The invention relates to a winding device for winding up a ribbon or web, in particular a carrier web, following the dispensing of labels.
EP 1 663 791 B1 (corresponding to U.S. Pat. No. 8,012,279) shows, by way of example, the structure of a labelling device and a labelling device with unwinder and rewinder.
Labelling devices are used nowadays for increasingly wide labels and increasingly fast labelling speeds. The labels are in some cases hereby dispensed in cyclic operation, so that a speed profile for the movement of the label web is predetermined and the label web is stopped between the individual dispensing actions. This leads to powerful accelerations (positive and negative). These demanding requirements can lead to malfunctions in the rewinding device or rewinder.
It is therefore an object of the invention to provide a new winding device. The object is achieved by equipping the winding device with a drive shaft, a positive engagement gear, a clutch shaft, an energy storage means, a clutch, and an output shaft, configuring the clutch to selectively transmit, or not transmit, torque from the drive shaft to the output shaft, at different respective transmission ratios, arranging the energy storage means to temporarily store energy from the drive shaft while simultaneously increasing the transmission ratio, relative to a first predetermined transmission ratio, and to release stored energy to the output shaft, while simultaneously decreasing the transmission ratio, relative to the first predetermined transmission ratio.
According to this, the energy storage means can temporarily store at least a part of the energy transmitted via the gear in the form of potential energy and thereby simultaneously increase the transmission ratio between the drive shaft and the clutch shaft. The stored potential energy can subsequently be released with simultaneous lowering of the transmission ratio.
The use of the positive-engagement gear makes possible a good transmission of torque. The provision of the energy storage means thereby makes it possible to reduce the slip on the clutch. This leads, on the one hand, to less wear on the clutch and to less generation of heat on the clutch, and on the other hand the risk of unsatisfactory rewinding on the winding device is reduced.
According to a preferred embodiment, the energy storage means is configured to store the potential energy in a spring element. This makes possible a good release of the energy stored in the spring element.
According to a preferred embodiment, the energy storage means is configured to enable a storage of potential energy with simultaneous lowering of the transmission ratio relative to the first predetermined transmission ratio, and then to enable a release of the stored potential energy with simultaneous increase of the transmission ratio relative to the first predetermined transmission ratio. As a result, the energy storage means can have an advantageous effect on braking of the drive shaft.
According to a preferred embodiment, the gear is configured as a gear drive. Gear drives allow the transmission of high torques.
According to a preferred embodiment, the energy storage means comprises the first clutch shaft element and a second clutch shaft element assigned to the first clutch shaft element, said second clutch shaft element being firmly connected to the clutch shaft, wherein the first clutch shaft element and the second clutch shaft element are arranged concentrically with the clutch shaft and are rotatable relative to each other, wherein at least one spring element is arranged between the first clutch shaft element and the second clutch shaft element, said spring element being configured, on a rotation of the first clutch shaft element relative to the second clutch shaft element in a first predetermined direction of rotation, at least partially to absorb potential energy in the form of spring energy, and on a relative rotation in a second direction of rotation opposite to the first direction of rotation, at least partially to release the potential energy again. This makes possible a rotary energy storage means.
According to a preferred embodiment, a first damping element is provided which is configured at least partially to dampen a rotation of the first clutch shaft element relative to the second clutch shaft element in the second direction of rotation. Such a damping element reduces the risk of a transmission of a high torque from the clutch shaft to the drive shaft.
According to a preferred embodiment, a second damping element is provided which is configured at least partially to dampen a rotation of the first clutch shaft element relative to the second clutch shaft element in the first direction of rotation. Such a damping element reduces the risk of a transmission of a high torque from the clutch shaft to the drive shaft.
According to a preferred embodiment, a first stop is provided in order to limit a rotation of the first clutch shaft element relative to the second clutch shaft element in the first direction of rotation. The provision of a stop facilitates the mounting of a damping element.
According to a preferred embodiment, the stop is arranged at least partially in the spring element in order to effect a guidance of the spring element. This means that the spring element can also be guided from within, and this improves the guidance of the spring.
According to a preferred embodiment, the gear is configured as a positive-engagement traction gear, said traction gear having a traction means, said traction means interacting with the drive shaft and with the first clutch shaft element in order to enable a transmission of torque from the drive shaft to the clutch shaft. Tests have shown that a distance between the drive shaft and the clutch shaft can readily be bridged through the traction means.
According to a preferred embodiment, the traction gear is configured as a toothed belt gear with a toothed belt as traction means, and the first clutch shaft element is configured as a belt pulley. A toothed belt gear requires less maintenance and is particularly suitable since it is only subject to a small degree of wear.
According to a preferred embodiment, the traction gear is configured as a chain gear with a chain as traction means, and the first clutch shaft element is configured as a sprocket. Chain gears can be used for very high forces; however, they usually require lubrication.
According to a preferred embodiment, the energy storage means comprises a carriage guide and a carriage, said carriage being displaceable relative to the carriage guide, wherein at least one spring element is arranged between the carriage and the carriage guide, and wherein the carriage has at least one first pulley, wherein the winding device defines a first partial path for the traction means between the drive shaft and the first clutch shaft element and a second partial path between the first clutch shaft element and the drive shaft, and wherein the first pulley is, in the first partial path, in contact with the traction means, so that a displacement of the carriage results in a shortening or lengthening of the first partial path depending on the direction of displacement, and said energy storage means is configured to enable an absorption of energy in that the first partial path is changed such that the transmission ratio is increased relative to the first predetermined transmission ratio through this change in the first partial path and potential energy is thereby stored in the spring element, and to enable a release of the stored energy in that the first partial path is changed such that the transmission ratio is lowered relative to the first predetermined transmission ratio through this change in the first partial path and the potential energy stored in the spring element is thereby released. As a result, the energy storage means can in particular be activated upon acceleration of the drive shafts.
According to a preferred embodiment, the energy storage means is configured to enable an absorption of energy in that the first partial path is changed such that the transmission ratio is lowered relative to the first predetermined transmission ratio through this change in the first partial path and potential energy is thereby stored in the spring element, and to enable a release of the stored energy in that the first partial path is changed such that the transmission ratio is increased relative to the first predetermined transmission ratio through this change in the first partial path and potential energy stored in the spring element is thereby released. As a result, the energy storage means can in particular be activated on an acceleration of the drive shafts.
According to a preferred embodiment, the carriage has a second pulley, said second pulley being, in the second partial path, in contact with the traction means in order to effect a compensation in length between the first partial path and the second partial path. This renders unnecessary additional means for length compensation.
According to a preferred embodiment, a damping element is provided at at least one end position of the carriage which is configured to dampen the movement of the carriage towards a first end position, wherein damping elements are preferably provided at both end positions of the carriage. In tests, a drive with powerful acceleration and powerful braking under extreme conditions led to a high torque on the clutch shaft being transmitted powerfully to the drive shaft in the case of a stop without damping element, and this can lead to malfunctions of the drive. This risk is reduced through the provision of the damping elements, and these have proved very advantageous.
According to a preferred embodiment, at least one end position of the carriage is defined by a stop, preferably both end positions. This prevents an overstretching of the springs, and the stops can readily be provided with a damping element.
According to a preferred embodiment, the winding device has a pendulum, said pendulum being able to assume variable pendulum positions, wherein the clutch is configured to influence the connection between the output shaft and the clutch shaft depending on the variable pendulum position. The use of a pendulum is particularly advantageous for the winding device, since the risk of a loose web is reduced.
According to a preferred embodiment, the pendulum has a web guide for guiding a web, and the pendulum position is dependent on the tension of the web. The web tension has proved to be an advantageous criterion for control in the region of the winding device.
According to a preferred embodiment, the winding device has a braking device, said braking device being configured to enable a controllable braking of the output shaft. In combination with a positive-engagement gear, such a braking device has proved advantageous for safe operation with large reels.
According to a preferred embodiment, the winding device has a pendulum, said pendulum being able to assume variable pendulum positions, wherein the braking device is configured to influence the controllable braking of the output shaft depending on the variable pendulum position. As a result, the braking device can be combined with the pendulum function, and the braking takes place in a readily reproducible manner.
According to a preferred embodiment, the winding device is configured, depending on the web tension,
Such a winding device makes safe operation possible, even with large, heavy reels and high speeds and accelerations.
According to a preferred embodiment, the labelling device has a drive for movement of a label web for the dispensing of labels and a winding device, wherein the drive is configured also to drive the drive shaft for the winding device. In this embodiment, the energy storage means is particularly advantageous, since the drive is actuated depending on the dispensing of the label web and can nonetheless be used reliably to drive the reel. Moreover, no additional drive is necessary.
Further details and advantageous further developments of the invention are disclosed in the exemplary embodiments described in the following and illustrated in the drawings.
Terms such as left, right, top, bottom, clockwise and anticlockwise relate to the figure in question and can change from figure to figure. The same reference symbols are used for identical parts or parts with the same function, and they are usually only described once.
A reel 111 with a label web 130 is arranged on the rewinder 110. The label web 130 comprises a carrier web 131 and labels 132 arranged thereon. The label web 130 runs from the label web reel 111 via a braking device 115 to the dispensing device 140. The dispensing device 140 has a dispensing beak 141, and the label web 130 is passed around the dispensing beak 141. Since the label web 130 performs a sudden change in the direction of movement at the dispensing device 140, the corresponding label 132 is detached from the label web 130 and projects forwards from the dispensing device 140. An object to be labelled 142 can be passed by the dispensing device 140 and the dispensed label 132 applied to the object 142. The remaining carrier web 131 of the label web 130 is, by way of example, fed back to the labelling device 12, and a drive device 14 with a drive roller—not visible—is provided on the labelling device 12 which drives the carrier web 131. The carrier web 131 then runs on further to the winding device 10 where it is rewound. Because the label web 130 or carrier web 131 is pulled over the dispensing device 140 by the drive roller and is braked, on the feed side, by the braking device 115, it lies taughtly or under tension against the dispensing device 140.
In operation, the label web 130 can either be driven continuously by the drive device 14 or a cyclic operation can be carried out, in which the label web 130 is briefly stopped between the dispensing actions until the next object to be labelled 142 is positioned at the dispensing device 140. Modern high-speed labelling machines 12 dispense labels 132 at the dispensing device 140 with a label web speed of for example 3.3 m/s in cyclic operation, that is to say, very high speeds and accelerations are possible.
The rotation of the rewinder 110 is influenced by a pendulum 112 which changes its pendulum position depending on the tension of the label web 130.
The rotation of the winding device 10 is influenced by a pendulum 69 which changes its pendulum position, depending on the tension of the carrier web 131. For this purpose, for example a spring—not shown—is connected with the pendulum 69 which applies a force to the pendulum in an anticlockwise direction of rotation, so that the carrier web tension can act against this force. The pendulum 69 can also be described as a lever or arm. The pendulum 69 serves on the one hand to measure the web tension of the carrier web 131. On the other hand, it also has the function, through its rotation, of effecting a web compensation, in order that the web tension does not become too high or too low.
A drive device 14 is provided around the labeler 12, for example an electric motor, a servo drive or a pneumatic drive. The drive device 14 drives a drive shaft 20, wherein the drive shaft 20 drives the label web via a—not shown—drive roller. The drive shaft 20 is also connected directly or indirectly with a drive shaft element 21, and the winding device 10 is also driven via this drive shaft element. For this purpose, a traction gear is provided which enables a rotation of the drive shaft element 21 on a first clutch shaft element 61.
The traction gear 30 is configured as a positive-engagement traction gear with a traction means 32, said traction means 32 interacting with the first clutch shaft element 61 and the drive shaft element 21 and enabling a transmission of torque from the drive shaft element 21 to the first clutch shaft element 61. The path of the traction means 32 is additionally influenced through a pulley 34, and the pulley 34 causes an enlargement of the peripheral range over which the traction means 32 lies against the drive shaft element 21 and the first clutch shaft element 61. In addition, the opening in the labeler 12 which is provided for the path of the traction means 32 can be made smaller.
The traction gear 30 is configured as a toothed belt gear with a toothed belt as traction means 32 and with a belt pulley as first clutch shaft element 61. The drive shaft element 21 can also be configured as a belt pulley.
Alternatively, the traction gear 30 can be configured as a chain gear with a chain as traction means 32, and the first clutch shaft element 61 and preferably also the drive shaft element can be configured as a sprocket.
As a result of the positive-engagement configuration of the traction means—unlike for example a round belt gear or V-belt gear—no slipping is possible. This is advantageous since, in the case of a round belt gear, slipping leads to wear and to soiling in the region of the gear.
The winding device 10 has a flange 150 onto which parts can be attached. The pendulum 69 with the web guide 70, in the form of a roller, is shown.
The spring elements 52 are, by way of example, configured as coil springs, and a curved bow spring is preferably used. However, other spring elements 52, for example disc springs, are also possible.
The second clutch shaft element 62 lies against a first damping element 66, said first damping element 66 consisting for example of a PU (polyurethane) foam such as VULKOLLAN (U.S. Pat. Nos. 1,572,694 & 5,273,576) or an elastomer. This simultaneously forms a stop. It can be specified, from the relative rotary position of this stop, whether the spring element 52 is preloaded in the first state Z1, and if so how high this preloading is. However, the preloading can also for example be effected via the selection of the spring element 52. A first stop 68 is provided on the first clutch shaft element 61, and a damping element 67 is provided on the first stop 68 which consists, for example, of a soft component of a 2-component injection molding process, of an elastomer or of a PU (polyurethane) foam. The spring elements 52 are relaxed or slightly preloaded in the first state Z1, and the second clutch shaft element 62 lies against the damping element 67.
As a result of a rotation of the drive shaft element 21, the traction means 32 (see
i=n_21/n_61
With the clutch 60 closed (see
If the clutch 60 is, for example, configured as a friction clutch, slip can occur if, due to the high inertia of the reel 90, the torque to be transmitted via the clutch 60 becomes greater than a maximum torque which is to be transmitted by the clutch 60. In this case, the rotation of the first clutch shaft element 61 is only partially transmitted to the output shaft 80, and it is partially converted into heat in the clutch 60 through friction.
The energy storage means 50 is provided, in order to reduce or preferably completely prevent slip in the clutch 60. In the event of a powerful acceleration of the traction means 32 in the direction of rotation 64 indicated in
If the spring element 52 is compressed, it attempts to relax again and release the potential energy. This takes place, in that the spring element 52 rotates the second clutch shaft element 62 relative to the first clutch shaft element 61 in the direction of rotation 64. As the spring element 52 is relaxed, the potential energy stored in the spring element 52 is thus released again, and the transmission ratio i is lowered in comparison with the basic transmission ratio i_0 without the influence of the energy storage means 50, since the rotational speed n_63 of the clutch shaft 63 is increased on release of the potential energy in relation to the rotational speed n_61 of the first clutch shaft element 61. Thus, on release of the potential energy: i<i_0.
The consideration of the relative rotation between the first clutch shaft element 61 and the second clutch shaft element 62 simplifies the consideration of the energy flow. However, the actual rewinding of the carrier web 131 usually only takes place in one direction of rotation, and both the first clutch shaft element 61 and also the second clutch shaft element 62 fundamentally rotate in the same direction of rotation 64 on a transmission of torque. The rotational speed n_62 of the second clutch shaft element 62 is hereby somewhat lower during the storage of energy in the energy storage means (transition in the direction from Z1 to Z2) than the rotational speed n_61 of the first clutch shaft element 61, and on releasing energy from the energy storage means (transition in the direction from Z2 to Z1) the rotational speed n_62 is somewhat higher than the rotational speed n_61, wherein both clutch shaft elements 61, 62 usually rotate in the same direction of rotation 64.
The energy storage means 50 thus causes a delayed transmission of the energy transmitted from the drive shaft element 21 or of the torque transmitted from the drive shaft element 21 to the clutch shaft 63 or to the output shaft 80.
The damping element 67 on the stop 68 prevents a hard stop of the stop 68 against the second clutch shaft element 62. Tests have shown that in the event of a hard stop a torque such as a jerk can be transmitted via the traction gear 30 to the drive shaft 20 (see
The line 201 shows the speed with which the carrier web 131 is accelerated and braked again by the labeler 12 (see
The line 202 shows the speed with which the web is wound onto the reel 90. Where an additional drive is used for the winding device 10, the rotational speed can be adjusted to the necessary rotational speed. However if, as in the exemplary embodiment, the drive for the labeler 12 is used directly, which can also be described as a passive function of the main drive, the speed is dependent on how much web 131 has already been wound onto the reel 90, since the diameter of the rewound web 131 increases during rewinding. The speed is for example adjusted such that a maximum speed occurs with an empty reel 90 which corresponds to 110 percent of the speed of the web 131 at the labeler 12. This means that a reserve is provided, if for example a slip occurs in the clutch 60 or if for example the web 131 is not tensioned to begin with.
The line 203 shows the speed of the web on the reel 90 if a slip occurs on the clutch 60 and no energy storage means 50 is provided. Due to the powerful acceleration at the rising edge, a slip occurs in the clutch 60, and the rotary movement is initially largely translated into frictional heat in the clutch 60, not into a rotation of the reel 90. At a certain point, the clutch engages, and the output shaft 80 is powerfully accelerated. However, shortly after reaching the maximum rotational speed, the web speed is lowered again due to the falling edge. The total path covered corresponds to the area below the respective curve. The area below the curve 203 is less than the area below the curve 201, and therefore the winding device 10 takes in less web than is moved by the labeler 12. This can lead to the web no longer being taut, or even falling to the ground or becoming entangled in another part. This is an undesirable state. In tests, in particular with very short labels with high accelerations, a slip in the clutch 60 has led to problems since the clutch 60 has become very heated due to the slip occurring at short intervals, and the drive of the reel 90 was insufficient. With longer labels too, the heating of the clutch 60 was critical, but the drive of the reel was less critical.
Tests were also carried out with a clutch with high coupling force in order to reduce the slip. These tests led to a high torque being transmitted to the drive of the labeler 20, and the drive registered an overload.
The line 204 shows the web speed on the winding device 10 using the energy storage means 50. Since the movement caused through the traction means 32 is only partially transmitted to the clutch shaft 63 and is partially used for the storage of potential energy in the energy storage means 50, the output shaft 80 can follow the movement of the clutch shaft 63 with the reel 90. No slip, or only a slight slip, occurs in the clutch 60. The potential energy stored in the energy storage means is translated at a later time into an additional rotation of the clutch shaft 63 and thus also the output shaft 80, and as a result an increase in the maximum rotational speed of the output shaft 80 and thus an increase in the web speed can occur. The area below the line 204 is greater than the area below the line 201, and the winding device 10 can therefore work well.
These remarks apply to a closed clutch 60. In the case of an opened clutch 60, the mass adhering to the clutch shaft 63 is much smaller, and therefore the second clutch shaft element 62 can follow the first clutch shaft element 61 without any problem, and either no compression or only a slight compression of the spring element 52 occurs.
The spring element 52 is, as in
The second pulley 56 serves the purpose of length compensation of the path for the traction means 32. This length compensation is advantageous; however, it can also be achieved through an additional length compensation device. The second pulley 56 is thus not essential.
At the end position of the carriage 54, as shown in
Preferably, at least one end position of the carriage 54 is defined by a stop, preferably both end positions. The stops can also be formed through the damping elements 66, 67 in that these are configured as stops with a rubber-elastic end or with another relatively soft material such as PU (polyurethane) foam. However, the stops and damping elements can also be configured as separate components in the exemplary embodiments.
The energy storage means 50 from
This leads to a relief of the clutch 60, since the risk of a slip is reduced or wholly prevented, and the movement of the traction means 32 can as a result be translated into a rotation of the clutch shaft 63, completely or at least to a greater extent than without the use of an energy storage means 50.
If the linear energy storage means from
In the linear energy storage means shown in
The traction means 32 runs parallel to the first pulley 55 and to the second pulley 56, and this has the advantage that the length compensation is exactly equal on a displacement of the carriage 54.
In other words, the spring element 52 is configured, on a rotation of the first clutch shaft element 61 relative to the second clutch shaft element 62 in a first predetermined direction of rotation 64, to partially absorb potential energy in the form of spring energy, namely on a rotation from the state Z1 in the direction of the state Z2, and on a relative rotation in the second direction of rotation 65 opposite the first direction of rotation 64, to release the previously stored potential energy again, namely on a rotation from the state Z2 back in the direction of the state Z1.
In addition, the spring element 52 is configured, on a rotation of the first clutch shaft element 61 relative to the second clutch shaft element 62 in a predetermined direction of rotation 65, to partially absorb potential energy in the form of spring energy, namely on a rotation from the state Z1 in the direction of the state Z2′, and on a relative rotation in the direction of rotation 64 opposite this direction of rotation 65, to release the previously stored potential energy again, namely on a rotation from the state Z2′ back in the direction of the state Z1.
A value i0 shows the basic transmission ratio of the traction gear 30 if the energy storage means 50 remains unchanged. For example the rising edge from
The state of the energy storage means 50 then changes from the state Z2 back to the state Z1.
At the time t2, the energy storage means 50 has been depleted, and the transmission ratio i once again corresponds to the basic transmission ratio i0 of the traction gear 30.
By way of explanation, reference is always made to a movement between the first state Z1 and the second state Z2. However, one of the end states Z1, Z2 is not reached every time, and the amount of potential energy stored in the energy storage means depends on numerous factors, in particular on the acceleration of the drive shaft 20 and on the mass of the reel 90.
A value i0 shows the basic transmission ratio of the traction gear 30 if the energy storage means 50 remains unchanged. For example, the rising edge from
The state of the energy storage means 50 then changes from the state Z2′ back to the state Z1, wherein the transmission ratio i is increased in this region, since the clutch shaft 63 is additionally braked on conversion of the energy from the spring elements 52.
At the time t2, the energy storage means 50 has been depleted, and the transmission ratio i once again corresponds to the basic transmission ratio i0 of the traction gear 30.
A bolt 152 is fixed to the housing flange 150, for example through a screwed connection. The bolt 152 is indicated with dots in order to facilitate understanding. The output shaft 80 is guided in the bolt 152, and a pot 84 is attached non-rotatably at the left-hand end of the output shaft 80. The clutch shaft 63 is mounted rotatably on the output shaft 80 and connected non-rotatably with the second clutch shaft element 62, preferably being formed in a single piece with this. A clutch disc 85 is provided on the second clutch shaft element 62 which is configured to interact with the pot 84 in order so to enable a closing of the clutch 60 to form a frictional connection. The second clutch shaft element 62 is connected with the first clutch shaft element 61 via one or more bearings 162 and is in operative connection with the first clutch shaft element 61 via the spring elements 52. The energy storage means 50 comprises the first clutch shaft element 61, the second clutch shaft element 62 and the spring element 52, and it corresponds to the energy storage means from
The traction means 32 is in contact with the first clutch shaft element 61 and can drive this. A clamping piece 160 is connected with the right-hand end of the output shaft 80, and an axial bearing 158 is arranged on the left-hand side of the clamping piece 160. A socket 156 sits on the bolt 152, wherein a thread 153 is provided between the bolt 152 and the socket 156. The pendulum 69 is connected non-rotatably with the socket 156, and as a result a rotation of the pendulum 69 leads to a relative rotation between the socket 156 and the bolt 152 and, via the thread 153, simultaneously to an axial displacement of the socket 156 relative to the bolt 152. If the socket 156 is moved to the right through the axial displacement, it presses against the axial bearing 158 and, via this, against the clamping piece 160. As a result, the output shaft 80 is shifted to the right, and this leads to a clamping between the pot 84 and the second clutch element 62 or the clutch disc 85. As a result, a frictional connection is created between the second clutch shaft element 62 and the output shaft 80, and a torque can be transmitted from the traction means 32 via the clutch 60 to the output shaft 80. If, in contrast, the socket 156 is moved to the left relative to the bolt 152, the pot 84 moves away from the clutch disc 85, and the clutch 60 is opened. In the exemplary embodiment, the thread has an axial displacement of approximately 1 mm on a rotation of the pendulum 69 by 90°; the clutch 60 thus only requires a small axial displacement of the pot 84 in order to change between the opened and closed states.
The illustrated advantageous exemplary embodiment allows a change in the pendulum position of the pendulum 69 to be translated directly into an opening or closing of the clutch 60. Naturally, it is for example also possible to use an electronic clutch 60 and to ascertain the position of the pendulum 69 via a sensor, in order to influence the clutch 60, depending on the determined value.
The configuration in which the bolt 152 is configured as a hollow shaft makes possible a compact structure. However, the output shaft 80 could for example also be continued to the left, and a simple disc clutch could be used.
This rotation of the eccentric 218 makes possible a deflection of the main part 210 in a clockwise direction, and as a result a braking effect can be achieved through the braking device 200.
In the exemplary embodiment, a gear drive (not shown) with a transmission ratio of 1:2 is provided between the pendulum 69 and the eccentric 218, so that a deflection of the pendulum by 90 degrees causes a rotation of the eccentric 218 by 180 degrees.
Other braking devices, for example electronic braking devices with motors, can also be provided, and the configuration with the pendulum 69 can also be such that for example the pendulum 69 is configured eccentrically in its region facing the main body 210 and on a rotation from the state B1 into the state B2 the main part 210 moves in a clockwise direction in that it presses directly on the main part 210.
In the range between the pendulum positions P2 and P3, the clutch 60 is opened, and the braking device 200 is not yet active. The reel 90 can thus rotate, and it is neither accelerated via the traction gear 30 nor braked via the traction gear 30, or through the braking device 200. Thus, if the label web is advanced by the labeler 12, the output shaft 80 is not driven by the drive shaft 20; instead, the pendulum 69 is moved in the direction of the pendulum position P2.
Between the pendulum positions P3 and P4, the clutch 60 is again opened, and the braking device 200 from
The three-zone model shown in
Naturally, a wide range of variance and modifications is possible within the scope of the invention.
In the embodiments, a cyclic operation of the labeler 12 is shown in which the invention is particularly advantageous due to the high accelerations (positive and negative) which occur. However, the winding device 10 can also be used for a continuous operation in which the label web is not stopped between each dispensing action.
Instead of the pendulum 69, another measuring device can be used to ascertain the web tension of the carrier web 131. For example, web tension measuring devices can be used which use a deflection stamp to measure the deflecting force, or optical frequency meters which measure the vibration of the web which is dependent on the web tension.
Number | Date | Country | Kind |
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10 2017 113731.9 | Jun 2017 | DE | national |
This application is a section 371 of PCT/EP2018/064,507 filed 1 Jun. 2018.
Filing Document | Filing Date | Country | Kind |
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PCT/EP2018/064507 | 6/1/2018 | WO | 00 |