operate even for people of moderate height, despite its 
large capacity. Nonetheless, there are various alternatives for how the 
finished product can be removed. The drum can be placed so high on the 
support frame that a container wagon, for example, or a conveyor device 
can be slid into place beneath the outlet slide. 
For feeding the drum manually, it is advantageous that the feed opening on 
top be closable by a flap comprising transparent material. The flap 
preferably has a contoured inside. The flap is preferably removably 
secured on a pivoting axis which lies parallel to the drum axis. On the 
one hand, this makes it possible to add ingredients by hand; on the other 
hand, it allows the processing of the material to be viewed through the 
flap. 
If the inside of the transparent flap is contoured, the scraping edge of 
the transport blade would also slide over the flap. In the case of 
materials which tend to smear, this detracts strongly from the 
transparency of the flap. It can thus be advantageous to have at least one 
portion of the contoured inner surface of the flap set back somewhat with 
respect to the inner surface of the drum shell. Even if the inner surface 
is set back approximately 1 mm, the flap remains clear in this area. 
The drum can also be fully automatically fed through a snorkel, funnel, 
hose, or the like. The flap is then replaced by a fixed funnel with 
appropriate attachments. 
The drum shell can also be embodied with a double wall if heating or 
cooling of the drum is desired. The device can also be set up for 
operation in a partial vacuum or under pressure. Steam valves or the like 
which empty into the drum can then be provided. 
It is advantageous that an electronic thermometer project into the drum for 
exact temperature measurement. A timer for preset control for ending 
kneading time, for example, can be provided on the control panel provided 
on the operator side. Furthermore, an output chronograph or a current 
chronograph can be provided. The readings can then show the optimal 
kneading process or the optimal energy input into the material to be 
processed. 
The features of the present invention result in a flap which is easy to 
install and remove, and one which is simple and quick to clean. Even the 
clamp handle in the plate can be removed quickly. The pocket-shaped recess 
is as large as possible and embodied with shallow curves so that, even 
here, safe and simple cleaning is possible. The aforementioned runoff 
opening lets material that was spilled or which splashes out when the flap 
is opened run back into the interior of the drum. To this end, it is 
advantageous that the runoff opening be provided in the lower-lying hopper 
wall, whose inner surface is only shallow with respect to the horizontal 
toward the top. 
The invention comprises a reliably-functioning, user-friendly food 
processing device, the inlet and outlet of which are simply-conceived and 
can be watertight and, if required, airtight. The new device will meet the 
most stringent sanitary requirements, while avoiding gaps and 
hard-to-clean places in the food zones. For uncomplicated cleaning, the 
parts in the food-zones can be installed or removed with few operations. 
The food processing device shown especially in FIGS. 1 and 7 includes a 
mixing drum 2 which is disposed on a support frame 1 such that it slightly 
clears the floor. The mixing drum has an inlet 3 on top, an outlet slide 4 
on the bottom. On the left end of the mixing drum 2 in FIG. 1, a front 
cover 5 is connected by a hinge which allows it to swing along a vertical 
axis 6. An angled transport blade 8 (see FIG. 7) with its own motor 7 is 
centrally located in the front cover. The horizontal arm 8a of the 
transport blade, which has a scraping edge 9, lies against the inner wall 
of the shell 2a of the mixing drum 2 (see FIG. 8). A horizontal tool shaft 
10 is over-mounted in the mixing drum 2 parallel to and below the drum 
axis 11. 
The rear wall 12 of the mixing drum 2 is securely connected by a flange to 
a main motor 13. The motor 13 drives the tool shaft 10 which projects 
through the rear wall 12. The mixing drum 2 and main motor 13 are situated 
on the vibration mount 14 on the top of the support frame 1. The main 
motor 13 is located with a housing 15, which encases, among other things, 
a hydraulic drive 16 to activate the outlet slide 4. 
A water injection conduit 17 is welded into the upper region of the rear 
wall 12. Water can be sprayed through the conduit 17 onto the inner wall 
of the drum shell 2a at a predetermined angle. Not shown in greater detail 
are a water meter and an adjustment device provided on a control panel 18, 
where the quantity of water can be preset. 
The one-piece outlet slide 4 is embodied such that a side which faces the 
inside of the mixing drum 2 is contoured to lie precisely within the 
inside contour of the mixing drum 2. The discharge opening 19 on the 
bottom (see FIG. 8) is surrounded by a discharge structure 20. The 
structure 20 has steel sealing surfaces 21 which are only a few 
millimeters wide and are raised only a few tenths of a millimeter. These 
sealing surfaces 21 work in concert with the upper surface of two 
reinforcing strips 22 disposed on the margin of the outlet slide 4. The 
guide for the outlet slide 4 comprises two guide bars 23 disposed below 
the two reinforcing strips 22. Each of the strips 22 hangs detachably on a 
holding and tightening fixture affixed to the discharge structure 20. The 
latter fixture comprises a corner piece 24 fastened to the discharge 
structure 20. The vertical section 24a of the corner piece enters a 
longitudinal groove on a clamping plate 25 fastened to the guide bar 23. 
The clamping plate has an upwardly-projecting threaded bolt 26. The bolt 
projects through a slot 27 in the corner piece 24. The slot is open to the 
side. The free end of the bolt carries a tightening nut 28 which presses 
on the corner piece 24 through a cup spring 29. Comparable sealing 
surfaces 21 work in concert with the cross-strips 22a provided in the two 
faces of the outlet slide 4 (see FIG. 7d). The back face of the outlet 
slide 4 hangs on a hydraulic rod 30 activated by the hydraulic drive 16. 
Tightening the two tightening nuts 28 produces a definite contact pressure 
between the sealing surfaces 21 and the strips on the outlet slide 4 due 
to the cup springs 29 in between the nuts 28. A reliable seal which still 
permits the outlet slide 4 to slide without binding is thus achieved. To 
remove the outlet slide 4 it is necessary only to loosen the two 
tightening nuts 28, which, by the way, can remain on the threaded bolts 26 
together with the cup springs 29. It is then easy to pull the guide bars 
23 to the side, which draws the threaded bolts 26 from the matching slit 
27. The outlet slide 4 then drops down until it rests against a block 31. 
The outlet plate 4 which continues to hang from the hydraulic rod 30, the 
discharge opening 19, the discharge structure 20, and the holding and 
tightening fixture 24 through 29 can then all be cleaned simply, reliably, 
and quickly. 
In a closed position, the outlet slide 4 rests on a limit switch 32 (see 
FIG. 8), which then permits the various functions of the equipment. 
A central access opening is provided in the front cover 5. The splined 
shaft 34, on which the motor 7 rests, projects through this opening. The 
transport blade 8 having a bearing 35, is slid onto the shaft 34 and 
fastened to turn with shaft 34. The access opening 33 has a significantly 
greater diameter than the splined shaft 34. A sliding sealing ring 36 is 
pressed into the toroidal space thus formed. The ring 36 comprises two 
identical steel rings with a rubber sleeve (see FIG. 7a). A large-sized 
cap nut 38 is screwed onto a threaded bolt 37 that is fastened to the face 
of the splined shaft 34. The cap nut presses the bearing 35 with an 
annular sealing lip 39 against the sliding sealing ring 36, thus radially 
deforming the ring 36 outwardly. 
The seal between the rear wall 12 and the tool shaft 10 essentially matches 
the construction just described. Instead of the threaded bolt 37 with cap 
nut 38, a tightening nut 40 in the form of a bayonet ring is provided. The 
bayonet ring is slid onto the tool shaft 10. The bayonet ring can be 
twisted, using a wrench, into place in a matching receptacle in the rear 
wall 12. Twisting the bayonet ring places pressure on the sliding sealing 
ring 36 located in the toroidal space between the tool shaft 10 and the 
rear wall 12, deforming the ring 36 radially outwardly (see FIG. 7c). 
While the transport blade rotates slowly, for example at 20 RPM, the tool 
shaft 10 can rotate at 750-1,200 RPM when the food processing equipment is 
used as a kneading machine. 
As is seen in FIG. 8, the scraping edge 9 on the transport blade 8 
comprises a strip of plastic which is affixed so that it is easily 
removable by a clamping strip screwed to the horizontal arm 8a of the 
transport blade 8. The free end of the tool shaft 10 has a recessed radial 
slit 42 open toward the front. A cross bolt 43 on a tool socket 44 fits 
into the slit 42 and is thus inserted onto the tool shaft 10. The tool 
socket 44 bears the tools 45 and an anular shoulder 46 on the end facing 
the front cover 5. The annular shoulder 45 is separated from the 
tightening nut 38 which fastens the transport blade 8 by a small clearance 
"a". 
The transport blade 8 and tools 45 are simple to install and remove. To 
remove the transport blade 8, the cap nut 38 is loosened, allowing the 
transport blade 8 to be removed from the splined shaft 34. The sliding 
sealing ring 36 can subsequently be removed. Removing the ring 36 opens up 
the toroidal space between the splined shaft 34 and the front cover 5, 
making it simple to rinse out through this toroidal space for cleaning. 
The rinse water then simply flows out. Loosening the screw connection 
which holds the clamping strip 41 makes it quick and easy to remove and 
clean the scraping edge 9. The tool socket 44 only needs to be pulled off 
the tool shaft 10. After loosening the tightening nut 40 and removing the 
sliding packing ring 36, the toroidal space thus created between the tool 
shaft 10 and the rear wall 12 can be rinsed from the inside out here as 
well. The rinse water exits the mixing drum 2 between its rear wall 12 and 
the main motor 13 flanged to the drum. 
The transport blade and tool are installed analogously. Should the tool 
shaft 10 start up during assembly of the equipment, the inertia of the 
mass or a resistance applied to the tool 45 will produce a slight relative 
displacement of the tool socket 44 and the tool shaft 10. An auto-braking 
effect, resulting from the cross bolt 43 reaching behind the recess in the 
radial slit 42 is thus produced. Even if the tool socket 44 should slip 
axially along the tool shaft, the annular shoulder 46 on the tool socket 
44 would come to rest against the cap nut 38, thus limiting the axial 
slippage and rendering it harmless. 
The tool socket 44 can hold tools for chopping, slicing, grating, stirring, 
mixing, blending, emulsifying, and/or kneading. The exemplary embodiment 
in FIGS. 7 and 8 shows a kneading tool which is particularly suited for 
stiffer doughs. Here, the tool socket 44 has two identically embodied 
U-shaped kneading tools 45 offset 180.degree. from each other and with an 
axial clearance from each other. The tools 45 are attached to the opposite 
sides of the tool socket 44 in such a way that the ends of the neighboring 
U-shaped arms 45a are on the one side of the socket and the ends of the 
two axially outermost U-shaped arms 45b are on the other side of the 
socket (see FIG. 7). When the tool socket 44 is viewed from the front, the 
two tools 45 form an apparently closed curve shaped like a shallow 
rectangle (see FIG. 8). Both tools 45 are bent from round stock, and are 
thus easy to clean. 
FIGS. 5 and 8 in particular make it clear that the inlet 3 on the top of 
the mixing drum 2 can be disposed on the drum shell 2a slightly below the 
latter's highest point facing the operator side. This arrangement is 
practical when the mixing drum 2 is to be loaded manually while allowing 
the interior of the drum to be observed. In this exemplary embodiment, the 
feed opening 47 includes a flap 49 and is surrounded on all sides by a 
shallow hopper 48 having hollow walls. The flap 49 is made of a 
transparent material, and its inside is contoured. The top longitudinal 
edge of the flap 49 is removably secured on a pivoting axis 50 which lies 
parallel to the drum axis 11. The pivoting axis 50 has two pins 51 
connected to the flap 49. One of the pins 51 is axially inserted into a 
matching lug 52. The other pin 51, which has a radial flattening (not 
shown), and is inserted into an appropriately-sized slot 53 in a second 
lug 52. The flap 49 can be latched by a pivoting clamp handle 54. The 
clamp handle is removably attached to the flap 49 by a screw connection 
55. The lower longitudinal wall of the hopper 48 has a pocket-shaped 
recess 56 to engage the clamp handle 54. A support shoulder 57 for the 
flap 49 is provided inside the hopper 48. If necessary, the shoulder 57 is 
formed from the drum shell 2a. The support shoulder 57 has a channel in 
the vicinity of the recess 56. The channel forms a runoff opening 58 into 
which a suitably-sized sealing ridge 59 on the flap 49 snugly fits when 
the flap is closed. The inner surface 60 of the lower longitudinal wall of 
the hopper 48 inclines only slightly upward from the horizontal (see 
especially FIG. 8). 
FIG. 6 shows a modified embodiment of the inlet 3 on top. Here, the inlet 3 
is located at the highest point of the drum shell 2a and is enclosed on 
all sides by a connecting pipe 61 which has connections for hoses and 
pipes 62, and a viewing and servicing flap 63. 
The front cover 5 has an off-center elbow lever latch 64 which surrounds an 
easily removable rotating axle 66 for supporting the hand lever 65. 
According to FIG. 1, a container vehicle 67 which can be pulled out from 
under the support frame 1 is positioned below the outlet slide 4. The 
container vehicle, shown in the filling position, contacts a contact 
switch (not shown). When the container vehicle 67 is pulled out, this 
contact switch stops the machine. 
In the exemplary embodiment illustrated in FIG. 2, a conveyor device 69 is 
pushed under the outlet slide 4 instead of a container vehicle. 
FIGS. 1, 2, 3, and 5 show the flap 49 open, while this flap is closed in 
the illustrations in FIGS. 4 and 8. The flap was omitted in FIG. 7 for a 
better overview. The flap is latched by a magnetic switch which is not 
described in greater detail. If it is desired that the device should 
operate under a vacuum, the flap 49 is equipped with an appropriate seal. 
A position switch, not described in any greater detail, is provided for the 
transport blade 8, in order to guarantee that the transport blade does not 
come to rest under the inlet 3 on top or above the outlet slide 4. 
When closed, the front cover 5 contacts a limit switch, not shown, which 
stops the machine when the front cover is opened.