The present invention relates to a packaging machine and a method for filling bulk materials into packages, wherein the packaging machine comprises a rotatable machine frame and a plurality of filling spouts distributed over the circumference of the packaging machine, so as to fill bulk materials into packages while the packaging machine respectively the machine frame is rotating. The machine frame is provided with a machine silo with a storage volume for storing a quantity of bulk materials for filling a plurality of packages. The bulk materials are conveyed from the machine silo to each of the filling spouts and filled into the associated or attributed or appended packages.
The invention relates in particular to a packaging machine and a method for bagging fine-grained and dusty bulk materials, such as cement, mortar products, calcium hydroxide, etc.
In the prior art, a great variety of packaging machines and methods have been disposed for bagging fine-grained and dusty bulk materials such as cement into packages. When filling bulk materials into packages such as open-mouth bags or valve bags, a (small) quantity of air is introduced as a rule so as to maintain flowability of the bulk materials and ensure an effective and efficient bagging operation. When the bulk materials intended for filling contain too little air during filling, then the flowability decreases, the bulk materials may be prone to bridging, and the bagging conditions deteriorate. When the bulk materials contain too much air during filling, there is the drawback that after the process the filled packages are larger than they need to be. The de-aeration time also increases, slowing down the filling process. Moreover, they show a low surface firmness. Packages filled with bulk materials appear more attractive and more stable with a lower air proportion. Moreover, a lower air proportion involves decreased material requirements for the packages respectively bags, so as to decrease the costs for the packages. At the same time the stowage volume decreases so that the transport costs decrease as well.
This is why packages filled with bulk materials are being de-aerated even during filling or right thereafter to remove at least part of the entrapped air.
It has been found that the conditions while filling bulk materials into packages change during the operation. Thus, seasonal fluctuations may occur. Furthermore, the flow behavior of the bulk materials may also be related to the ambient temperature and the ambient humidity. It has also been found that following a standstill of the packaging machine—when the product has settled—the filling conditions differ from those in an ongoing operation.
It is therefore the object of the present invention to provide a packaging machine and a method for filling bulk materials into packages which allow an efficient filling of bulk materials into packages and which achieve more uniform filling results.
A packaging machine according to the invention for filling bulk materials into packages is configured rotatable respectively comprises a rotatable machine frame. Over the circumference of the packaging machine or the machine frame, a plurality of filling spouts is disposed so as to fill bulk materials into packages while the machine frame is rotating. It is conceivable for the packaging machine to be configured for filling valve bags. It is also possible that the packaging machine is configured for filling bulk materials into open-mouth bags or other packages. The machine frame is provided with a machine silo with a storage volume for storing a quantity of bulk materials for filling a plurality of packages. Bulk materials can be filled into the associated or attributed and in particular appended packages from the machine silo through the filling spout or spouts. The machine silo is in turn connected with (at least) one material supply with a controllable closing head or closing member for feeding bulk materials to the machine silo. In this case, this means that the machine silo serves as an intermediate silo in which a storage volume for filling a plurality of packages is configured. Therefore, the bulk materials do not need to be supplied separately for each package from an external silo. A control device is provided with which to control the closing member of the material supply dependent on the fill level, so as to reduce the height of fall of the bulk materials while the bulk materials are being fed into the machine silo, or so as to avoid, in particular largely and preferably to the greatest extent possible in continuous operation, free fall of the bulk materials into the machine silo while feeding the bulk materials.
The packaging machine according to the invention has many advantages. A considerable advantage of the packaging machine according to the invention consists in the fact that in continuous operation of the packaging machine, the bulk materials are largely or entirely prevented from falling freely into the machine silo, or that the height of free fall is reduced as far as possible. Also preferred is sub-level filling wherein free fall of the bulk materials is virtually nonexistent in regular operation. The invention causes substantially the same characteristics of the bulk materials filled into the machine silo in any and all the continuous operating scenarios. The fact that the height of fall is minor and free fall is in particular avoided as far as possible, considerably reduces any air entering into the bulk materials while filling the machine silo.
Therefore, the bulk materials in the machine silo show considerably more homogeneous conditions than in the prior art where bulk materials were filled into the machine silo at intervals from a height of fall of for example 1 m or 2 m (min-max control). Thereafter the bulk materials were filled directly into the packages or the system was stopped for example due to maintenance, so that the bulk materials stored in the machine silo could be de-aerated prior to starting filling. These different conditions in turn also result in different conditions of the filled packages. The invention considerably reduces these kinds of differences. A continuous filling process is ensured and the weight accuracy is in particular also improved. Thus, the reject rate of underweight packages is also reduced.
In the case of a conventional rotary packaging machine, the subsequent supply of bulk materials into the machine silo is done by feeding bulk materials to the silo at periodic intervals in free fall through the non-rotary cover. As a rule, this will cause considerable dust formation in subsequent supplies. The bulk materials thus take up much air which changes their flow characteristics. Moreover, sealing measures notwithstanding, the sealing gap between the rotating silo and the stationary cover, and cracks and openings, let escape a comparatively large quantity of dust. This requires a larger air volume for dust removal, which in turn increases the system costs and the overhead. By means of the invention, no (or a very small quantity of) air is introduced into the product while replenishing the silo, since the bulk materials are largely prevented from freely falling. This causes much more homogeneous conditions over time than in the prior art, already in the (rotary) machine silo. Changes to the product characteristics over time due to the periodic air intake in replenishing are avoided, and changes to the product characteristics during standstill are also reduced since the product contains less air which may escape over time.
Another considerable advantage is that energy consumption for dedusting is reduced. Packing silos filled in free fall according to the prior art tend to generate dust, and vacuuming involving a large volume flow is required to reduce dust pollution. Also, this causes considerable loss of material.
In all the configurations it is preferred for the machine silo to be connected with the filling spout for example through product travel paths or conveying ducts. Preferably one conveyor element is provided for each filling spout for (controlled) conveying of the bulk materials into the attributed or appended package.
In preferred specific embodiments the control device is configured as a passive control device. The control device can in particular be configured mechanical.
Preferred specific embodiments provide for the closing member to be coupled with a pivoting lever and/or a paddle. The pivoting lever may be in particular mechanically coupled directly with the closing member. Alternately, it is possible for the pivoting lever to be coupled with the closing member through a deflector or a motor coupling. Also conceivable is a hydraulic or pneumatic coupling where the closing member is pivoted along, for example through a swivel cylinder, as the pivoting lever is pivoted.
The closing member preferably comprises at least one valve gate mechanism. A valve gate mechanism may e.g. be configured as a flap gate mechanism. It is also possible e.g. for the valve gate mechanism to comprise a shut-off gate or a flap shutter or the like. A shut-off gate or the like may enter the closing member e.g. from the side, thus reducing the clear flow cross-section continuously or in steps.
The (mechanical) pivoting lever is preferably provided for detecting the fill level of the bulk materials by way of contacting the bulk materials in the machine silo. In these configurations, the pivoting lever may serve as a simple passive control device. The height of the fill level is directly detected by way of the pivot position of the pivoting lever. This configuration allows a configuration of a packaging machine according to the invention which is permanently functional and offers ease of maintenance.
In the scope of the present invention, the term “pivoting lever” may be consistently replaced by the terms “pivoting member” or “pivoting unit”.
The pivoting lever preferably rests (at least partially) on the bulk materials in the machine silo (as far as the fill level reaches). It is possible and preferred for the pivoting lever to be at least partially immersed in the bulk materials in the machine silo. The pivoting lever glides in particular partially on the material level of the bulk materials. The pivoting lever may glide on the bulk materials as in “waterskiing”. The product stream, which moves in a circle relative to the pivoting lever during rotation of the machine frame, suitably deflects the pivoting lever so that the position of the pivoting lever is a measure of the fill level of the bulk materials. The pivoting lever may form part of a sensor device. The sensor device serves to capture the fill level of the bulk materials in the machine silo.
In preferred configurations the pivot axis of the pivoting lever is oriented transverse and in particular off-center to the pivot axis of the machine frame. The pivot axis of the pivoting lever may for example be oriented approximately horizontally, while the rotation axis of the machine frame is preferably oriented vertically. In preferred configurations, the pivot axis of the pivoting lever is in particular oriented approximately radially but it may be vertically inclined. In preferred configurations the pivot axis is approximately in a plane including, or parallel to, the rotation axis. The angle at which the pivot axis intersects the plane with the rotation axis of the machine frame is preferably <30° and preferably less than 15°. These kinds of parameters achieve an advantageous configuration wherein during rotation of the machine frame a pivoting lever may rest on, or be immersed in, the bulk materials, thus permitting useful detection of the fill level.
Also conceivable is a vertical or inclined pivot axis of the pivoting lever e.g. by way of utilizing the stagnation pressure and a return spring. One may for example, utilize the stagnation pressure on a paddle which is preloaded by a restoring device and which is deflected counter to the force of the restoring device as the fill level increases, thus capturing a measure of the fill level. A closing member controlling the supply to the machine silo may be directly (mechanically) coupled therewith.
In preferred specific embodiments, the pivoting lever is preloaded in particular downwardly by means of a spring device. In this way the pivoting lever is reliably pressed onto the surface of the bulk materials storage in the machine silo. Preferably, the spring device comprises at least one gas spring. A gas spring offers the advantage that as the spring force is exceeded, rebound is readily possible. In preferred configurations a piston cylinder unit is used as a spring device, or the spring device comprises at least one such piston cylinder unit. Piston cylinder units also enable hydraulic or pneumatic coupling of the pivoting lever with the closing member. In all the configurations, it is preferred for the material supply to comprise a filling pipe. Bulk materials are fed to the machine silo through the filling pipe. The filling pipe preferably comprises a stationary pipe section and a pivotable pipe section. The bulk materials for replenishment emerge from the pivotable pipe section.
The pivotable pipe section may preferably (also) directly serve as a pivoting lever. Then, at least one shaped part and e.g. one (or two or more) blade(s) may be configured thereat, or attached thereto, to ensure that the pivotable pipe section deflects as a function of the fill level. Then, no separate pivoting lever is required.
In other configurations a separate pivoting lever is provided, and the pivotable pipe section is pivotable together with the pivoting lever. Joint pivoting of the pivotable pipe section and of the pivoting lever may be realized by way of directly mechanically coupling the pivotable pipe section with the pivoting lever. For example, a chain drive or belt drive may be provided between the two pivotable members. Alternately, a hydraulic or pneumatic coupling is conceivable so that as the pivoting lever pivots, the pivotable pipe section co-pivots along. A spring device may also enable for example the pivoting lever to pivot further than does the pivotable pipe.
It is preferred for the closing member to be configured on the pivotable pipe section. The closing member may be configured for example as a flap shutter. It is also possible for the closing member to show a suitably configured circle segment structure which slides across the opening of the stationary pipe section as the pivotable pipe section is pivoting, thus decreasing and increasing the clear opening cross-section of the filling pipe. Preferably, the material supply is completely opened when the fill level is less than 30% or 40% or 50% or 60% or 70% of the maximum fill height. In particular is the pivoting lever disposed such that the closing member completely opens the (feed opening of the) material supply at least in the case that the pivoting lever is no longer immersed in the bulk materials or in the quantity of bulk materials respectively is no longer in contact with the product level. It is possible to open the feed opening completely when the fill level is less than 50% (or another suitable value) of the maximum fill height.
Preferably, the material supply is at least partially closed when the fill level is above 70% or above 80% or above 90% or 95% of the maximum fill height. In particular is the pivoting lever disposed so that the material supply is at least partially or suitably closed when the fill level reaches a suitable portion of the maximum fill height.
In advantageous specific embodiments, the closing member closes the feed opening of the material supply when the fill level reaches a specified height.
In all the configurations, it is preferred for the clear cross section of the feed opening of the material supply to be inversely proportional to the fill level. Alternately, a digital configuration is conceivable wherein the clear cross section of the feed opening is either entirely open or entirely closed. It is also possible for the clear cross-section of the feed opening of the material supply to be inversely proportional across a specific height range. It is for example possible for the feed opening to be entirely opened across a specific height range and to begin closing only as for example 50% (or 70% etc.) of the maximum fill height is reached.
In all the configurations, it is preferred that at least one contactless detector for sensing the fill level is comprised. The contactless detector may be a component of the sensor device. Such a contactless detector may be configured as a capacitive, inductive, optical and/or ultrasonic sensor and/or radar sensor or the like. Also possible is the use of multiple detectors which perform fill level measurements independently of one another, simultaneously or time-shifted. Such a contactless detector, or an additional, contacting detector may be used to permit active controlling. These detectors are also conceivable for monitoring the operation.
In the case of active controlling, an actuator is preferably provided for (supporting) the movement of the closing member. Purely active controlling is also possible.
In all the configurations, it is possible for the control device to (actively) control the position of the closing member as a function of the sensor signal of the sensor device.
A method according to the invention relates to filling bulk materials into packages by means of a packaging machine having a rotary machine frame and a plurality of filling spouts distributed over the circumference so as to fill bulk materials into packages while the machine frame is rotating. The machine frame is provided with a (co-rotating) machine silo with a storage volume for storing a quantity of bulk materials sufficient for filling a plurality of packages. The machine silo fills bulk materials into the packages (through product travel paths or conveying ducts) through a (selected) filling spout. At least one material supply with a controlled closing member is attributed to the machine silo so as to feed bulk materials to the machine silo. The subsequent supply of the bulk materials into the machine silo may be provided continuously. As a function of the fill level in the machine silo, a control device controls the closing member of the material supply to prevent the bulk materials from freely falling into the machine silo while bulk materials are being fed in continuous operation, or to reduce the height of the free fall as far as possible. In preferred specific embodiments and configurations, sub-level filling is permitted.
The method according to the invention also has many advantages. The method according to the invention allows considerable reduction of the air volume which is introduced while filling the machine silo with the bulk materials. This allows to provide considerably more consistent conditions in filling bulk materials into packages.
Another advantage is that the filling of the machine silo generates less dust requiring complex dedusting. This permits to reduce dust removal capacities so as to cut down on energy and costs. Also, the sealing between the rotary machine silo and the stationary cover can be simpler in configuration.
Depending on the configuration, it is possible that considerable free falling distances show when first filling the storage volume in the first start-up or following a change of products. Since these processes are comparatively rare and they are certainly known at the time, this may be taken into account in the directly following filling process so as to achieve consistent conditions in the filled packages again.
Further advantages and features of the present invention can be taken from the exemplary embodiment which will be described below with reference to the enclosed figures.
The figures show in:
This
While the bulk materials 2 are being filled into the package 3, a small quantity of air is as a rule introduced into the bulk materials 2 in the product travel path, so as to maintain the bulk materials 2 flowable and to provide homogeneous and reproducible conditions during the filling process. The bulk materials 2 are as a rule transported into the packages 3 through a conveyor element 9. Such a conveyor element may for example be configured as a conveyor turbine. Alternately, augers may be used or conveying by way of gravity, or other conveyor elements may be used.
A machine silo 6 is configured on the (rotatable) machine frame 4 above the filling spout 5 and the conveyor elements 9. The machine silo 6 provides a storage volume 7 for receiving a quantity of bulk materials 8. The storage volume 7 is larger than the volume of the largest possible package intended for filling by way of the packaging machine 1. In particular is the storage volume multiple times larger than the volume of one filled package 3.
The quantity of bulk materials 8 serves as a temporary storage for bulk materials so as to provide continuous and homogeneous conditions inside the packaging machine 1. In this way, the filling conditions can be maintained even and consistent.
Identical filling conditions are achieved in a considerably improved way in that the material supply 10 is controlled such that following the first filling shown in
The material supply 10 comprises a closing member 11 which is configured like a flap gate mechanism 17. The material supply 10 consists of a filling pipe 24 comprising a stationary pipe section 25 and a pivotable pipe section 26. The pivotable pipe section 26 is pivotable around the pivot axis 19. In relation to the rotational angle, the clear cross-sections of the stationary pipe section 25 and of the pivotable pipe section 26 are more or less flush to one another, thus clearing only part of the feasible cross section of the feed opening 28.
Thus the product flowing out of the storage silo backs up in the stationary pipe section, resulting in settling and deaeration. When “depositing” the bulk materials on the filled level respectively when introducing it beneath the filled level, an aeration of the bulk materials (product) and dust formation in the machine silo are drastically reduced. Moreover, the bulk materials are ensured to show considerably increased homogeneity in the machine silo and during filling.
The cross section of the stationary pipe section 25 and of the pivotable pipe section 26 may be round, triangular, square, polygonal, oval and/or rounded. The cross-sections may be adapted to the product. Intentional selection of the cross-sections of the pipe sections or interposing a valve gate or valve allow to take specific product characteristics into account.
The pivoting lever 16 is part of a sensor device 18 respectively preferably forms the sensor device 18, which is part of the control device 12. The control device 12 controls the position of the closing member 11 of the material supply 10. Another part of the control device is the gas spring 22 of the piston cylinder unit 23, with which the pivotable pipe section 26 and the pivoting lever 16 are preloaded to the illustrated lower position. When the fill level in the machine silo 6 continues rising, the product level of the bulk materials 2 reaches the lower edge of the pivoting lever 16, which is then raised by the bulk materials 2 during rotation of the machine frame 4 by way of pivoting around the pivot axis 19. In this way, the clear cross-section of the feed opening 28 is reduced, whereby the supply of bulk materials 2 is reduced in turn.
Thus, the closing member 11 has partially closed the feed opening 28 so as to reduce the further supply of bulk materials 2.
When the fill level 13 reduces again in the further operation, then the dead weight and the force of the piston cylinder unit 23 make the pivoting lever 16 pivot downwardly so that the closing member 11 once again clears a larger portion of the feed opening 28 for the material supply, such that more bulk materials 2 can now be filled into the machine silo 6.
When no bulk materials is discharged for bagging, the fill level rises up to the maximum and, by way of the pivoting lever 16 pivoting, results in closing the feed opening 28 in the end position.
In all the configurations, the free height of fall 14 of the newly supplied bulk materials 2 is always less in normal operation than is the diameter 15 of the pivotable pipe section 26. Preferably the free height of fall is nearly zero, or sub-level filling is realized. This considerably reduces the air intake when replenishing bulk materials in the machine silo 6. Any dust is considerably reduced as well.
The top portion of
The center of
The lower part of
While a particular embodiment of the present packaging machine and method for introducing bulk materials into containers has been described herein, it will be appreciated by those skilled in the art that changes and modifications may be made thereto without departing from the invention in its broader aspects and as set forth in the following claims.
On the whole, the invention offers many advantages since in normal operation the quantity of dust generated is considerably reduced, so as to considerably reduce the required dust removal capacities. The energy requirements are reduced as well. Moreover, the conditions during filling are more consistent and homogeneous, so that the fill results also improve. Thus, the packages can be filled in a reproducible and further enhanced quality.
Number | Date | Country | Kind |
---|---|---|---|
102017130958.6 | Dec 2017 | DE | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/EP2018/085299 | 12/17/2018 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2019/121561 | 6/27/2019 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
2260718 | Merrifield | Oct 1941 | A |
3189061 | Stockel | Jun 1965 | A |
3304964 | Rose | Feb 1967 | A |
3502119 | Sweeney | Mar 1970 | A |
4751948 | Hertig et al. | Jun 1988 | A |
5727607 | Ichikawa | Mar 1998 | A |
5753867 | Konishi | May 1998 | A |
7866353 | Combrink | Jan 2011 | B2 |
9540123 | Vollenkemper | Jan 2017 | B2 |
9650161 | Wehling | May 2017 | B2 |
9802724 | Vollenkemper | Oct 2017 | B2 |
10173794 | Breulmann | Jan 2019 | B2 |
10625890 | Vollenkemper | Apr 2020 | B2 |
20130048148 | Matye | Feb 2013 | A1 |
20140305542 | Vollenkemper | Oct 2014 | A1 |
20160122042 | Breulmann | May 2016 | A1 |
Number | Date | Country |
---|---|---|
102013009284 | Dec 2014 | DE |
102014100346 | Jul 2015 | DE |
0032481 | Jul 1981 | EP |
1513278 | Jun 1978 | GB |
Entry |
---|
German Search report from the corresponding German Patent Application No. 102017130958.6, dated Oct. 1, 2018. |
International Search report from the corresponding International Patent Application No. PCT/EP2018/085299, dated Mar. 14, 2019. |
Number | Date | Country | |
---|---|---|---|
20200324928 A1 | Oct 2020 | US |