ES2947468T3 - Machine for the production of cardboard - Google Patents

Abstract

The present invention relates to a machine for producing multi-layer cardboard or paper, or for printing or converting, from a reel of paper, cardboard or other material. In general, the invention can be applied to machines in which a reel of different materials is unwound and that require a contrast system to regulate the tension of the tape. In particular, the invention refers to a braking system for said coil. In particular, the invention relates to a braking system (2) for a support element (1) of a reel (B), for example, a paper reel in a machine for producing cardboard or corrugated cardboard, in which said braking system (2) comprises a motor-generator device (8) and a mechanical brake device (9) arranged coaxially. (Automatic translation with Google Translate, without legal value)

Description

DESCRIPTION

Machine for cardboard production

The present invention relates to a machine for producing multi-layer paper or cardboard, or to a printing machine or a machine in the processing sector, starting from a reel of paper or other material. In general, the invention can be applied to machines in which a reel of different materials is unwound and that require a contrast system to regulate the tension of the tape. In particular, the invention refers to a system for braking said coil. Document EP 2 206 667 discloses a braking system in paper unwinding devices.

As an example, machines for producing multi-layer cardboard, for example corrugated cardboard, usually comprise systems for unwinding paper from special reels, systems for corrugating the middle layer and systems for joining and gluing the different layers.

The paper rolls used for the different layers are usually large and therefore weigh a lot. To prevent uncontrolled unwinding of paper from such reels and to regulate their tension correctly, braking systems are consequently included, which can be both mechanical (for example, shoe brakes) and pneumatic or brake type. motor or electromagnetic powder brake.

The mechanical brake has the disadvantage of transforming kinetic energy, through friction, into thermal energy, which is lost when dissipated in the external environment.

However, the motor brake has the disadvantage of being very large, expensive and, in the launching and rewinding stages, consuming a lot of energy, characteristics necessary to implement a braking action suitable for a large reel of paper.

Therefore, the problem underlying the present invention is to provide a braking system that reduces energy consumption and energy dispersion to the environment, that has reduced dimensions and that can be integrated into machines for unwinding coils that are already installed.

Such a problem is solved by a braking system for coils as defined in the attached claims, whose definitions form an integral part of the present description.

Additional features and advantages of the present invention will become more evident from the description of the embodiments, provided herein below by way of non-limiting example, with reference to the following figures:

Figure 1 represents a schematic view from above of the support element of a coil provided with the braking system;

Figure 2 represents a vertical section of a detail of the support element in Figure 1 showing the braking system;

Figure 3 represents a schematic view from above of the support element of a coil provided with the braking system according to the invention.

Figure 1 shows a support element 1 of a paper reel B on which the braking system 2 is installed.

The support element 1, in the example shown in the figures, forms part of a machine (not shown) for producing cardboard, in particular, for producing corrugated cardboard, which will comprise, downstream of the support element 1, a system for joining several layers of paper and a traction system to unroll the paper from reel B. Reel B, which has been pulled by said traction system during the production stage to make it rotate, therefore supplies a motor torque, which It must be regulated by means of contrast with the braking system 2 in order to guarantee the necessary paper tension for correct unwinding of the same.

The support element 1, usually referred to as "roller support", comprises a C-shaped structure 3 having two arms 4 and a connecting bar 5. The distal ends 4a of the arms 4 support respective shafts 6, which support rotatably the coil B at the two proximal ends 6a thereof. However, the braking system 2 is mounted on the distal ends 6b of the axles 6, by means of a lap joint, for example.

As shown in Figure 2, the braking system 2 is coupled to the support element 1, for example, by means of a flange coupling 7.

The braking system 2 comprises a motor-generating device 8 and a mechanical brake device 9, arranged coaxially. Preferably, the mechanical brake device 9 is mounted and therefore acts on the same axis 10 as the motor-generating device 8.

The distal end 6b of the shaft 6 protrudes from the distal end 4a of the respective arm 4 and is fixed coaxially within the shaft 10 of the motor-generating device 8.

The motor-generator device 8 is an electric motor which, by means of the interface with an inverter, can supply, depending on the case (which will be further described below), a motor torque or a resistive torque of the load, which produces electricity in this last case.

The motor-generating device 8 has a smaller size with respect to the braking needs of the unwinding of coil B, especially when the latter is at the beginning of unwinding and, therefore, has a high inertial mass. This makes it possible to limit the size and cost of the motor-generating device 8 with respect to known braking systems, which use only a motor braking system.

Preferably, the mechanical brake device 9 is a single disc or polydisc brake (a double disc is shown in the figure), preferably of the pneumatic type.

For safety reasons, the mechanical brake device 9 has a size suitable for complete braking of the unwinding of coil B, in order to intervene also in the event of emergency braking. However, under normal operating conditions, it is activated by dividing the braking torque between it and the motor-generating device 8. In this way, a partial recovery of energy in the form of electricity is obtained, unlike known braking systems, which They only use a mechanical brake and in which all the energy derived from friction is released to the environment in the form of thermal energy.

As shown in Figure 1, the braking system 2 comprises a command and control unit 11 and a user interface 12 for presenting operating parameters.

Normally, a cardboard production machine comprises two supporting elements 1, which act alternately and which are designed to prevent a machine from stopping when a coil B has almost run out and needs to be replaced by a new coil B. However, the Arrangement of two support elements 1 with relative coils B allows rapid joining of the paper tape being processed with a new coil B when coil B has almost finished on the other support element 1.

Therefore, the cardboard production method includes the following stages:

- machine start;

- production stage with controlled speed and tension;

- replacement of an almost empty coil B with a new coil B.

As stated above, the motor-generating device 8 can act as a motor, that is, supplying a driving torque, and as a generator, that is, supplying a braking torque. In particular, the motor-generator device 8 acts as a motor in the starting stage (called coil launching stage), together with the traction system in order to overcome the resistance due to the inertial mass of the coil B, and in the coil replacement stage, in order to rewind the remaining paper tape after cutting and joining the new coil B. Vice versa, the motor-generating device 8 acts as a generator during the normal production stage of the machine.

Therefore, the command and control unit 11 is configured to order the start-up of four braking systems 2, that is, two braking systems 2 for each of the two support elements 1, and to send the electricity produced by the motor-generating device 8 to the energy supply network E during the operating stage. Preferably, the command and control unit 11 comprises four circuit boards 11 a for commanding the braking action and one circuit board 11 b for managing the delivery of the electricity produced to the power supply network E.

In other embodiments, each coil will only comprise one braking system 2, so that the command and control unit 11 only comprises two circuit boards 11 a for controlling the braking action.

In particular, according to a first embodiment, the command and control unit 11 is configured to perform the following operations:

i) receive the machine parameter values of line speed, paper tension, diameter of coil B and number of turns of coil B;

ii) compare said machine parameter values with pre-established values;

Ni) calculate the braking torque CL of the braking system 2 to be supplied;

iv) calculate the division of the braking torque CL between the braking torque CM of the motor-generating device 8 and the braking torque CF of the mechanical brake device 9;

v) order the motor-generating device 8 and the mechanical brake device 9 according to the calculation in step iv) to supply the calculated braking torques CM and CF;

vi) manage, through the interface of an inverter, the electricity produced by the motor-generating device 8 and send said electricity to the energy supply network E.

Step i) is carried out by means of suitable machine sensors, for example, a photoelectric sensor to monitor the diameter of the coil B. The motor-generator device 8 is further provided with a "resolution element" or "' encoder" to read the number of turns of the shaft 10. The pulling force of the line is detected by means of a bridge or by means of load cells.

Stage iv) is carried out as follows:

a) when CL > CM-MAX, where CM-MAX is the maximum braking torque that the motor-generating device 8 can supply, CL is given by the sum of CM-MAX CF;

b) when CL < CM-MAX, CL is given by the sum of CM CF, where CF = mCL and CM = nCL, where m = 1 -n and n is from 0.9 to 0.99 and is preferably around 0.95;

c) in case of emergency braking, CL = CM-MAX CF-MAX, where CF-MAX is the maximum braking torque that can be supplied by the mechanical brake device 9.

Such an operating sequence allows the energy recovery to be sent to the energy supply network E for optimization, which keeps the braking torque supplied by the motor-generating device 8 as high as possible. In fact, when the required braking torque CL is greater than CM-MAX, the difference will be given by the mechanical brake device 9. Vice versa, when CL is less than CM-MAX, a situation that normally occurs when coil B is almost empty - so its inertial mass decreases significantly - or when the coil B itself is wound with light paper, it is necessary to keep the mechanical brake device 9 activated to achieve fast reaction times in case of braking. emergency and to ensure management of the braking torque supply through feedback action. Therefore, the mechanical brake device 9 will contribute a percentage of from 1% to 10% to the required braking torque CL.

When the mechanical brake device 9 is a pneumatic disc brake, step v) of commanding the mechanical brake device 9 is carried out by adjusting the air pressure of the pneumatic disc brake by means of an electrical signal transducer to pneumatic pressure.

Figure 3 shows an embodiment of the braking system of the invention, which is particularly adapted to be integrated into cardboard production machines, which are already equipped with a pneumatic type braking system.

As in the previous embodiment, the tensile force of the line is detected in real time by means of a detection device 13, such as a bridge or a load cell.

The device 13 sends an electrical signal to an electro-pneumatic converter (EP converter) 14, which commands the air pressure, which is sent, along the lines 15, 15', to the mechanical (pneumatic) brake devices 9, to generate the braking torque necessary to guarantee the preset voltage value. It should be noted that the configuration described so far is characteristic of a roller support with a conventional pneumatic brake.

The system of the invention comprises the arrangement of a branch 15" of the pneumatic line 15, 15' operatively connected to a pressure transducer 16, which reads the air pressure along the line 15, 15' and the converted into an electrical signal, which is sent to the command and control unit 11, which, by means of the algorithm described above in stage iv), calculates the braking torque and sends a command signal to the motor-generating device 8.

Clearly, in this way, the total braking torque will be greater than what is actually required, so the sensing device 13 will detect a voltage greater than the required voltage and, as a consequence, the electropneumatic converter 14 will regulate the air pressure. A rapid repetitive adjustment cycle is established, allowing balance to be achieved in fractions of a second, providing the division of the necessary braking torque CL, as described above, between CM and CF.

Consequently, according to such an embodiment, the braking system 2 comprises:

- a detection device 13 configured to detect, in real time, the tension applied to the paper unwound from a reel B;

- an electropneumatic converter 14 operatively connected to said detection device 13, the electropneumatic converter 14 being configured to regulate the pressure of the air that is sent to said mechanical brake device 9 according to a preset braking torque value CL that is going to be supplied;

- at least one pneumatic line 15, 15' connected to said electropneumatic converter 14 and to said mechanical brake device 9;

- a pressure transducer 16 connected, by means of a shunt 15", to said at least one pneumatic line 15, 15' and to a command and control unit 11, in which said command and control unit 11 calculates a division of the preset braking torque CL to be supplied between a braking torque CF of the mechanical brake device 9 and a braking torque CM of the motor-generating device 8 according to the pressure detected by the pressure transducer 16 and commands the braking torque CM of the device motor generator 8 according to said calculation.

The command and control unit 11 is configured to perform the following operations:

i) receiving, by means of a pressure transducer 16, the air pressure values supplied along the line 15, 15' from said electropneumatic converter 14;

ii) calculate the division of the braking torque CL between the braking torque CM of the motor-generating device 8 and the braking torque CF of the mechanical brake device 9 according to said pressure values received and the pre-established braking torque CL to be supplied;

iii) command the motor-generating device 8 according to the calculation in step ii) to supply the calculated braking torques CM and CF;

iv) repeat steps i) to iii) until reaching a braking torque CL equal to the pre-established braking torque CL;

v) manage, through the interface with an inverter, the electricity produced by the motor-generating device 8 and send said electricity to the energy supply network E.

Therefore, the braking system 2 of the invention achieves the predetermined objectives.

In fact, such a braking system can also be integrated into machines already in use, which have a pneumatic brake, simply replacing the latter with the braking system 2, or, in case of replacing a motor brake or a magnetic brake, providing a compressed air supply. In the case of the second embodiment described above, in addition to replacing the pneumatic brake with the coaxial motor-generating device 8 and the mechanical brake device 9, it will be enough to connect the pneumatic lines 15, 15' to the pressure transducer 16 by means of the bypass 15"' and the pressure transducer 16 to the command and control unit 11, which commands the motor-generating device 8.

The braking system of the invention has reduced dimensions and low cost, also due to the fact that the current use of a mechanical brake does not require a motor generator with great power.

The braking system 2 also allows a recovery of electricity, although only partial (that is, related only to the part of the braking torque supplied by the motor-generating device 9).

Clearly only one particular embodiment of the present invention has been described, so that a person skilled in the art can make all the necessary changes to adapt it to particular applications, without thereby departing from the scope of protection of the present invention. as defined in the attached claims.

Claims (6)

1. Braking system (2) for a support element (1) of a reel (B), for example, a paper reel in a machine for producing cardboard or corrugated cardboard, in which said braking system (2) It comprises a motor-generating device (8) and a mechanical brake device (9) arranged coaxially, characterized in that said mechanical brake device (9) is a pneumatic brake, which comprises: - a detection device (13) configured to detect, in real time, the tension applied to the paper unwound from a reel (B); - an electropneumatic converter (14) operatively connected to said detection device (13), the electropneumatic converter (14) being configured to regulate the air pressure that is sent to said mechanical brake device (9) according to a value of preset braking torque (CL) to be supplied; - at least one pneumatic line (15, 15') connected to said electro-pneumatic converter (14) and to said mechanical brake device (9); - a pressure transducer (16) connected, by means of a bypass (15"), to said at least one pneumatic line (15, 15') and to a command and control unit (11), in which said control unit command and control (11) calculates a division of the pre-established braking torque (CL) to be supplied between a braking torque (CF) of the mechanical brake device (9) and a braking torque (CM) of the motor-generating device (8). ) according to the pressure detected by the pressure transducer (16) and commands the braking torque (CM) of the motor-generating device (8) according to said calculation. 2. Braking system (2) according to claim 1, wherein the mechanical brake device (9) is mounted on the same axis (10) as the motor-generating device (8). 3. Braking system (2) according to claim 1 or 2, wherein the motor-generating device (8) is an electric motor that is configured, through the interface, with an inverter to supply a motor torque or a resistive torque of the load, which produces, in the latter case, electricity. 4. Braking system (2) according to any one of claims 1 to 3, wherein the mechanical brake device (9) is a single disc or polydisc brake, preferably of the pneumatic type. 5. Braking system (2) according to any one of claims 1 to 4, wherein said command and control unit (11) is configured to perform the following operations: i) receiving, by means of a pressure transducer (16), the pressure values of the air supplied along said at least one pneumatic line (15, 15') from said electro-pneumatic converter (14); ii) calculate the division of the braking torque (CL) between the braking torque (CM) of the motor-generating device (8) and the braking torque (CF) of the mechanical brake device (9) according to said pressure values received and the pre-established braking torque (CL) to be supplied, in which said calculation is carried out using an algorithm, which comprises the following steps: a) when CL > CM-MAX, where CM-MAX is the maximum braking torque that the motor-generating device (8) can supply, CL is given by the sum of CM-MAX CF; b) when CL < CM-MAX, CL is given by the sum of CM CF, where CF = mCL and CM = nCL, where m = 1 - n and n is from 0.9 to 0.99 and is preferably around 0.95; c) in case of emergency braking, CL = CM-MAX CF-MAX, where CF-MAX is the maximum braking torque that the mechanical brake device (9) can supply; iii) order the motor-generating device (8) according to the calculation in step ii) to supply the calculated braking torques (CM) and (Cf); iv) repeat steps i) to iii) until reaching a braking torque (CL) equal to the pre-established braking torque CL; v) manage, through the interface with an inverter, the electricity produced by the motor-generating device (8) and send said electricity to the energy supply network (E). 6. Machine for producing cardboard or corrugated cardboard, for either printing or processing, comprising at least one, preferably two support elements (1) of a reel (B) of paper or other material, in which each of said support elements (1) comprises a C-shaped structure (3) having two arms (4) and a connecting bar (5), in which the distal ends (4a) of the arms (4) support respective axes (6), which rotatably support the coil (B) at the two proximal ends (6a) thereof, the braking system (2) according to any one of claims 1 to 5 being mounted on the distal ends (6b) of the axles (6). Machine according to claim 6, wherein the distal end (6b) of the shaft (6) protrudes from the distal end (4a) of the respective arm (4) and is fixed coaxially within the shaft (10) of the motor-generating device (8). ). Machine according to claim 6 or 7, comprising two support elements (1), in which the command and control unit (11) is configured to order the start-up of four braking systems (2), i.e. two braking systems (2) for each of the two support elements (1), and to send the electricity produced by the motor-generating device (8) to the energy supply network (E) during the operating stage. Method for producing cardboard or corrugated cardboard, for either printing or processing, comprising the steps of: - providing a machine according to any one of claims 6 to 8; - start the machine; - produce paper or other material at a controlled unwinding speed and tension; - replace an almost empty coil (B) with a new coil (B), in which the motor-generating device (8) acts as a motor at startup and when the coil (B) is replaced and as a generator during production.