This application claims priority from German application DE 10 2010 060 325.2 filed on Nov. 3, 2010, which is incorporated in its entirety by this reference.
The invention relates to a method for cutting a food strand into slices including the steps of:
a) feeding the food strand forwards at a feed velocity to a cutting device having a rotating blade;
b) successively cutting off slices with the cutting device from the food strand at a forward end in feed direction during feeding;
c) placing the cut off slices onto an intermediary storage device moveable transversal to the feed direction and in the feed direction in order to form a portion after cutting the slices off from the food strand, wherein a stacked or fish scaled slice arrangement with a total of n slices is generated and n is a natural number greater than or equal to 3;
d) moving the intermediary storage away from the cutting device with feed velocity; and
e) transferring a non-finished portion including m slices, wherein m is a natural number and m<n, in its entirety from the intermediary storage device to a conveying device, wherein the slices are extracted through the conveying device, wherein the transferred portion after being transferred to the conveying device is completed by cutting off and adding one additional slice and is subsequently extracted.
DE 197 13 813 C1 discloses a method in which a transfer of a partial portion from the intermediary storage which is configured as a fork is provided to a feed device which is configured as a conveyor belt. The feed device is moveable relative to the cutting device, in particular relative to its blade in vertical direction. Transferring a partial portion from the intermediary storage device to the conveying device is provided so that the intermediary storage device continuously moves away from the cutting device with the feed velocity and penetrates with its tongs into the intermediary spaces between adjacent drive belts of the conveying device. Thus the storage conditions, this means the vertical distance between the cutting plane and the top side of the slice that has been cut off last and already stored is being maintained constant. After transferring the partial portion to the conveying device it is required for keeping the storage conditions constant that the conveying device moves away with feed velocity from the cutting device while cutting off the slices that are still missing to form a complete portion. The feed device only stops this lowering process when the last slice of a portion has been cut off and deposited. Thereafter the horizontal extraction of the completed portion is initiated and the intermediary storage device that has been moved into its idle position in the mean time can be moved back into the cross section of the food strand in order to start receiving the next partial portion slice by slice.
It is disadvantageous for the known method that the intermediary storage device and also the feed device have to be synchronized in their vertical movements with the feed movement of the food strand in vertical direction. This places stringent requirements on the type of drives and on the control. In particular the point in time of the transfer when the partial portion switches from being placed on the intermediary storage to being placed on the feed device has to be determined precisely.
Another method is furthermore known from, for example, U.S. Pat. No. 3,842,692. The device as disclosed in this printed document in
The two intermediary storage devices are being used in order to be able to provide feeding of the food strand continuously, this means continuously without interruptions when transporting out completed portions. While one portion is still on the first intermediary storage device or is just being taken over by the transfer element, the second intermediary storage device is already in an idle position or in a receiving position moved under the cross section of the food strand, so that the cutting process can be continued without interruption.
This does not only provide advantages with respect to the cutting performance which is accordingly high based on the continuity of the cutting process, but also avoids interrupting the feed movement which is always critical. Deviations in the feed velocity, in particular a short term stoppage of the food strand leads to problems in the feed device due to vibrations namely in particular for softer and deformable foods (e.g. pork sausage, meat loaf, ham, sausage, cheese etc.). Due to calibrations nozzles shortly above the blade the feeding of the food strand has high friction. Additionally, there is a so called “slip stick effect” this means when undercutting a particular feeding force the food strand suddenly breaks loose, this means uneven feeding of the food strand occurs. Due to the strong dynamics of all movements longitudinal vibrations at the knife side end of the material strand cause the food strand to protrude by a small amount below the blade plane in spite of a wanted stop, which leads to cutting off small food pieces (snipping effect). In particular for self service packages using clear foil as packaging material slice fragments of this type are not acceptable since they are perceived as substantial optical deficiency. Providing a continuous feeding without interruption is therefore an essential prerequisite for obtaining high cutting performance and in particular first class cutting quality so that the cut off slices always have an identical geometry.
Whereas the latter problem has been solved for the method according to U.S. 3,842,698, its design complexity is high and the control algorithms for controlling the movements of the many device components are complex.
It is the object of the invention to provide a method for cutting a food strand into slices, wherein high cutting performance and high geometrical precision of the cut off slices can be implemented with low design complexity.
The object is achieved through a method as recited supra in that after transferring the unfinished portion onto the feed device a distance between a top side of the last cut off slice and a bottom side of the blade is successively reduced with each additional slice produced. The invention is based on the finding that the storage conditions for generating portions with high geometric precision are not only optimum or acceptable for a particular distance, but also that the function of the placement quality over the distance between the bottom side of the blade and the top side of the slice placed last extends very flat in the range of the optimum distance. This means that the distance between the bottom side of the blade and the top side of the partial portions already formed can be varied within particular limits without the storage quality being significantly impaired. The invention uses this finding in that in the end phase of producing a portion, this means after transferring a partial portion from the intermediary storage device to the conveying device the distance between the top side of the partial portion and the bottom side of the blade is not kept constant any more through an active vertical movement of the conveying device but that after transferring the partial portion onto the conveying device an increase of the height of the partial portion is permitted until the final stacking height is reached.
According to the method according to the invention a vertical adjustment of the partial stack is only performed during the phase in which the partial stack is still on the intermediary storage. Only the intermediary storage device therefore has to be capable to change its position in vertical direction as a function of the feed velocity. On the other hand side a vertical position change of this type is not performed any more after the transfer onto the conveying device is performed so that with a further increase of the portion height the distance between the top side of the portion and the bottom side of the blade is successively reduced with each additional slice. As already stated supra a reduction of the distance of this type does not lead to a perceivable deterioration of the storage quality when the distance previously was slightly greater that the “optimum distance” and through producing the last slice was only slightly smaller than the “optimum distance”.
Another prerequisite for obtaining sufficient cutting quality with the method according to the invention is the fact that the number of the slices which are cut off after the partial portion is transferred to the feed device does not exceed a particular number. Exceeding a particular number, however, is not required according to the method according to the invention since only a certain number of slices still have to be cut off after transferring the partial portion to the feed device, wherein the number of slices is required for moving the intermediary storage device back into the idle position. Thus while a synchronous movement of food strand and intermediary storage device can be provided maintaining constant storage conditions while the partial portion is formed on the intermediary storage device the distance to the conveying device standing still in vertical direction is successively reduced with each added slice after the partial portion is transferred.
According to an advantageous embodiment of the method according to the invention the intermediary storage device is moved away from the cutting device after storing m slices on the intermediary storage device with a velocity which is greater than the feed velocity of the food strand which transfers the non-finished portion to the feed device, wherein a distance between the blade of the cutting device and the top side of the m-th slice when transferring the non-finished portion from the intermediary storage to the feed device is greater than during cutting off the first m slices.
This way the storage conditions while cutting the first m slices can be kept constant, whereas transferring the non-finished portion to the feed device is performed after a drop of the intermediary storage into the conveying device with maximum dynamics. Starting with the point in time of the transfer the distance between the top side of the m-th slice and the bottom side of the blade is then increased and successively reduced with each additional cut off slice up to the n-th slice. It is important that the distance at the point in time of transferring the unfinished portion is sufficiently large in order to be able to receive all slices of the portion which still need to be cut off without a collision between the blade and the top side of the n-th slice occurring.
An embodiment of the method according to the invention includes moving the intermediary storage device so that the respective distance between the top side of the first slice to the m-th slice is greater than the respective distance of the (m+1)-th slice to the n-th slice. In this case the distance between the top side of the portion and the bottom of the blade is only minimal at the point in time when the n-th slice, this means the last slice, is cut off, whereas it is greater than cutting off all preceding slices. Thus the intermediary storage device can be moved downward when cutting off the first m slices, this means up to the point in time of transferring the non-completed portion to the conveying device with the feed velocity of the material strand, wherein constant placement conditions are provided during this phase of the cutting process. A successive reduction of the distance between the portion top side and the bottom side of the blade only occurs after the point in time when the portion is transferred to the feeding device. The advantage of this method is that dynamic movements of the loaded intermediary storage device are not necessary.
Furthermore there is also the option to increase the distance between the top side of the partial portion and the bottom side of the blade while cutting off the first m slices. This increase can be performed immediately when producing the first slice but it can also be provided after a particular number of slices have already been cut off and stored. The distance reduction is achieved in that the intermediary storage device is moved away from the blade with a greater velocity than the feed velocity of the material strand. This way it is possible to store the first slice or the first slices with a particularly small distance between the top side of the slice stored last and the bottom side of the blade. This continuous distance increase provides the necessary increased distance at the point in time when the partial portion is transferred in order to provide sufficient reserves for storing the last n−m slices on the conveying device that is standing still in vertical direction. In turn highly dynamic movements of the intermediary storage device can be omitted for this method.
In the method according to the invention thus the storage conditions after transferring a non-completed portion to the feed device are changed voluntarily, thus in a sense that the distance between the cutting plane and the surface of the slice cut off last is successively reduced with each additional slice. This has the advantage that a synchronization of a vertical movement of the conveying device with the feed movement of the food strand is not required. The requirements upon the control and the precision of the conveying device are thus smaller for the methods according to the invention which affects costs favorably.
According to an embodiment of the invention the conveying device stands still at least in vertical direction at the point in time in which the non-finished portion is handed over to it from the intermediary storage device. This helps reducing control complexity and device complexity with respect to the type of the drive of the feed device in vertical direction. When the conveying device stands still in vertical direction it is important at the point in time when transferring the non-finished portion to the conveying device to provide a distance in vertical direction to the cutting plane so that when the conveying device stands still in vertical direction during the entire cutting process, so that sufficient vertical space is provided for storing all slices that still need to be cut off in order to complete the portion (number n−m).
Thus, in this case the distance between the top side of the m-th slice and the blade of the cutting device is a maximum and the distance is reduced again when additional slices are cut off (when the conveying device stands) still in vertical direction, wherein advantageously the storage conditions when cutting off the last, this means the n-th slice of a portion are the same again as they were while cutting off the first m slices of the portion.
The method according to the invention thus leads to a change in the storage conditions during a transition time in order to thus gain time for bringing back the intermediary storage device. This gains time namely through the accelerated lowering and the “premature handover” of the non-finished portion to the feed device measured by the vertical distance, wherein the time gain can be used for moving the intermediary storage device back into its idle position in order to be able to insert the intermediary storage device in a timely manner back into the food cross section or its projection into the cutting plane when beginning to generate the next portion.
An improvement of the method according to the invention is characterized in that the distance between the blade of the cutting device and a surface of the cutting device before beginning the cutting process as a function of the number n of the slices of the portion to be produced and a thickness d of a particular slice is adjusted. In particular the recited vertical distance is determined from the multiplication of the number n of the slices and their thickness d plus a distance A0 which provides safe clearance for the blade and typically is in a range of a few millimeters.
During tests it has become apparent that it is favorable in particular when the number n of the slices of a completed portion is greater by 2 to 4, advantageously by 3 than the number n of the slices of a non-finished portion when it is transferred from the intermediary storage device to the feed device. This facilitates a sufficient time gain in order to move the intermediary storage device back into its idle position after transferring the non-finished portion to the conveying device or to then also move the intermediary storage device back into the food cross section. Thus, it has also become apparent that increasing the storage distance by such an amount as it is required for subsequent generation and storage of two to four or preferably three vertically stacked slices the storage quality is not significantly deteriorated. As a matter of principle a more “premature” transfer of the non-finished portion to the feed device can increase the time available for moving the intermediary storage device back, wherein however the storage conditions are increasingly deteriorated through stronger vertical lowering of the unfinished portion with an increasingly earlier transfer, at least when the conveying device stands still in vertical direction. The recited number n−m=3 of slices which still have to be produced after the transfer to finish the respective portion thus has proven to be an ideal compromise.
Thus, the method according to the invention omits the transfer element known from U.S. Pat. No. 3,846,698 and therefore substantially reduces manufacturing complexity. Thus, a direct transfer of the partial portion to the feed device is provided without using other components there between. Not only the engineering complexity is reduced, but the invention also simplifies control when implementing a device according to the new method since the complex adjustment between intermediary storage device and transfer element on the one hand side and transfer element and conveying device is reduced to an adjustment between intermediary storage device and conveying element.
Producing a finished portion is provided in two phases according to the method according to the invention, namely one phase in which the intermediary storage device is initially used as a support device for the portion being produced. After a particular amount of time, this means producing a particular number of slices of the portion currently being produced the portion is placed on the feed device during the ongoing cutting process, this means in particular also when the feeding is continued unchanged and the rotation of the blade is unchanged which is not critical, because the storage, this means adding additional slices is performed on the top side of the portion, whereas changing the support from the intermediary storage device to the feed device is performed on the bottom side and therefore can be configured so that it does not cause any interferences on the top side of the portion being created.
A particularly simple transfer of the cut off slices from the intermediary storage device to the feed device is facilitated when the support elements of the intermediary storage device penetrate the intermediary spaces between adjacent belts of the feed device during transfer, wherein a surface of the support elements which supports the slices is arranged below a surface of the belts of the conveying device after the transfer. Through the penetration a change of the support of the slices occurs from the intermediary storage device to the feed device.
In another embodiment of the invention it is proposed that the intermediary storage device performs a movement including translatoric movement sections along a closed path, wherein the intermediary storage device:
Transferring the cut off slices from the intermediary storage device to the conveyor belt can be advantageously provided through a relative movement in feed direction between the intermediary storage device and the conveying device. Thus, the intermediary storage device is lowered accordingly for an advantageously still standing conveying device.
During cutting operations when producing simple vertical (non-fish scaled) slice stacks the conveying device or before that also the intermediary storage device is lowered by the thickness dimension of the slice for each newly added slice successively or with a corresponding mean velocity continuously per section in order to provide a constant distance between the cutting plane of the blade and the storage surface for the newly created slice during the entire cutting process, wherein the storage surface is provided in the form of the surface of the intermediary storage device or of the surface of the last slice that has already been cut off.
In order to facilitate a quick insertion of the intermediary storage device in the moment of activating the intermediary storage device for receiving the first slice of a new portion it is helpful that the intermediary storage device with the surface of its support elements is in the same plane as the surface of the last completely cut off slice on the conveying device, wherein the surface is oriented towards the food strand in the idle position of the intermediary storage device. For a continued lowering of the conveying device (continuously or in increments) the exact amount of vertical space is provided above the already cut off and slightly lowered slices in the next moment so that the intermediary storage device can be inserted into the strand cross section transversal to the feed device.
In order to have sufficient time for inserting the intermediary storage device into the strand cross section the intermediary storage device can leave the idle position only when the blade has already started to cut off another slice and is already within the cross section of the food strand. On the particular critical time conditions, this means under a high cutting frequency and an accordingly high cutting performance the intermediary storage device during its movement into a projection of the cross section of the food strand in a plane orthogonal to the feed direction can even lift a portion of the slice that is currently being produced, wherein the portion already hangs down due to gravity or even contacts the previously cut off slice, wherein the lifting is performed with the surface of the support elements of the intermediary storage device. This way a starting storage of the newly produced slice on the slices of the preceding portion is reversed again through transferring the intermediary storage device into the receiving position in order to associate the currently produced slice with the new portion, this means with the intermediary storage device.
According to another embodiment of the method according to the invention the intermediary storage device penetrates from one side into the cross section of the food strand and the blade of the cutting device penetrates the cross section of the food strand from the opposite side. Thus, collisions between the intermediary storage device to be inserted and a completed portion are prevented on the feed device during transporting. Also the insertion can be time delayed far enough so that downward extending portions of a slice that is being created are lifted off from the inserting intermediary storage device and picked up, wherein precise storage conditions can also be provided for an extreme time based arrangement of this type.
From a device point of view the intermediary storage device advantageously includes support elements which are arranged so that they can be positioned in intermediary spaces between adjacent belts of the feed device, wherein a plane defined by the surface of the support elements extends parallel to a plane defined by the surface of the belts of the feed device. Since the planes are parallel, a transfer of the slices from the intermediary storage device to the belts is configured particularly gentle which provides high quality of the placement geometry. Advantageously the intermediary storage device is configured fork shaped and the supports elements are configured tongue shaped and arranged at a support beam and preferably welded together therewith.
In order to provide high dynamics when moving the intermediary storage device the mass of the intermediary storage device that shall be accelerated quickly shall be kept as low as possible. Therefore, the height of the support elements measured in feed direction shall be smaller than twice the thickness, advantageously smaller and 1.5 times the thickness of the slices to be cut off in particular smaller than 10 mm, advantageously smaller than 8 mm, particularly advantageously shall be between 4 mm and 6 mm. The mass of the intermediary storage device should be less than 0.5 kg advantageously less than 0.3 kg. For a material for the intermediary storage device in particular for the support elements besides stainless steel or aluminum alloys also fiber reinforced plastic material in particular using carbon fibers is suitable.
From a design point of view it is advantageous when the intermediary storage device is moveably supported perpendicular to the feed direction in a receiving frame and the receiving frame is moveably supported in feed direction at a machine frame, wherein the receiving frame includes two linear supports for the intermediary storage device arranged laterally adjacent to the feed device. A receiving frame according to the instant application is not necessarily a closed arrangement of the members. This rather also includes a three sided, this means U shaped arrangement of members which is helpful in order to be able to implement support devices for the intermediary storage device at both sides adjacent to the conveying device. For the linear supports in particular also a drive using a timing belt is suitable, wherein the timing belt provides operation without slippage even for movements with highest dynamics.
Typically the conveying device is followed by an extraction device also configured as a band with a plurality of belts extending parallel to one another. In order to provide a continuous transition between the conveying device and extraction device when moving the conveying device, in particular on the side of the conveying device oriented towards the extraction device, the feed device can be supported at a extraction frame together with an extraction device, wherein the extraction frame is adjustably supported, in particular moveably or pivotably supported at a machine frame.
In order to also be able to implement a fish scaled storage of slices on the intermediary storage device before transferring them to the conveying device the support elements of the intermediary storage device should have a length measured perpendicular to the feed direction which is at least twice the width of the cut off slices measured perpendicular to the feed direction, preferably at least three times the width.
In order to prevent time based problems in the time critical phase of inserting the intermediary storage device, the intermediary storage device starting from its idle position shall be insertable in the same direction into a projection of the cross section of the food strand into a plane which is formed by the support elements of the intermediary storage device, wherein the cut off slices are transportable by the conveying device in the same direction.
It provides further time relief for the cutting process when the intermediary storage device enters from one side into a projection of the cross section of the food strand into a plane which is formed by the surface of the support elements of the intermediary storage device, wherein the surface is opposite to a side where a slice that is being created disengages from the food strand driven by gravity.
The method according to the invention is subsequently described based on an embodiment of a device with reference to drawing figures and two diagrams, wherein:
A device 1 for cutting a food strand 2 (e.g. sausage, cheese etc.) illustrated in
On a side of the cutting plane 7 that is oriented away from the food strand 2 and the feed device 10, there are adjacent and partially overlapping with one another an extraction device 10, a conveying device 14 and an intermediary storage device 15. The intermediary storage device 15 is formed as a fork and includes a plurality of support elements 16 that are arranged in parallel and equidistant to one another and configured tongue shaped and a support beam 17 that extends perpendicular to the support elements and is connected therewith. The intermediary storage device 15 is supported in a receiving frame 18, thus so that it is movable perpendicular to the feed direction, this means parallel to the cutting plane 7. Thus, the support beam 17 is supported respectively at both longitudinal ends in a respective linear support 19 which is respectively arranged in the interior of a longitudinal member 20 of the receiving frame 18. The drive of the intermediary storage device 15 in a direction of the linear support devices 19 is provided through a timing belt 21 which is connected with the support beam 17 on both sides of the intermediary storage device 15 through a coupling element.
The receiving frame 18 as such is movable in a direction (double arrow 22) parallel to the feed direction (arrow 9) within a machine frame 23 that is schematically illustrated in
The conveying device 14 includes a plurality of belts 29 which are arranged equidistant from one another and which form a common conveying plane 28 on their top side, wherein the belts are run about two deflection rollers 30, 31 including ring grooves for the belts 29, wherein one of the deflection rollers is drivable through a servo drive. The inner distance between two adjacent belts is slightly greater than the width of the support elements 16 measured perpendicular to the longitudinal extension of the fork shaped support elements 16. Since the pitch of the belts 29 of the conveying device 14 corresponds to the pitch of the support element 16 of the intermediary storage device 15, the latter can penetrate intermediary spaces between adjacent belts which is important for the transfer of cut off slices from the intermediary storage device 15 to the feed device 14 described infra.
The extraction device 13 like the conveying device 14 includes a plurality of belts 32, whose width is substantially greater than the width of the belts 29 of the conveying device 14. A deflection roller of the extraction device 13 is arranged close enough to the deflection roller 30 of the conveying device 14 so that the belts 29, 32 do not collide with one another, which provides a transfer from the conveying device 14 to the extraction device 13 which does not impair the slice arrangement.
The extraction device 13 is supported in an extraction frame 34 which is pivotably supported in the machine frame 23 about the rotation axis of a deflection roller 35. The end of the extraction device 13 which is associated with the deflection roller 33 of the extraction device 13 is connected in
The method according to the invention is subsequently illustrated in more detail wherein the particular method steps are described with reference to the drawing figures, wherein:
It is evident from
According to
Contrary to providing the fish scaled portions according to
Comparable with the situation according to
In
On the other hand side,
Now the intermediary storage device 15 can be pulled out of the projection of the cross-section of the food strand 2 in a next step perpendicular to the feed direction (intermediary position c.f.
It is essential for the transfer in the illustrated variant of the method according to the invention that the storage conditions are changed, this means a greater distance between the top side 42 of the unfinished portion and the cutting plane is provided in a preliminary manner in that the intermediary storage device 15 quickly penetrates into the conveying device 14 that is standing still in vertical direction. When cutting off the subsequent three slices 10, 11, 12 of the portion to be completed, the storage conditions change while reducing the vertical distance successively so that when storing the n-th, this means the 12th slice, the same storage conditions are provided again as they were provided when storing the first nine slices of the portion due to the synchronous movement of food strand 2 and intermediary storage device 15.
In
The dotted line shows that the travel of the intermediary storage device is already by a thickness of 3 slices greater than in the previously described method already at the beginning of the cutting process. As a consequence the travel of the intermediary storage device 15 after cutting off the 9th slice is already large enough so that a sufficient buffer distance between the top side 42 of the 9th slice and the bottom side 43 of the blade 5 is provided, wherein the last three slices can be stored on the conveying device 14 that is standing still in vertical direction. The accelerated downward movement of the intermediary storage device 15 after storing the 9th slice as illustrated in the form of solid lines in
The procedure illustrated in dash dotted lines in
Number | Date | Country | Kind |
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10 2010 060 325.2 | Nov 2010 | DE | national |