The present invention relates to a method and system for emptying a container, e.g. a drum, containing a fluid product.
The present invention can mainly be applied in the sector of the food industry, but it can also be used in the chemical and pharmaceutical sectors.
In the food sector there are many processes for transforming raw materials into products for consumption. Fluid semi-processed products are moved various times into relevant containers (e.g. preparation containers, mixers, drums, cases) and systems are usually used for emptying such containers.
Typically, such systems comprise a pneumatic cylinder that forces a pumping unit into the container, appropriately arranged below it. Such pumping unit comprises at least one pipe terminating at one end with a scraping plate, which first engages the container, and connected at the other end to a pump. The scraping plate has a central hole communicating with the pipe and its descent forces the fluid into it. Due to the action of the pump, the fluid is sucked through the pipe and directed towards a device for distribution or towards another container. After finishing the emptying operation, the cylinder lifts the pumping unit, forcing the scraping plate out of the container.
For information purposes, the pumps used in such systems vary according to the product contained in the containers to be emptied. For example, they are of the alternative volumetric, eccentric screw, membrane, double screw type.
In this context, the existing solutions imply a series of disadvantages. Above all, the presence of an operator to manually control the movement of the pumping unit and who guarantees the correct performance of the operations is necessary. This extends the times for performing the set of operations and does not guarantee the optimal emptying of the containers.
Furthermore, solutions of the known type activate the pumping unit in the emptying step through the pneumatic cylinder. This generates overturning moments, especially in the latter part of the stroke of the pumping unit within the container, which are dangerous for the operator. Furthermore, frequent maintenance of the movement means is necessary. Again, during the upwards return of the pumping unit, it is a critical moment when the scraping plate disengages the container. In fact, the exit of the plate implies the undesired lifting of the container. To face this problem, some known solutions envisage the use of systems for locking the container, thus increasing the structural complexity and costs.
In this context, the technical task underpinning the present invention is to provide a method and a system for emptying a container, e.g. a drum, containing a fluid product, which obviate the drawbacks of the prior art cited above.
In particular, the object of the present invention is a method and a system for emptying a container, e.g. a drum, containing a fluid product, which reduce the performance times of the operations and ensure the optimal emptying of the container.
Another object of the present invention is to make available a method and a system for emptying a container, e.g. a drum, containing a fluid product, which increases the safety with respect to known solutions.
The defined technical task and the specified objects are substantially reached by a system for emptying a container, e.g. a drum, containing a fluid product, the system comprising:
a pumping unit comprising:
a pneumatic cylinder operatively active on the pumping unit for moving it inside a container;
a first and a second sensor;
a supply circuit for supplying air to the pumping unit, the air supply circuit being configured to supply air below the scraping plate;
a control unit configured at least to:
The pneumatic cylinder is operatively active on the pumping unit for exercising at least a first force and a second force of a greater size than the first.
The control unit is further configured to:
According to one embodiment, the first and the second sensor are arranged on the pneumatic cylinder.
In accordance with one embodiment, the first and the second sensor are magnetic.
According to one embodiment, the control unit is further configured to make the pumping unit stop at the second level for a predefined period of time.
According to one embodiment, the system further comprises a means for positioning the container below the pumping unit.
For example, the means for positioning the container comprises at least one adjustable guide element.
According to one embodiment, the system further comprises a plurality of wheels such as to be able to be moved on a resting plane.
The defined technical task and the specified objects are substantially reached by a method for emptying a container, e.g. a drum, containing a fluid product, comprising the steps of:
arranging the container in a predetermined position below a pumping unit. Such pumping unit comprises at least a pump and a scraping plate;
moving the pumping unit close to a mouth of the container;
detecting a passage of the pumping unit at a first level of the container;
upon detection of the passage of the pumping unit at the first level, activating the pump;
making the pumping unit descend towards a bottom of the container so that the pump sucks the product inside the container during the descent of the pumping unit;
detecting a passage of the pumping unit at a second level of the container, lower than the first level;
upon detection of the passage of the pumping unit at the second level, stopping the descent of the pumping unit;
deactivating the pump;
dispensing air coming from an air supply circuit to the pumping unit inside the container;
making the pumping unit return upwards towards the mouth of the container through the combined action of a pneumatic cylinder which is operatively active on the pumping unit and of dispensed air;
detecting a further passage of the pumping unit at the first level;
upon detection of the further passage of the pumping unit at the first level, interrupting the dispensing of air;
extracting the pumping unit from the container through the action of the pneumatic cylinder.
According to one embodiment, the method further comprises a step of making the pumping unit, once stationary, stop at the second level for a predefined period of time so as to complete the emptying of the container.
Further characteristics and advantages of the present invention will become more apparent from the approximate and thus non-limiting description of a preferred, but not exclusive, embodiment of a method and a system for emptying a container, e.g. a drum, containing a fluid product, as illustrated in the accompanying drawings, in which:
With reference to the figures, number 1 indicates a system for emptying a container, e.g. a drum, containing a fluid product.
The system 1 comprises a pumping unit 2. Such pumping unit 2 comprises:
Preferably, the motor 3 is of the pneumatic activation type. The pumping unit 2 is moved vertically inside the container 100 by means of a pneumatic cylinder 6. Preferably, the pneumatic cylinder 6 is operatively active on the pumping unit 2 for providing at least a first force and a second force of a greater magnitude than the first.
The system 1 further comprises a first and a second sensor suitable to detect the presence of the pumping unit 2.
There is also a supply circuit for supplying air to the pumping unit 2. Preferably, the air supply circuit communicates with the scraping plate 4 so that it dispenses air below it.
The system 1 further comprises a control unit 7 configured at least to:
The second level is lower than the first level.
Preferably, the control unit 7 is further configured to make the pumping unit 2 stop at the second level for a predefined period of time so as to complete the emptying of the container 100. This happens after stopping the descent of the pumping unit 2 and before deactivating the pump 5.
Preferably, the control unit 7 is further configured to:
In the embodiment described and illustrated herein, the sensors are arranged on the pneumatic cylinder 6. According to the height of the container 100, it is possible to determine a first position and a second position assumed by the cylinder 6 when the pumping unit 2 passes at the first level and the second level, respectively. By positioning the first and the second sensor in this way, it is possible to detect when the pumping unit 2 is at the first and the second level. In the eventuality of a format change for the container 100, the position of the sensors is easily and quickly adaptable.
Preferably, the sensors are of the magnetic type.
It is to be noted that the connection between the pneumatic cylinder 6 and the pumping unit 2 is of the rigid type, therefore the motion of the pumping unit 2 is of the rigid type. Therefore, knowing the position assumed by any point of the pumping unit 2 with respect to the pneumatic cylinder 6, the position of all the points of the pumping unit 2 is also known. Therefore, it can be envisaged without any significant modification to the system 1 to implement the sensors described above in a component of the pumping unit 2. In an alternative embodiment, the sensors are arranged on the scraping plate 4. For example, such sensors are proximity sensors, of the induction or ultrasonic type. Preferably, the system 1 further comprises a positioning means 8 for positioning the container below the pumping unit 2. In the embodiment described and illustrated herein, such positioning means 8 comprises at least one adjustable guide element 9. Preferably, there are at least three guide elements 9 suitable for contacting the container 100 in three distinct points.
In an alternative embodiment, the positioning means 8 comprises a conveyor belt with intermittent operation.
Preferably, the system 1 further comprises a plurality of wheels 10. Thus the system 1 can be moved on a resting plane.
The method for emptying a container, e.g. a drum, containing a fluid product, according to the present invention, is described below.
Above all, the container 100 is arranged below a pumping unit 2 in a predefined position. Preferably, the arrangement in a predefined position takes place by means of the adjustable guide element 9.
The pumping unit 2 is moved close to a mouth of the container 100. Then, the passage of the pumping unit 2 at the first level of the container 100 is preferably detected by means of the first sensor. For example, such first level may be the mouth or a level of the container 100 below the mouth. For example, such level may identify the level of the product contained inside.
Passage of the pumping unit 2 at the first level means that the passage of at least one of the elements comprising the pumping unit 2 is detected.
Preferably, the passage of the scraping plate 4 at the first level of the container 100 is detected.
Upon detection of the passage of the pumping unit 2 at the first level, the pump 5 is activated.
The pumping unit 2 descends towards a bottom of the container 100 so that the pump 5 sucks the product inside the container 100 during the descent of the pumping unit 2. Preferably, the descent of the pumping unit 2 is activated by the sole weight of the pumping unit 2 without the intervention of external forces thereto.
During the descent, the passage of the scraping plate 2 at the second level of the container 100 is detected. For example, the second level may be the bottom of the container 100 or a level of the container 100 above the bottom. In any case, as already mentioned, the second level is lower than the first level.
The detection preferably takes place through the second sensor.
Upon detection of the passage of the pumping unit 2 at the second level, the descent of the pumping unit 2 stops and the pump 5 is deactivated. Passage of the pumping unit 2 at the second level means that the passage of at least one of the elements comprising the pumping unit 2 is detected.
Preferably, the passage of the scraping plate 4 at the second level of the container 100 is detected.
The method further comprises a step of dispensing air inside the container 100 coming from the air supply circuit to the pumping unit 2.
Then, the pumping unit 2 is made to return upwards towards the mouth through the combined action of a pneumatic cylinder 6 which is operatively active on the pumping unit 2 for providing the first force and of dispensed air. According to one embodiment, the first force exerted by the pneumatic cylinder 6 in this step is substantially equal and opposite to the weight force of the pumping unit 2.
During the upwards return, a further passage of the pumping unit 2 at the first level is detected, preferably by means of the first sensor.
Upon detection of the further passage of the pumping unit 2 at the first level, the dispensing of air is interrupted.
Finally, the pumping unit 2 is extracted from the container 100 through the action of the pneumatic cylinder 6. Preferably, in this step, the pneumatic cylinder 6 exerts on the pumping unit 2 the second force of a greater magnitude with respect to the first force. Preferably, the pumping unit 2 is made to stop at the second level for a predefined period of time so as to complete the emptying of the container 100. This step takes place after stopping the descent of the pumping unit 2 and before deactivating the pump 5.
The characteristics and the advantages of the method and system for emptying a container, e.g. a drum, containing a fluid product, according to the present invention, prove to be clearly indicated in the description provided, as do the advantages.
In particular, the use of sensors for detecting the passage of the pumping unit in determined positions makes it possible to automate, at least in part, the drum emptying operations, reducing the times and increasing the reliability. In fact, it is no longer necessary to have to appoint an operator to establish the end of one operation and the beginning of the next.
Furthermore, the descent of the pumping unit only takes place due to the weight force of the pumping unit. The pneumatic cylinder does not push downwards, thus preventing the formation of overturning moments during emptying, which are dangerous to any operators who may be in the vicinity. Furthermore, in this way, bases are not necessary to contrast the thrust of the cylinder in the downwards direction, which would make the machine less hygienic and easy to clean, as well as making the step of positioning drums below the pumping unit more difficult.
Furthermore, the change in magnitude of the thrust of the cylinder to the pumping unit when the pumping unit is to be extracted from the container enables the lifting of the container itself to be prevented, as happens in some known solutions. Furthermore, it is no longer necessary to envisage the use of means for locking the container to solve the problem of the container being lifted, therefore the system is more streamlined.
Number | Date | Country | Kind |
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102019000025237 | Dec 2019 | IT | national |
Filing Document | Filing Date | Country | Kind |
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PCT/IB2020/061178 | 11/26/2020 | WO |
Publishing Document | Publishing Date | Country | Kind |
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WO2021/130574 | 7/1/2021 | WO | A |
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20220298001 | Paterlini | Sep 2022 | A1 |
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202013102871 | Jul 2013 | DE |
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102014114374 | Mar 2016 | DE |
102016125207 | Jun 2018 | DE |
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Entry |
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International Search Report for PCT/IB2020/061178, dated Feb. 24, 2021, 12 pages. |
Number | Date | Country | |
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20220298001 A1 | Sep 2022 | US |