DE4439889C1 - Continuous belt tension control, giving constant draw tension value at edges - Google Patents

Abstract

To control the tension in a continuous moving belt, such as the fourdrinier or blanket in a papermaking machine, the tension is registered independently at each edge of the belt (2). These tensions are corrected independently of each other to match nominal values. Also claimed is an appts. with sensors to register the forces at both bearings (5) of one of the belt rollers (3,4), linked to independent belt draw tension control systems which act on setting drives for the tensioning roller (4). Pref. the independent belt tension controls apply a setting in the same direction at the ends of the tensioning roller (4) to a mean value and a difference gives opposing settings at the roller (4) ends. The angular lie of the guide roller (3) is registered for comparison with an action zone between two threshold values. If the setting breaches the upper level, the independent belt tension action is interrupted, and a new action zone is set if it is below the lower level, with a narrower span. On breaching the upper level, the belt tension control is coupled and the ends of the tensioning roller (4) are set at the same time in the same direction while the angular setting of the guide roller (3) is held at a constant pitch. When the upper level is breached, an optical or acoustic alarm is triggered.

Description

The invention relates to a method in the preamble of claim 1 given type and an associated device.

In a generic device known from DE-PS 40 11 796 a revolving Endless belt held by several rollers. This is endless in papermaking usually tied a circulating felt or a sieve. One of these rollers is ver pivotable guide roller formed with a scanning device in Wirkver bond stands. By swiveling the guide roller an offset of the endless becomes bandes balanced. Is the tension of the endless belt ver on both edges and if there is a stretch on one side of the endless belt, they run Edge areas of the endless belt with different speeds. This leads to a parallelogram-like distortion of the structure of the band. This ver Distortion is undesirable because the openings in the fabric or in the sieve become smaller and the bandwidth is reduced. Water can therefore usually make the tape worse penetrate so that the press capacity of the paper machine is reduced. In the pre called publication is therefore proposed a tension roller on both bearings to keep sliding. The guide roller is pivoted in an oscillatory manner, the movements of the bearing points being synchronous and counter-rotating  fen. This oscillatory movement causes constant tension and relaxation the edge of the circulating endless belt around an average. The circulating Endless belt is therefore strained in its structure, reducing production output a paper machine is affected in a known manner.

A similar device is also known from DE-OS 25 40 923. It is featured propose to improve a scheme to obtain a better voltage ver division over the entire width with a voltage regulation and a regulation for Edge set course with a guide roller and a tension roller at the same time as a guide roller by using their bearings adjustable by independent actuators are. A single edge sensor and a single force transducer, which on one another roller is provided, provide correction signals for a control device. This control device controls the actuators of the tensioning roller in such a way that a required tension correction the two actuators syn be moved chronically, and if the end has to be corrected laterally losbandes these are adjusted synchronously in opposite directions. Because of having a run Correction required inclination of the tensioning roller can large clamping force diff are introduced between two edge areas of the endless belt. These cause a parallelogram-like distortion of the endless belt. Except Often, the force transducer is located in the bearing one far from the tensioning roller removed deflecting roller. This can cause a time lag between the Changing the actuators of the tensioning roller and the reaction of the force transducer to lead. This delay sometimes leads to a tendency of the control to oscillate, so that it has to be adjusted very slowly.

The invention has for its object a method of the type mentioned and to create an associated device that has a circulating endless belt allows a constant tape tension on both edge areas, the endless band is still well positioned.

The object is achieved according to the invention in those specified in claim 1 NEN procedural steps solved.  

In the method emphasized as advantageous in claim 1, the voltage of the endless belt, which is referred to as belt tension in the following, is detected on both edge regions. This allows a determination of the band tension difference between the two edges of the Endless belt. These band tension are controlled independently of each other, so that the Belt tension along the entire width of the endless belt at predetermined values is held. In addition, the setpoints for the control of the strip tension are on the two edge areas are the same, so the tape tension is along the entire width of the Endless belt equal to the setpoint. This gives the surprising effect that the Contact force of the endless belt over the whole of the subsequent rolls Width is constant. A subsequent drying cylinder therefore achieves over the Width of the endless belt an even drying performance. In addition is a parallelogram-like warping of the endless belt reduced. The one in the endless belt for breakthroughs intended for evaporation are therefore always of their maximum size, so that water can easily penetrate the endless belt. A paper machine, its felt or sieve with the process in place and Tension is regulated, therefore allows a significant increase in the belt running speed and thus an increased production output. Passing the Endless bandes is made in a manner known per se by regulating the edge posi tion causes, but using a separate guide roller. Since at An Using this method, the tension roller is only inclined by very small angles must be, the guide roller is easily able, even by the Tensioning roller quickly corrected the lateral course of the endless belt ren. The individual control loops therefore remain decoupled, so that they are particularly simple and can be tuned independently.

The use of the method steps according to claim 2 is particularly favorable. By separating the regulations into a regulation of the mean on the one hand and the adjustment devices can regulate the band tension difference can be optimized particularly advantageously. In general, the tension roller must over relatively large distances can be adjusted. In contrast, the required win  small changes. To compensate for a difference in clamping force can therefore be particularly sensitive adjusting device can be used. In addition, the system very safe, because the maximum angle of the tensioning roller is very simple due to a limitation tion of the travel of the actuator influenced by the tape tension difference control can be done. Such a measure prevents the inclination of the Tension roller without limiting the travel of the tension roller.

The application of the method step according to claim 3 has been particularly intended Proven in part, because even under the most unfavorable conditions, secure tape guidance is guaranteed. Is the endless belt, for example, by a short-term one-sided If the ge fault is heavily loaded, this band tension has to be increased Tilting of the tensioning roller required. This increased oblique position of the instep However, roller leads to a very strong running of the endless belt. The leadership Under certain circumstances, roller can no longer be pivoted so far that the position of the endless belt is adjusted back to its setpoint. In this out situation, it is therefore advantageous to use independent tension control on both sides abandon until the guiding of the endless belt is guaranteed. To one of the to recognize like extreme situation, the angular position of the guide roller is detected. It is a measure of how big the trend of the endless belt is from its target position to get lost. This angular position is preferably symmetrical about the Normal action area arranged to the tape running direction compared.

In order to suppress the tendency to oscillate, the application of Ver driving step according to claim 4 cheap. The resulting schmitt trigger-like switching between the independent and the coupled band tension control prevents permanent switching when the guide roller exactly that Angular position that defines the boundary of the action area.

In order to continue the belt tension of the belt tension after interrupting the tension control on both sides Endless belt at least approximately in the area of both edge areas Keeping the setpoint is the application of the method step according to claim 5  advantageous. A coupled regulation of the tape tension with synchronous in the same direction Adjustment of the tensioning roller ensures that the middle belt tension or is kept constant the tape tension at an edge area. The endless belt is therefore always tense, which reliably prevents its destruction.

It is also favorable to use the method step according to claim 6, since ins especially the transition between independent and coupled belt tension control can be carried out without interference. In addition, the middle is used in both types of regulation Belt tension of the endless belt regulated to the same setpoint, which is the lifespan of the endless belt increased.

In order to inform the staff of an extreme position of the guide roller, the Use of the method step according to claim 7 cheap. This is particularly so important to take appropriate care of common problems with the tape guide To be able to initiate countermeasures.

A particularly effective tape guide results from the use of the method rens Step according to claim 8. The angular position of the tension roller is detected and from this the expected course of the endless belt due to this adjustment averages. The guide roller is then pivoted accordingly, so that the La Regulation not or to a much reduced extent to correct the position of the endless ban that must intervene. The guide roller is therefore changed in its angular position adapted conditions before the belt has run out of its target position. This he gives a particularly fast and therefore effective position control.

The device according to claim 9 has been used to carry out the method particularly favorable. In this training, the control device is available a separate guide roller in operative connection. The belt tension control and the Belt guidance is therefore carried out by different rollers. Preferential wise, the tension roller is from the endless belt at a much larger angle wrapped around as the guide roller. The actuators of the tensioning roller adjust this  in the direction of the angular symmetry between the incoming and the outgoing endless tape. A slight change in the angle of the tensioning roller therefore causes the greatest possible che band tension change. In contrast, the guide roller becomes approximate adjusted perpendicular to the angular symmetry of the incoming and outgoing endless belt. This adjustment therefore causes an almost negligible change in tape tension. From this division of the two control tasks on two different rollers there is therefore an excellent decoupling of the two regulations from one another of the. This reduces the tendency of the control devices to oscillate and therefore improves their stability. Force sensors on both bearings of the tensioning roller allow an effekti ves Detection of the belt tension on both edge areas of the endless belt. The band train is therefore preferably measured on the same roller on which the clamping force is regulated. This results in a minimal delay time of the controlled system, so that the regulation takes place faster overall. The use of independent tape access gel devices for both force sensors gives the surprising effect that the Belt tension along the entire width of the endless belt is close to the target value. This particularly gentle treatment increases the lifespan of the endless ban the significantly increased. Due to the particularly stable running of the endless belt also its running speed can be increased. This also increases the producti performance of the device.

The application of the features of claim 10 is particularly for implementation of the method according to claim 2 favorable. A coupling of the two in the same direction Bearing of the tension roller by means of a gear allows a synchronous in a simple manner Adjustment of both bearings in the same direction by means of an actuator. Preferably this actuator is controlled by a control device which determines the mean value of the strip tension measured at both edge areas is obtained as the actual value. This Stellan drive causes the tensioning roller to move without changing its angular position. By superimposing the motion of the actuator with the motion of a another actuator, an angular adjustment of the tensioning roller is achieved. Since the required angular adjustment of the tensioning roller is low, it is from below orderly meaning whether the second actuator is moving in the opposite direction  caused the bearing of the tension roller, or whether this actuator only on one the camp works. Both actuators are preferably designed with travel limitation equips both the maximum adjustment of the tensioning roller and its maximum Limit angular position.

The application of a planetary gear according to claim 11 results in a special simple yet robust superimposition of the movements of the two actuators. The planetary gear is space-saving and can also reduce the Actuate actuator. This increases the positioning force and allows a particularly sensitive Adjustment of the tension roller.

The application of the features of claim 12 is particularly advantageous because with very simple technical means a very safe strip guiding is guaranteed. A displacement sensor allows a precise detection of the angular position of the guide roller. The use of a window comparator makes the angular position more advantageous Wisely compared to both limits of the action area at the same time. The end gang of the window comparator therefore provides the information as to whether the guide roller is inside or outside of its scope. A switch whose Control input is operatively connected to the window comparator, allowed in one the most professional way of interrupting the control loop of a belt tension control device tung. The corresponding actuator is in the activated position of the switch no longer with the output of the independent second strip tension control device, but connected to another source, which is the belt tension control device of the opposite edge area is in operative connection. Of course it is also possible to connect several changeover switches in series, or an analog module use tiplexer so that the actuator is connected to different sources can be. A plurality of window comparators are then preferably also inserted that sets the angular position of the guide roller with different action areas Compare and depending on the position of the guide roller with the actuator of the tension roller connect different sources. This allows a sensitive and to the respective Use the optimally adapted control type for the situation.  

The application of the feature according to claim 13 stabilizes the control behavior of the Device in a particularly advantageous manner. The guide roller is in egg location, which corresponds exactly to a limit value of the action area, could a repeated switchover in the control loop of the strip tension control device the switch. A Schmitt trigger input of the window body tors prevents this because the individual switching operations on different Threshold voltages, i.e. different limit values, occur. This stabilizes the control behavior of the device.

Alternatively, it is advantageous to the device with the features of claim 14 realize. The summer can the output signal of the tape tension control device any other signal superimposed on the opposite edge area. This allows a synchronous adjustment of the two actuators in the same direction Tensioning roller, the tensioning roller being any one dependent on the additional signal Can assume inclination. The belt pulls of the endless belt on both edges areas remain close to their target values.

The application of the features of claim 15 allows in a particularly advantageous manner Way the calculation and storage of the difference of the input signals of the actu links of the tension roller. This difference is saved at the time of Switching between independent and coupled belt tension control. This is done in a surprisingly simple way by the edge-triggered control input of the sample hold amplifier. Because the output of the sample hold amplifier is connected to one of the inputs of the adder, the tension roller remains at Switching between the two control types exactly in their current position. The transition between the two types of regulation is therefore trouble-free. At at closing tension changes of the endless belt remains the angle between the Tension roller and the direction of the endless belt constant.  

If the tape tension control devices work according to the method of claim 2, so the application of the features of claim 16 is favorable. The sample hold Amplifier saves at the time of switching between the independent and the coupled belt tension control the output voltage value of that belt tension control device that receives the belt tension difference as the actual value. After switching this stored value is output to the corresponding actuating device. So As long as the coupled belt tension control is active, the angular position of the remains Tension roller constant.

The application is in particular for carrying out the method according to claim 6 of the features according to claim 17 favorable. This allows automatic switching the actual value input of the belt tension control device from a force sensor to the Average of both force sensors when changing the control mode. It is also advantageous to use the output of the window comparator to connect a sound generator or a signal lamp. This allows each time If an extreme position of the guide roller occurs, notification of the operator Personnel so that appropriate countermeasures can be initiated. To In addition, the tape could also be switched off in this case to destroy it prevention.

Finally, it is advantageous according to claim 18 to provide a computer that the Device at least partially implemented in software. This allows a knockout Most inexpensive development of the device, since the computer is very easy to change can be grammed. The control devices can therefore be easily adapt to the requirements. Since the building blocks of a computer as a chip with sup Most integration densities are produced, only a few components are real fixation of the device required. This has an advantageous effect on a small one Power consumption with high reliability of the circuit.

Preferred embodiments of the Device and the inventive method described.

It shows

Fig. 1 is a perspective view of the device and

Fig. 2 is a schematic representation of the device as a block diagram.

Fig. 3 is a schematic representation of an alternative device.

As can be seen from FIG. 1, a device 1 , which is part of a paper machine and is used for the tension control and for guiding a continuous endless belt 2 , essentially consists of a guide roller 3 and a tension roller 4 . The Füh approximately roller 3 and the tension roller 4 are rotatably held in bearings 5 . In particular for use in wet presses, the endless belt 2 is designed as a circumferential felt or metal sieve. The guide roller 3 can be pivoted on one side by means of an adjusting device 6 . The adjusting device 6 consists of a linear guide 7 , in which a slide 8 is held pivotably. The carriage 8 is adjusted along the linear guide 7 by means of a drive 9 , so that the angular position of the guide roller 3 is adjustable. The drive 9 is preferably an electric motor to which a step down of the gear (G₀, G₁, G₂) is assigned. Alternatively, the drive 9 could also be a hydraulic or pneumatic cylinder with an internal piston. The adjusting device 6 has a displacement sensor 10 for detecting the setting angle of the guide roller 3 . For example, it can be implemented as a potentiometer actuated by the drive 9 . The guide roller 3 is assigned an edge scanning device 11 for detecting the edge position of the endless belt 2 . This edge scanning device 11 can scan the endless belt 2 either optically, pneumatically or mechanically. It supplies a signal which is proportional to the edge position of the endless belt 2 and which is used as a correction signal of a control device (not shown).

The tension roller 4 has on its two bearings 5 a force sensor, not shown, for determining the strip tension, that is, the tension of the endless belt 2 . An adjustment device 12 , 13 , which are independent of one another, acts on both bearings 5 . The adjusting devices 12 , 13 are essentially similar to the adjusting device 6 , so that a detailed description is unnecessary. The adjusting devices 12 , 13 allow displacement and any pivoting of the tensioning roller 4 . Alternatively, the two adjustment devices 12 , 13 could be connected to one another via a coupling K. In this case, an adjustment of the adjustment device 12 causes a synchronous movement in the same direction of both bearings 5 of the tension roller 4 . The gear G₂ of the adjusting device 13 effects a superposition of the movement of the displacer 12 with the movement of the on drive 9 'of the adjustment. 13 In this way, the tension roller 4 is pivotable ver. In order to achieve the greatest possible tensioning effect of the endless belt 2 by the tensioning roller 4 , the tensioning roller 4 is wrapped by the endless belt 2 at a large angle of approximately 180 °. The direction of displacement of the bearing 5 of the tensioning roller 4 extends approximately in the direction of the angular symmetry 14 , between the tapering and the tapering section 2 a, 2 b of the endless belt 2 . It is assumed that the endless belt 2 moves in the direction 15 . In comparison, the adjusting device 6 pivots the guide roller 3 perpendicular to the angular symmetry 16 between the tapering and the tapering section 2 c, 2 d of the endless belt 2 . A pivoting of the guide roller 3 therefore only causes a negligible change in the belt tension of the endless belt 2 .

In order to implement the tape tension and edge position control, in addition to the mechanical components described, an electronic circuit 17 is provided which is in operative connection with the adjusting devices 6 , 12 , 13 and with the edge scanning device 11 and the force sensors. This circuit 17 can also be a computer that performs the regulation and control tasks in software.

In FIG. 2, the apparatus 1 is schematically illustrated together with the circuit 17 as a block diagram. The same reference numerals mean the same parts. A control device 20 for controlling the edge position of the endless belt 2 receives signals from the edge scanning device 11 as an actual value via a signal path 21 . In egg nem summer 22 , the signals of the edge scanner 11 are subtracted from those of a setpoint generator 23 . The setpoint generator 23 could, for example, be a potentiometer provided between a reference voltage and ground. The result of the difference formation is given to a controller 25 via a signal path 24 . The controller 25 has at least one amplifier and preferably has a PID behavior. The controller 25 calculates a correction signal which quickly compensates for any difference between the actual value and the target value at the summer 22 .

The controller 25 is connected via a signal path 26 to another summer 27 . Further inputs of the summer 27 are operatively connected via signal paths 28 , 29 to displacement sensors 30 , 31 actuated by the tension roller 4 . In this way, the summator 27 ensures that the output signal of the controller 25 is superimposed on a signal proportional to the inclination of the tensioning roller 4 . An amplifier 32 , 33 , the amplification factors of which can be set, is preferably each seen between the displacement sensors 30 , 31 and the summer 27 . By varying the amplification factors of the amplifiers 32 , 33 , the superimposition of the signal from the controller 25 with the signals from the displacement sensors 30 , 31 is set such that the expected course of the endless belt 2 is essentially compensated for when the tensioning roller 4 is inclined, without the control device 20 operating. In practice, this ideal case cannot be realized, but it can be achieved in this way that the path course to be corrected by the control device 20 is considerably reduced by this superimposition.

The summer 27 transmits the result of the superimposition via a signal path 34 to a power amplifier 35 , which amplifies this signal to such an extent that an actuator 36 of the adjusting device 6 can thus be controlled. The actuator 36 is mechanically connected via the path 37 to the bearing 5 of the guide roller 3 . To record the setting angle of the guide roller 3 , the travel sensor 10 is provided in the path 37 . The opposite bearing 5 of the guide roller 3 is pivotally held, no separate actuator being provided.

Belt tension regulating devices 41 , 42 are provided to regulate the belt tension of the endless belt 2 . The belt tension control device 41 has a summer 43 which carries out an actual setpoint comparison. The actual value is generated by a force sensor 44 , which measures the bearing force of the tension roller 4 . The force sensor 44 is operatively connected via a signal path 45 to an inverting input of the summer 43 , the actual value input. The setpoint of the tension control device 41 and 42 is generated by a known setpoint generator 46 and is given via a signal path 47 to a non-inverting input of the summer 43 .

In order to produce a periodic swiveling of the tensioning roller 4 , a triangular oscillator 48 can optionally be provided, the output signal of which is fed via the signal path 49 to an input of the summer 43 . The superposition of the output signals of the setpoint generator 46 and the oscillator 48 produces a triangle around the set by the reference value generator 46 periodically oscillating signal value which serves as a target value of the Bandzugregeleinrichtung 41st

Via an additional inverting input of the summer 43 , the displacement sensor 30 of the adjusting device 12 is connected in a negative feedback manner via a signal path 49 . This connection ensures a reduction in the phase shift of the controlled system. This lowers the tendency of the strip tension control device 41 to oscillate. A controller 51 with a preferably PID behavior, which is operatively connected to the summer 43 via a signal path 50, can therefore have a significantly increased proportional component in its transmission behavior. This considerably increases the speed at which disturbances can be corrected.

The output signal of the controller 51 is connected via a signal path 52 to a power amplifier 53 . This power amplifier 53 amplifies the output signal of the controller 51 to such an extent that an actuator 54 for adjusting the bearing 5 of the tension roller 4 can be controlled. For accurate detection of the tension force of the endless belt 2 , the force sensor 44 is provided in the path 55 between the actuator 54 and the bearing 5 of the tension roller 4 . The force sensor 44 is preferably integrated directly in the bearing 5 of the tensioning roller 4 . To record the adjustment path of the tensioning roller 4 , the path encoder 30 is provided in the path 55 .

The belt tension control device 42 for the opposite edge of the endless belt 2 is constructed similarly to the web tension control device 41 . A summer 60 provides an actual setpoint comparison. For this purpose, the summator 60 is connected to the setpoint generator 46 or the triangular oscillator 48 via the signal paths 47 , 49 . In contrast to the strip tension control device 41 , however, the signal path 49 leads to an inverting input of the summer 60 . The triangular output voltage of the triangular oscillator 48 is therefore phase shifted in the band tension control device 42 with respect to the band tension control device 41 by 180 °. An oscillatory tilting of the tensioning roller 4 is thereby achieved.

The summer 60 receives the actual value from a force sensor 61 via a signal path 62 or from the displacement sensor 31 via the signal path 63 . The result of the actual-target value comparison of the summer 60 is fed to a controller 64 with PID behavior. The controller 64 generates at its output a correction signal which is given to a power amplifier 66 via a signal path 65 . In the signal path 65 , a switch 67 is provided, which connect the power amplifier 66 to the controller 64 in the basic position shown. On the output side, the power amplifier 66 is connected to an actuator 69 of the adjusting device 13 . The adjusting device 13 is constructed symmetrically to the adjusting device 12 , so that a repeated description is unnecessary.

The displacement sensor 10 of the guide roller 3 is connected via a signal path 70 to window comparators 71 , 72 . The switching thresholds of the window comparators 71 , 72 are symmetrical about the rest position shown. If the displacement sensor 10 supplies a signal which is proportional to the angle between the guide roller 3 and the normal 73 to the belt running direction 15 , the switching thresholds of the window comparators 71 , 72 are symmetrical about the zero point. The window comparators 71 , 72 therefore operate in a manner as if they would compare the magnitude of the input voltage with fixed limit values U 1 and U 2. On the output side, the window comparator 71 is connected to a control input 78 of the changeover switch 67 via a signal path 76 . The window comparator 72 is connected via a signal path 77 to a sound generator or a signal lamp 80 . This emits an acoustic or optical signal for the operating personnel as soon as the guide roller 3 exceeds the outer limit value U₂ in its angular position. The limit values U₁ and U₂ of the window comparators 71, 72 are selected so that from its rest position, first the change-over switch 67 and only at even larger adjustment angles a Warnsi is discharged gnal for pivoting the guide roller. 3 It is also conceivable that in this case the tape will also be switched off.

If the angular position of the guide roller 3 exceeds the limit value U 1 , the changeover switch 67 switches to its active position. In this case, the changeover switch 67 connects the power amplifier 66 to a summer 91 via a signal path 90 . A non-inverting input 92 of the summer 91 is connected to the controller 51 via the signal path 52 . Another non-inverting input 93 of Summie rers 91 is connected via a signal path 94 to another source. The sum mier 91 superimposes a constant voltage on the output signal of the regulator 51 . The movements of the actuators 54 and 69 are therefore coupled to one another. It is only a synchronous movement of the bearing 5 of the tensioning roller 4 possible in the same direction. The tensioning roller 4 can take any angular position to the tape running direction 15 .

Another summer 95 is connected to the controller 51 with an inverting input 96 via the signal path 52 and to the controller 64 with a non-inverting input 97 via the signal path 65 . The summer 95 calculates the difference of the output signals of the controllers 64 and 51 . On the output side, the summer 95 is connected to a sample hold amplifier 99 via a signal path 98 . The sample-hold amplifier 99 has an edge-triggered control input 100 which is operatively connected to the window comparator 71 via the signal path 76 . If the guide roller 3 exceeds the limit value U 1 in its angular position, the sample-hold amplifier 99 stores the voltage value arriving via the signal path 98 , that is to say the difference between the output signals of the controllers 64 and 51 . This stored voltage value is output via signal path 94 to input 93 of summer 91 . The summer 91 therefore calculates the sum of the output signal of the controller 51 with the difference of the output signals of the controllers 64 and 51 at the time of switching over the window comparator 71 . This leads to the tension roller 4 being held in its angular position when the limit value U 1 of the angular position of the guide roller 3 is reached.

The force sensors 44 and 61 are in active connection with an average value generator 110 , which is formed by a summer 111 and an amplifier 112 . The amplifier 112 has a gain factor of 0.5. On the output side, the amplifier 112 is connected to a changeover switch 114 via a signal path 113 . In its basic position shown, the changeover switch 114 connects the signal path 45 of the summer 43 , that is to say the actual value input of the control device 41 , via a signal path 115 to the force sensor 44 . A control input 116 of the changeover switch 114 is connected to the window comparator 71 via the signal path 76 . If the window comparator 71 switches over, the changeover switch 114 connects the summer 43 of the strip tension control device 41 to the mean value generator 110 . In this case, the belt tension control device 41 no longer controls the belt tension on one side of the endless belt 2 , but rather the middle belt tension of the endless belt 2 .

In Fig. 3 an alternative device 1 is shown schematically as a block diagram Darge. The same reference symbols again mean the same parts. Since essential parts of this device 1 are the same as the device from FIG. 2, only the differences between the two devices are discussed below. The adjusting devices 12 , 13 are connected to one another by means of a coupling K in such a way that the adjusting device 12 effects a synchronous adjustment of the bearings 5 of the tensioning roller 4 in the same direction. The adjustment device 13 acts only on a bearing 5 of the tensioning roller 4 , the movement of which is superimposed on the synchronous adjustment in the same direction by the adjustment device 12 . Adapted to this mode of operation of the adjustment devices 12 , 13 , the strip tension control device 41 controls the mean value of the measured strip tension and the strip tension control device 42 controls the measured strip tension difference between the right and left sides of the endless belt 2 . The mean value generator 110 is therefore connected directly to the summer 43 of the strip tension control device 41 via the signal path 45 . The summer 95 is connected with its inverting input 96 and its non-inverting input 97 to the outputs of the force sensors 44 , 61 . The sample hold amplifier 99 is connected directly to the output of the strip tension control device 42 via the signal path 65 . When the action range of the tensioning roller 4 is exceeded, the current inclined position of the tensioning roller 4 is stored in the sample-hold amplifier 99 and output to the adjustment device 13 via the switch 67 . This causes a constant holding of the angular position of the tensioning roller 4 , so that its bearings 5 can only be adjusted in the same direction in syn chron.

Claims (18)

1. A method for controlling the tension of a circulating endless belt ( 2 ) by adjusting a tension roller ( 4 ) on both sides and for guiding the endless belt ( 2 ) by pivoting a guide roller ( 3 ) with which a detected voltage from the tension of the endless belt ( 2 ) caused lateral course is corrected, characterized in that the tensions of the endless belt ( 2 ) areas on both edges are detected independently of each other and these are each independently controlled to a setpoint. 2. The method according to claim 1, characterized in that for independent control of the strip tension on both sides, the mean value of which is regulated by synchronously adjusting in the same direction and whose difference by adjusting the ends of the tensioning roller ( 4 ) in opposite directions. 3. The method according to claim 1 or 2, characterized in that the angular position of the guide roller ( 3 ) is detected and compared with an action range defined between two limit values, when exceeded, the bilateral independent belt tension control is interrupted. 4. The method according to claim 1 or 2, characterized in that the angular position of the guide roller ( 3 ) is detected and compared with an action range defined between two limit values, when exceeded, the bilateral independent belt tension control is interrupted and after falling below a narrower action range than the previously defined is reactivated. 5. The method according to at least one of claims 1 to 3, characterized in that after the exceeding of the range of action, the regulation of the belt pulls is coupled, the ends of the tensioning roller ( 4 ) being adjusted synchronously in the same direction and the angular position of the tensioning roller ( 4 ) constant is held. 6. The method according to claim 5, characterized in that the coupled belt tension control for synchronous adjustment of the tensioning roller ( 4 ) is carried out by averaging the detected belt tension and regulation of the mean. 7. The method according to at least one of claims 1 to 6, characterized in that that after the action area has been exceeded, an optical or acoustic signal nal is delivered. 8. The method according to claim 1, characterized in that for the correction of the lateral course of the endless belt of the position control by the guide roller ( 3 ) one of the angular position of the tension roller ( 4 ) proportional signal is superimposed. 9. Device for carrying out the method according to one of claims 1 to 8, characterized in that on both bearings ( 5 ) one of the rollers ( 3 , 4 ) act forces sensors ( 44 , 61 ), which independent strip tension control devices ( 41 , 42 ) are arranged, which are in operative connection with the actuators ( 54 , 69 ) of the tensioning roller ( 4 ). 10. The device according to claim 9, characterized in that one of the actuators be ( 54 ) the tension roller ( 4 ) on both bearings ( 5 ) via at least one gear (G₁, G₂) in parallel and the other actuator ( 69 ) on the tension roller ( 4 ) with at least one of the gears (G₁, G₂) causes an angle adjustment. 11. The device according to claim 10, characterized in that at least the tensioning roller ( 4 ) parallel adjusting gear (G₁, G₂) is designed as a planetary gear. 12. The device according to at least one of claims 9 to 11, characterized in that between a belt tension control device ( 42 ) and an actuator ( 69 ) of the tensioning roller ( 4 ) at least one switch ( 67 ) is provided, which has a control input ( 78 ) which is in operative connection with at least one window comparator ( 71 , 72 ), the window comparator ( 71 , 72 ) on the input side being in operative connection with a displacement sensor ( 10 ) detecting the angular position of the guide roller ( 3 ). 13. The apparatus according to claim 12, characterized in that the window comparator ( 71 , 72 ) has a Schmitt trigger input ( 74 , 75 ). 14. The apparatus of claim 12 or 13, characterized in that the switch operated by the window comparator ( 71 ) switch ( 67 ) is operatively connected to a summer ( 91 ) having inputs ( 92 , 93 ), one of which with the band tension control device ( 41 ) of the opposite edge region of the endless belt ( 2 ) is in operative connection. 15. The device according to at least one of claims 9 to 14, characterized in that the belt tension control devices ( 41 , 42 ) are in operative connection with a summing unit ( 95 ) calculating a difference in their output signals, the summing unit ( 95 ) on the output side with a the difference storing sample-hold amplifier ( 99 ) is in operative connection, which is connected to one of the inputs ( 93 ) of the switch ( 67 ) provided at the summer ( 91 ), the sample-hold amplifier ( 99 ) having an edge-triggered control input ( 100 ), which is in operative connection with the window comparator ( 71 ). 16. The device according to at least one of claims 9 to 14, characterized in that the sample hold amplifier is connected on the input side to the output of the band tension control device ( 64 ) and on the output side to the changeover switch ( 67 ), its control input ( 100 ) is in operative connection with the window comparator ( 71 ). 17. The device according to at least one of claims 9 to 16, characterized in that the force sensors ( 44 , 61 ) are in operative connection with a mean value image ( 110 ), the output side with a switch operated by the window comparator ( 71 ) th switch ( 114 ) is in operative connection, which is provided between the force sensor ( 44 ) and the belt tension control device ( 41 ). 18. The device according to at least one of claims 9 to 17, characterized records that at least part of the computing and / or switching functions by means of a Computers is realized.