Vegetable processing machine with product mobilizer apparatus

A processing machine for washing, scrubbing, or peeling products, such as vegetables or fruit, comprises a plurality of elongated rotatable processing rollers (with brushes or abrading elements thereon) arranged to define a U-shaped trough through which the products pass for processing. A rotatable waste discharging auger is located below the trough. A rotatable product mobilizer apparatus, comprising a drive shaft, helical rods arranged around and supported on the drive shaft and located in the trough, and augers on the drive shaft at the opposite ends of the helical rods, operates to raise the product layer next to the processing rollers thereby creating a tumbling action, to positively move the products toward the discharge end of the processing rollers, and to control product load level in the trough as a function of the rotational speed of the product mobilizer apparatus. Each processing roller, the waste auger, and the product mobilizer apparatus is rotatably driven by an individual hydraulic motor supplied from a hydraulic pump and speed-regulating flow control valves are provided for the hydraulic motors. One end of each processing roller and one end of the waste auger is rotatably supported by the associated hydraulic motor.

BACKGROUND OF THE INVENTION 
1. Field of Use 
This invention relates generally to machines for processing products, such 
as vegetables, fruit, or the like, by washing, scrubbing, abrading, 
peeling or the like, by means of rotatable processing rollers having 
brushes or abrading elements thereon. In particular, it relates to such 
machines having apparatus therein for controlling the product flow 
therethrough. 
2. Description of the Prior Art 
In some prior art processing machines of the aforesaid character, wherein 
one or more elongated rotatable processing rollers are provided, rotatable 
auxiliary rollers or drums having helically-shaped elements embodied 
therein are also provided to advance the products along the processing 
rollers and through the machine. Typically, the processing rollers and 
auxiliary rollers or drums are driven by complex chain drives, pulleys and 
V-belts, or geared drives. U.S. Pat. Nos. 3,750,211; 3,747,149; 2,824,318; 
and 1,407,501 illustrate the state of the art. In one type of prior art 
machine presently in use, a plurality of elongated processing rollers are 
arranged to define a generally U-shaped sloped trough in which the 
products are deposited for processing and from which they exit by the 
force of gravity. In the latter machine, there is a tendency for the 
product layer adjacent the rollers and those products at the bottom of the 
trough to remain there too long, and this results in non-uniform 
processing and excessive product waste. Furthermore, in the latter 
machine, passage of the products therethrough depends on gravity and there 
is no effective way to control product flow rate other than to change the 
slope of the trough. Also, there is no practical way to control the 
product load level within the trough other than to control the amount of 
product introduced. 
SUMMARY OF THE PRESENT INVENTION 
In accordance with the present invention, there is provided a machine for 
processing vegetables by washing, scrubbing, or peeling the same which 
comprises a plurality of elongated cylindrical parallel driven brushes (or 
abrasive rollers) which are arranged to form a U-shaped trough in which 
vegetables are tumbled and processed as they move from the input end to 
the discharged end of the machine. A product mobilizer comprising a drive 
shaft and one or more helically-shaped rotatable rods arranged around and 
supported on the drive shaft is located in the trough and operates to lift 
upwardly the vegetable layer next to brushed thereby creating a tumbling 
action and to move the vegetables positively toward the discharge end of 
the machine. The product mobilizer also comprises an auger connected to 
the drive shaft at the discharge end of the rods and rotatable therewith 
for controlling the load level of the machine in response to the speed at 
which the product mobilizer is rotatably driven. The product mobilizer 
further comprises another auger connected to the drive shaft at the input 
end of the rods and rotatable therewith to expedite entry and passage of 
the product through the machine. A waste auger is located below the trough 
to recover and remove waste which fall between the product rollers 
defining the trough. Each processing roller, the product mobilizer 
apparatus and the waste auger is driven by a separate hydraulic motor and 
operating fluid for the hydraulic motor is supplied from a hydraulic pump 
driven by an electric motor. Flow control valves are provided for each 
hydraulic motor to enable speed control thereof. One end of each 
processing roller and one end of the waste auger is rotatably supported by 
its associated hydraulic motor. 
A processing machine in accordance with the invention offers numerous 
advantages over the prior art. For example, the helical rods of the 
product mobilizer apparatus reach down and lift the product layer adjacent 
the processing rollers to improve or increase the tumbling action of the 
products in the trough thereby ensuring that the products are more 
uniformly and rapidly processed by the processing rollers and with less 
waste than heretofore. The helical rods also expedite and positively move 
the products in the trough axially along the processing rollers. The auger 
at the infeed end of the product mobilizer apparatus also operates 
effectively to positively and evenly feed the products into the trough. 
The auger at the discharge end of the product mobilizer positively 
discharges the products from the trough and, depending on an increase or 
decrease in its rotational speed, can decrease or increase, respectively, 
the quantity of products left in the trough and thereby serves as a means 
for regulating or controlling the product load within the machine at any 
given time. Furthermore, the depth (i.e., weight) of the product load or 
load level also effects the pressure at which the products are pressed 
against the processing rollers and, thus, determines the aggressiveness of 
the action of the processing rollers on the products. Thus, the speed of 
rotation of the discharge auger also determines the degree or extent of 
processing. 
The use of individual and independently controllable hydraulic motors for 
the processing rollers, product mobilizer apparatus, and waste auger also 
offers many advantages over prior art drive systems. For example, as 
hereinbefore mentioned, the control of the rotation speed of the product 
mobilizer controls product load and the degree of processing. The ability 
to control processing roller speed independently of product mobilizer 
speed also enables additional control over processing, i.e., more or less 
scrubbing or abrasion of the product, depending on processing roller 
speed. 
The product mobilizer apparatus in accordance with the invention can be 
installed on processing machines during manufacture thereof or can be 
retrofitted in machines already in the field. 
The use of independently driven hydraulic motors for the processing rollers 
and the product mobilizer apparatus eliminates the need for costly and 
complex chain, belt, or gear drives and facilitates retrofitting, as well 
as subsequent repair and servicing of the equipment. 
Other objects and advantages of the invention will hereinafter appear.

DESCRIPTION OF A PREFERRED EMBODIMENT 
Referring to FIGS. 1, 2, and 3, the numeral 10 designates a processing 
machine having product mobilizer apparatus 11 in accordance with the 
invention. Machine 10 is especially well adapted to perform processing 
operations, such as washing, scrubbing, abrading, peeling, or the like, on 
products, such as vegetables, fruits, or the like, and especially 
potatoes, carrots, or beets. 
Machine 10 generally comprises a framework 12 on which a plurality of 
elongated rotatable driven processing rollers 14 are arranged about a 
horizontal axis 16 in parallel relationship to each other and to the axis 
16 to define a generally U-shaped trough 18 through which products P pass 
for processing in the direction of arrow 23. The inlet and discharge ends 
of trough 18 are closed by end plates 13 and 19 which are mounted on 
framework 12. Framework 12 is provided with housing panels (not shown) 
which enclose the unit. Each processing roller 14, which takes the form of 
a hollow cylinder, comprises roller shafts 21 and 22 at the opposite ends 
thereof and is provided with abrading elements 24 or some other type of 
brushes (not shown). Shaft 21 of each roller 14 comprises a cylindrical 
portion 21A which is rotatably supported or journalled in an antifriction 
bearing 25 which is mounted in a sleeve 14B which is secured within the 
end of hollow cylindrical roller 14. Shaft 21 also comprises a threaded 
portion 21B which extends through an opening 19A in end plate 19 and 
through an opening 20A in a plate 20 which is secured by screws 20B to 
plate 19. A nut 20C on shaft 21 secures the stub shaft 21 against 
rotation. The other shaft 22 of each roller 14 is connected to a hydraulic 
motor 29 which is mounted on framework 12. Thus, each motor 29 physically 
supports and rotatably drives its associated roller 14 in the direction of 
the arrow 30 (see FIGS. 3 and 4). In the embodiment shown, eight 
processing rollers 14 and eight hydraulic motors 29 are provided. 
The rollers 14 in each pair of adjacent rollers are spaced apart 
sufficiently to allow waste material brushed or scraped from the 
vegetables in the trough to be flushed therethrough into a waste disposal 
means 32 which is disposed beneath the rollers 14 and mounted on framework 
12, by water injected from a spraying apparatus in the form of a hollow 
tube 39 mounted on framework 12 and located above the trough 18. Spraying 
apparatus 39, which includes a water flow control valve 35, is supplied 
with water from a water supply 44. The waste disposal means 32 comprises a 
waste hopper 33 which is rigidly mounted on framework 12 and which 
comprises downwardly and inwardly sloped side walls 34 and a 
semi-cylindrical waste trough 36 located at the bottom of the walls. Waste 
trough 36 has a waste discharge opening 37 at the discharge end of the 
trough. A waste auger 40 is rotatably mounted in waste trough 36 and 
comprises a rotatable shaft 41 having an auger flight 42 secured thereto. 
Shaft 41 of waste auger 40 is supported in an antifriction bearing 45 
which is mounted on a plate 46 defining one end of waste trough 36. The 
other end of shaft 41 of waste auger 40 is connected to the drive shaft 47 
of a hydraulic motor 50 which is mounted on a plate 52 defining the other 
end of waste trough 36. Motor 50 physically supports and rotatably drives 
its associate waste auger 40 in the direction of arrow 54 (see FIG. 2) to 
discharge the waste material which collects in waste trough 36. 
Machine 10 comprises a product inlet or infeed opening 60 at one end 
thereof and a product outlet or discharge trough 62 at the opposite end 
thereof. Infeed opening 60 is located on the upper side of framework 12 
and communicates with an inlet hopper 64 which is mounted on framework 12 
below opening 60. Inlet hopper 64 comprises a semi-cylindrical inlet 
trough 65 which is closed at one end by an end plate 66 which has a 
shaft-receiving hole 68 therethrough. The other end of inlet hopper 64 is 
open and communicates through an opening 13A in end plate 13 with the 
inlet end of trough 18. Discharge trough 62 is located on the end of frame 
12. Discharge trough 62 has a product discharge chute 70 which extends 
through end plate 19 to the end of rollers 14 to receive the product P 
from trough 18 for discharge. 
The product mobilizer apparatus 11 for machine 10 generally comprises a 
pair of elongated rotatable driven helically-shaped three-quarter flight 
stainless steel rigid rods 72 and 74, which are rotatable in trough 18 
about the horizontal axis 16 hereinbefore mentioned; a rotatable driven 
one and one-half flight discharge auger 75 which is rotatable in trough 18 
at the discharge end thereof; and a rotatable driven two-flight infeed 
auger 77 which is rotatable in inlet hopper 64. The helical rods 72 and 
74, the discharge auger 75 and the infeed auger 77 are connected to and 
rotatable with a common drive shaft 78 in the direction of arrow 79 (see 
FIGS. 3 and 4). The opposite ends of shaft 78 are supported on 
antifriction bearings 81 and 82, respectively. Bearing 81 is supported on 
a bracket 81A which is mounted on framework 12. Bearing 82 is mounted on 
channel 12A of frame 12. Each helical rod 72, 74 is connected to shaft 78 
by two pairs of support rods 84 of appropriate length. The end of drive 
shaft 78 which extends through hole 68 in end plate 66 is connected to and 
driven by a drive sprocket 85. Driven sprocket 85 is connected by an 
endless flexible drive chain 87 to a drive sprocket 88 which is mounted on 
and rotatable with the drive shaft 89 of a hydraulic motor 90 which is 
mounted on framework 12. 
As FIG. 7 shows, the drive and control system for machine 10 includes a 
hydraulic pump 92 for supplying hydraulic fluid to operate the hydraulic 
motors 29, 50, and 90. Pump 92, which is mounted on reservoir R, is driven 
by an electric motor 93 which is also mounted on reservoir R. Adjustable 
flow control valves 94, 95, and 96 are provided in the fluid supply lines 
97, 98, and 99, respectively, for the hydraulic motors 29, 50, and 90, 
respectively, to control the rotational speed thereof. A flow divider 110 
is connected in the hydraulic circuit between valve 94 and the motors 29. 
A pressure relief valve 106 is connected in the hydraulic circuit between 
pump 92 and the motors 50 and 90. An on-off switch 100 is provided for in 
the electrical supply line 101 for electric motor 93. The hydraulic pump 
92 and electric motor 93 are mounted on a tank or reservoir R which is 
mounted to frame 12. 
Operation 
The machine 10 operates as follows. Assume that switch 100 is closed, 
electric motor 93 is energized and rotating, pump 92 is rotating and 
supplying fluid through the flow (speed) control valve 94, and through 
pressure relief valve 106 and flow control valve 94, to the hydraulic 
motors 29, 50, and 90, respectively, and that the processing rollers 14, 
the waste auger 40, and the product mobilizer apparatus 11 are rotating. 
Also assume that the flow control valves 94, 95, and 96 are set or 
adjusted to operate their respective components at a desired rotational 
speed, i.e., 0 to 500 rpm for the processing rollers 14, about 50 rpm for 
waste auger 40, and about 1 to 12 rpm for the product mobilizer apparatus 
11. Further assume that water flow control valve 35 is open and that the 
spraying apparatus 39 is in operation. 
Now assume that products, such as potatoes, which are to be washed and 
peeled, are supplied through infeed opening 60 into inlet hopper 64. As 
this occurs, infeed auger 77 moves the products into the processing trough 
18 wherein the processing rollers 14 engage and act upon (by brushing, 
scraping, or abrading) the products therein. As the helical rods 72 and 74 
rotate, they pass through and under the products, causing the product 
layer next to the processing rollers 14 to be moved upwardly. This creates 
a positive tumbling action which ensures that all products and all sides 
thereof are exposed to processing roller action. The rods 72 and 74 also 
cause the products to move positively through trough 18 from the infeed 
toward the discharge end thereof. The auger 75 at the discharge end of the 
product mobilizer positively discharges the products from the trough 18 
and, depending on an increase or decrease in its rotational speed, can 
decrease or increase, respectively, the quantity of products left in the 
trough, and thereby serves as a means for regulating or controlling the 
product load within the machine at any given time. Furthermore, the depth 
of the load in trough 18 is important because the weight of the product on 
the processing rollers 14 determines the degree of aggressiveness of the 
roller action on the products. The products are moved by discharge auger 
75 through discharge trough 62 onto discharge chute 70 from whence they 
are loaded into bins (not shown) or onto a discharge conveyor (not shown). 
As processing occurs in trough 18, the water from spray apparatus 39 washes 
the waste material brushed or abraded from the products between the 
processing rollers 14 into the waste hopper 33 from which it is expelled 
through opening 37 by waste auger 40.