EP3405636B1 - Door drive device, overhead door, and operating method therefor - Google Patents

Description

The invention relates to a sectional door and a roller door. The invention also relates to an operating method for the sectional door and the roller door.

DE 20 2010 007 951 U1 discloses an assembly of an automatic gate with vertical movement, comprising a gate with at least one element with a substantially linear stroke, a motorized device for opening and closing the gate, and a control unit that controls the motorized device, the assembly also having an element on one element accelerometer mounted with substantially linear travel of the door and arranged to sense acceleration of the member, means for comparing the reading of the accelerometer to a range of predetermined values, and means for actuating the motorized means via the control unit if the reading of the accelerometer is not in is in the range of predetermined values.

WO 2015 / 078 453 A1 discloses a device for detecting the force used by the drive when moving industrial doors, in which the door control is assigned a force detection component that determines a force curve each time the industrial door moves. These force curves are stored in a memory and can be used for comparison with the force curve that follows in each case in order to identify any dangerous situations and switch the drive accordingly. The force detection component then ensures that the industrial door is stopped when driving upwards, initiated by the button and divergences occurring between the force curves, while when driving downwards, initiated by the button from the upper end position, to which it has automatically reversed, can be moved down again. If there is another divergence in the force curves, a new force curve can be determined with the help of the button then switched to the dead man's switch, which is then the starting point for further operation of such an industrial door.

EP 2 388 424 A2 discloses a gate drive apparatus mountable relative to a gate leaf guide and connectable to the gate leaf for driving a gate leaf in a number of different ways, and having a control device for controlling and monitoring a gate drive movement. A mounting type detection device is provided, by means of which the respectively selected mounting type can be detected. The control device is designed in such a way that it carries out the control and/or monitoring depending on the type of assembly detected. In addition, the invention relates to a door system that can be operated automatically and is designed with such a door drive device.

WO 2011 / 095 474 A1 discloses a gate drive device for driving a gate and a drive method for automatically driving the gate, the gate drive device being designed in such a way that it can detect the gate model of the gate to be driven.

DE 10 2009 050 185 A1 discloses a gate operator having a motor having a rotor. The rotor can be connected to a gate leaf to be driven by the gate drive device. The door drive device also includes a first rotation angle sensor for determining the current door position, the first rotation angle sensor being connected via a transmission gear to the rotor and/or a rotary member rotating with it in such a way that a total movement of a door leaf to be connected between its end positions is less than 360° a first rotary element of the first rotary angle sensor rotating for the rotary angle detection. The gate drive device comprises a second rotation angle sensor with a second rotation element for detecting the rotation angle, which rotates many times faster than the first rotating element of the first rotation angle sensor when the rotor and/or the rotating member rotating therewith rotates.

Gate drive devices, such as those in DE 20 2010 007 951 U1 and in WO 2015 / 078 453 A1 are disclosed are often designed and further developed with regard to their security. The revelations through EP 2 388 424 A2 , WO 2011/095 474 A1 and DE 10 2009 050 185 A1 show that improvements with regard to the installation and configuration of the controls and the drive devices themselves controlled by them are also of great interest.

What the known gate drive devices have in common, however, is that the transmission of the movement of the drive motor to the gate leaf and the effects of the interposed gears and the kinematic peculiarities inherent in the gate have so far been neglected. This is particularly the case with overhead doors such as roller shutters and sectional doors.

Out of U.S. 6,640,494 B2 , GB 2 341 948 A and AU 2009 100 649 A4 Gate drives with variable speed output are known.

DE 20 2014 103 264 U1 discloses a so-called soft stop, in which the door is slowly braked at the end of its movement.

In the case of overhead doors, more than with other types of door, there is usually the fact that when the door leaf is closing in the event of a collision with an obstacle, the not inconsiderable weight of the door leaf acts on the obstacle in addition to the driving force of the door operator. This can have particularly serious consequences in the event of a collision with a person, since the head is often the first point of contact with the door leaf due to the design. Consequently, it is important to secure overhead doors against such accident risks.

However, these safety requirements are fundamentally in a conflict of objectives with the most convenient and quickest possible operation of an overhead door. For example, it is conceivable that ambient conditions make it appear favorable for the door leaf to be closed and opened as quickly as possible; for example when the gate closes off a refrigerated warehouse. In addition, it can save energy if the opening and closing process is carried out as quickly as possible. One idea of the invention is to enable overhead doors to be operated in a more convenient, energy-saving and safer manner.

The object of the invention is to improve overhead doors, namely sectional doors and roller doors, and their operating methods.

The object is solved by the subject matter of the independent claims. Preferred configurations are the subject matter of the respective dependent claims.

The invention creates a sectional door or a roller door with a door leaf that can be moved between an open position and a closed position and has a main closing edge, with a door shaft that is operatively connected to move the door leaf between the open position and the closed position, and with a door drive device that is used to drive the Gate shaft is formed, wherein the gate drive device comprises a drive device which is designed to drive the gate shaft at an instantaneous drive speed and which is connected to the gate shaft, the drive device comprising a drive motor; and a control device which is designed to control the drive device in such a way that during a start-up the instantaneous drive speed is brought to a final start-up drive speed. According to the invention, it is proposed that the control device is also designed to control the drive device in such a way that during a closing drive following the start-up, the instantaneous drive speed decreases from the final start-up drive speed to a final drive drive speed depending on the design of the door, is continuously increased or continuously decreased, so that in the case of a sectional door the instantaneous drive speed is continuously reduced from the final drive speed to a final drive speed during the closing movement following the start-up, and in the case of a roller shutter during the closing movement following the start-up Closing driving the instantaneous drive speed is steadily increased from the final drive speed to the final drive speed, with the instantaneous main closing edge speed remaining essentially constant or steadily decreasing during the closing motion of the roller door.

According to the invention, the sectional door and the roller door are characterized in that the control device is also designed to control the drive device in such a way that during the start-up preceding the closing movement, the instantaneous drive speed is increased up to a maximum drive speed, so that the main closing edge moves to a position within a is accelerated by the normative requirements with regard to the maximum operating forces and/or the maximum door leaf speed in the prohibited area as long as the main closing edge is in a position above 2.5 m, with the current drive speed then being steadily reduced to the final drive speed.

It is preferred that the increase takes place with a characteristic adapted to the movement characteristics of the overhead gate.

It is preferred that the increase takes place with a polynomial, in particular linear, characteristic.

It is preferable for the increase to be monotonous, in particular strictly monotonous.

It is preferred that the lowering takes place with a characteristic adapted to the movement characteristics of the overhead gate.

It is preferred that the decrementing takes place with a polynomial, in particular linear, characteristic.

It is preferred that the decrease occurs monotonically, in particular strictly monotonically.

It is preferred that the control device is also designed to control the drive device in such a way that during a stop carried out after the opening drive, the instantaneous drive speed is continuously reduced from the final drive drive speed to a standstill.

It is preferred that the control device is also designed to control the drive device in such a way that during a stop carried out after closing travel, the instantaneous drive speed is continuously reduced from the final drive speed to a standstill.

It is preferred that the control device is also designed to control the drive device in such a way that during a stop following the fast driving, the instantaneous drive speed is continuously reduced from the maximum drive speed to a standstill.

It is preferred that the control device is designed in such a way that the instantaneous drive speed is continuously reduced from the final drive speed to a final drive speed during opening travel.

The control device is designed in such a way that, in the case of a roller shutter, the instantaneous drive speed is continuously increased from the end drive speed to a final drive speed during the closing process, with the instantaneous main closing edge speed remaining essentially constant or steadily decreasing during the closing of the roller shutter.

It is preferred that the control device is designed in such a way that the instantaneous drive speed is continuously increased from the final drive speed to a final drive speed during opening travel.

The control device is designed in such a way that, in the case of a sectional door, the instantaneous drive speed is continuously reduced from the final drive speed to a final drive speed during the closing process.

• Anfahren der Torwelle durch Erhöhen der Momentan-Antriebsgeschwindigkeit auf eine Endanfahrantriebsgeschwindigkeit derart, dass die Hauptschließkantengeschwindigkeit stetig zunimmt; und
• Schließfahren der Torwelle durch stetiges Erniedrigen der Momentan-Antriebsgeschwindigkeit in Abhängigkeit von der Bauart des Tores von der Endanfahrantriebsgeschwindigkeit auf eine Endfahrantriebsgeschwindigkeit, sodass bei einem Sectionaltor während des an das Anfahren anschließenden Schließfahrens die Momentan-Antriebsgeschwindigkeit stetig erniedrigt wird und bei einem Rolltor während des an das Anfahren anschließenden Schließfahrens die Momentan-Antriebsgeschwindigkeit von der Endanfahrantriebsgeschwindigkeit zu der Endfahrantriebsgeschwindigkeit stetig erhöht wird, derart, dass die Momentan-Hauptschließkantengeschwindigkeit während des Schließfahrens im Wesentlichen konstant bleibt oder stetig abnimmt.

The invention also provides a method for operating a sectional door or roller door as described above, with the steps:

• Starting the door shaft by increasing the instantaneous drive speed to a final drive speed such that the main closing edge speed increases steadily; and
• Closing of the door shaft by constantly reducing the instantaneous drive speed, depending on the type of gate, from the final drive speed to a final drive speed, so that in the case of a sectional door, the instantaneous drive speed is constantly reduced during the closing movement that follows the start-up, and in the case of a roller shutter during the Starting then closing the current drive speed from the final start drive speed to the final drive speed is steadily increased in such a way that the instantaneous main closing edge speed remains essentially constant or steadily decreases during the closing movement.

According to the invention, it is proposed for the method that the closing process is started by continuously increasing the current drive speed up to a maximum drive speed so that the main closing edge reaches a maximum main closing edge speed that is within a range that is prohibited by the normative requirements with regard to the maximum operating forces and/or the maximum door leaf speed is accelerated as long as the main closing edge is in a position above 2.5 m, and the current drive speed is then continuously reduced to the final drive speed.

The method is preferably characterized by the following step: stopping after the opening movement by constantly reducing the instantaneous drive speed from the final drive speed to a standstill.

• Anhalten anschließend an das Schließfahren durch stetiges Erniedrigen der Momentan-Antriebsgeschwindigkeit von der Endfahrantriebsgeschwindigkeit bis zum Stillstand.

The method is preferably characterized by the step:

• Stopping after the closing run by continuously reducing the instantaneous drive speed from the final drive speed to a standstill.

It is preferable that the stopping subsequent to the fast running is performed by steadily decreasing the current driving speed from the maximum driving speed to a standstill.

It is preferable that the opening driving is performed by gradually decreasing the current driving speed from the final starting driving speed to a final starting driving speed.

In the case of a roller shutter, the closing movement takes place by constantly increasing the instantaneous drive speed from the final drive speed to a final drive speed.

It is preferable that the opening driving is performed by gradually increasing the current driving speed from the final starting driving speed to a final starting driving speed.

In the case of a sectional door, the closing movement takes place by constantly reducing the instantaneous drive speed from the final drive speed to a final drive speed.

It is preferred that the increase takes place with a characteristic adapted to the movement characteristics of the overhead gate.

It is preferred that the increase takes place with a polynomial, in particular linear, characteristic.

It is preferable for the increase to be monotonous, in particular strictly monotonous.

It is preferred that the lowering takes place with a characteristic adapted to the movement characteristics of the overhead gate.

It is preferred that the decrementing takes place with a polynomial, in particular linear, characteristic.

It is preferred that the decrease occurs monotonically, in particular strictly monotonically.

It is preferred that the door leaf has a main closing edge and the control device is designed to control the drive device in such a way that a Current main closing edge speed of the main closing edge increases steadily during the start.

It is preferred that the control device is designed to control the drive device in such a way that an instantaneous main closing edge speed of the main closing edge remains essentially constant or steadily increases during the opening movement.

It is preferred that the door leaf has a main closing edge and the control device is designed to control the drive device in such a way that an instantaneous main closing edge speed of the main closing edge steadily decreases to a standstill during the stop.

Preferred configurations can have the advantages discussed below, among others. It should be noted that not all advantages need be realized in a single embodiment or all embodiments.

The configurations described enable faster door opening and closing and can at the same time comply with the maximum operating forces or maximum door leaf speeds. This can not only the comfort to be increased; energy savings can also be achieved, for example by reducing heat losses. At the same time, impairment of the operational safety of the overhead door can be avoided. Overall, a uniform door leaf speed can result during operation, which can also protect the material. Furthermore, the control device can be designed in such a way that various door parameters of the overhead door, such as the type of fitting, the door height or the door type, can be programmed. This can be done manually or by the measures mentioned at the outset. Different types of gearing, such as direct drive, sprocket transmission, winding shaft diameter and the like, could also be programmed into the control device. The door parameters can also be determined automatically by means of a learn run. The control device can then use a movement characteristic determination module to detect the movement characteristic of the overhead gate and, based on this, control the drive device as desired. For example, force sensors, rotary encoders or the power consumed by the drive device, specifically the drive motor, can be used to determine the movement characteristics.

Fig. 1 bis Fig. 4

ein Ausführungsbeispiel eines Sectionaltores beim Öffnungsfahren des Torblatts;

Fig. 5

ein Diagramm der Momentan-Antriebsgeschwindigkeit über der Torblattposition und ein Diagramm der Momentan-Hauptschließkantengeschwindigkeit über der Torposition;

Fig. 6

ein Diagramm der Momentan-Antriebsgeschwindigkeit über der Torblattposition und ein Diagramm der Momentan-Hauptschließkantengeschwindigkeit über der Torposition;

Fig. 7

ein Diagramm der Momentan-Antriebsgeschwindigkeit über der Torblattposition und ein Diagramm der Momentan-Hauptschließkantengeschwindigkeit über der Torposition;

Fig. 8 bis Fig. 11

ein Ausführungsbeispiel eines Rolltores beim Öffnungsfahren des Torblatts;

Fig. 12

ein Diagramm der Momentan-Antriebsgeschwindigkeit über der Torblattposition und ein Diagramm der Momentan-Hauptschließkantengeschwindigkeit über der Torposition;

Fig. 13

ein Diagramm der Momentan-Antriebsgeschwindigkeit über der Torblattposition und ein Diagramm der Momentan-Hauptschließkantengeschwindigkeit über der Torposition; und

Fig. 14

ein Diagramm der Momentan-Antriebsgeschwindigkeit über der Torblattposition und ein Diagramm der Momentan-Hauptschließkantengeschwindigkeit über der Torposition, gemäß einem erfindungsgemäßen Ausführungsbeispiel.

Exemplary embodiments of the invention are explained in more detail below with reference to the accompanying schematic drawings. It shows:

Figures 1 to 4

an embodiment of a sectional door when opening the door leaf;

figure 5

a diagram of the instantaneous drive speed over the door leaf position and a diagram of the instantaneous main closing edge speed over the door position;

6

a diagram of the instantaneous drive speed over the door leaf position and a diagram of the instantaneous main closing edge speed over the door position;

7

a diagram of the instantaneous drive speed over the door leaf position and a diagram of the instantaneous main closing edge speed over the door position;

Figures 8 to 11

an embodiment of a roller door when the door leaf is opening;

12

a diagram of the instantaneous drive speed over the door leaf position and a diagram of the instantaneous main closing edge speed over the door position;

13

a diagram of the instantaneous drive speed over the door leaf position and a diagram of the instantaneous main closing edge speed over the door position; and

14

a diagram of the instantaneous drive speed over the door leaf position and a diagram of the instantaneous main closing edge speed over the door position, according to an embodiment of the invention.

It will be on first Figures 1 to 4 Reference is made, which schematically shows an opening movement (see arrow) of an overhead door 10. FIG. The overhead door 10 is shown as an example in four positions I to IV.

The overhead door 10 is designed as a sectional door 12, for example. The sectional door 12 comprises a door leaf 14. The door leaf 14 has a main closing edge 16 at its lowermost end area. The door leaf 14 preferably comprises two, three, four, five, six or more door leaf panels 18.

The overhead door 10 also includes a door shaft 20. A winding drum 22 can be arranged at the opposite ends of the door shaft 20 in each case. The winding drum 22 is designed as a conical winding drum 24, for example. A traction means 26 can be wound onto the winding drum 22 . The traction means 26 is attached at one end to the winding drum 22 and extends, for example, through the door leaf panels 18 to the main closing edge 16. The traction means 26 is attached to the door leaf panel 18, which has the main closing edge 16. A cable, in particular a steel cable 28 , is preferably used as the traction means 26 .

The overhead door 10 also has a door drive device 30 . The door drive device 30 is designed to drive the door shaft 20 . The door drive device 30 has a drive device 32 with a drive motor 34 . The drive motor 34 is preferably designed as an electric motor 36 which can include a motor gear 38 . Such a drive motor 34 is also referred to as an electric geared motor 40 . The drive device 32 is connected to the door shaft 20 so that the overhead door 10 can be opened and closed.

The door drive device 30 also includes a control device 42. The control device 42 is operatively connected to the drive device 32 in such a way that the door shaft 20 can be driven by the drive device 32 at an instantaneous drive speed V _A . The control device 42 is implemented by a microcontroller, for example. Alternatively, the control device 42 can also be formed from discrete components.

By driving the door shaft 20 at the instantaneous drive speed V _A , the movement of the drive device 32 is transmitted to the door leaf 14 via the winding drum 22 and the traction mechanism 26 . As a result, the main closing edge 16 is moved at an instantaneous main closing edge speed V _HS . It it should be noted that the dependence of the instantaneous main closing edge speed V _HS on the instantaneous drive speed V _A is determined by the transfer of motion from the gate shaft 20 to the main closing edge 16 .

It will be referred to below Figures 1 to 5 Reference is made, on the basis of which an opening process of the door leaf 14 is explained by way of example.

figure 5 shows qualitatively in the upper half the characteristic curve of the instantaneous drive speed V _A compared to the instantaneous position of the door leaf 14, more precisely the position of the main closing edge 16. In the lower half shows figure 5 qualitatively the characteristic curve of the instantaneous main closing edge speed V _HS in relation to the position of the door leaf 14, more precisely the position of the main closing edge 16.

First, the door leaf 14 is in the closed state (position I). To start up the door leaf 14 from a standstill, the drive device 32 is controlled by the control device 42 in such a way that the instantaneous drive speed V _A is brought from V _A =0 to a final start-up drive speed V _EA . The transmission of the movement of the door shaft 20 to the door leaf 14 also increases the instantaneous main closing edge speed V _HS until a main closing edge final approach speed V _HSEA is reached. The main closing edge final approach speed V _HSEA is selected so that it is always below a maximum main closing edge speed V _HSMAX at which the permissible maximum operating forces and/or speeds are just still maintained.

Following the start-up, the door leaf 14 is opened. For this purpose, the instantaneous drive speed V _A is controlled according to the kinematics of the overhead door 10, ie according to the transmission of the movement from the drive device 32 to the main closing edge 16. In the present example, a constant instantaneous Drive speed V _A due to the design of the winding drum 22 lead, for example, to as the movement of the door leaf 14 progresses, the instantaneous main closing edge speed V _HS would decrease.

However, the controller 42 controls the drive device 32 such that the instantaneous drive speed V _A increases from the final drive speed V _EA to a final drive speed V _E according to the characteristics of the winding drum 22 . In the case of a conical winding drum 24, this can be achieved, for example, by a strictly monotonous and linear increase in the instantaneous drive speed V _A . Due to the constant, strictly monotonous and linear increase in the instantaneous drive speed V _A , the instantaneous main closing edge speed V _HS can be kept approximately constant. The main closing edge 16 thus moves close to, but below, the forbidden area VB defined by the maximum main closing edge speed V _HS-MAX during the opening movement.

When opening, due to the reduced risk of accidents, it is also conceivable that the instantaneous main closing edge speed V _HS increases slightly and briefly enters the forbidden area VB. When the instantaneous drive speed V _A reaches the final drive speed V _E , the opening drive is ended. To stop the door leaf 14, the instantaneous drive speed V _A is reduced comparatively quickly from the final drive speed V _E to standstill V _A =0. The overhead door 10 has then reached the open position (position IV).

How out figure 5 recognizable, the instantaneous main closing edge speed V _HS decreases from a main closing edge final speed V _HSE to 0 when stopping. The main closing edge final speed V _HSE can deviate slightly from the main closing edge final approach speed V _HSEA .

Thus, the open position of the overhead gate 10 (position IV) is reached.

This control enables the overhead door 10 to open as quickly as possible without exceeding allowable operating forces or operating speeds. As a result of the speedy opening, a reduction in the energy requirement of the overhead door 10 can be achieved overall.

In order to close the overhead door 10, the steps of the opening movement are carried out essentially in reverse order in an exemplary embodiment which is not according to the invention. In contrast to the opening movement, however, when closing, it is important to ensure that the current main closing edge speed V _HS is always below the maximum main closing edge speed V _HSMAX and is therefore outside the prohibited range VB, as otherwise the door leaf 14 could cause serious injuries or damage to property . Consequently, an overall shortest time can be achieved in which the overhead door 10 is open, so that in particular air-conditioned premises, such as cold stores, ice rinks, greenhouses and the like, suffer minimal cold or heat loss and thus further energy can be saved.

It will be referred to below Figures 1 to 4 and 6 and 7 referenced.

6 shows the instantaneous drive speed V _A over the position of the door leaf 14 in the upper half. In the lower half of FIG 6 the instantaneous main closing edge speed V _HS is shown over the position of the door leaf 14 . An opening run of the overhead gate 10 will be described below. It should be noted that for a closing operation, the process is essentially reversed.

Initially, the door leaf 14 is in the closed position (position I). For opening, the drive device 32 is activated by the control device 42 in such a way that the instantaneous drive speed V _A is increased from standstill V _A =0 to the final start-up drive speed V _EA . By transmitting the movement from the drive device 32 via the gate shaft 20, the winding drum 22 and the traction mechanism 26 on the door leaf 14, the main closing edge 16 is also accelerated from a standstill to a main closing edge final approach speed V _HSEA (region I). The start-up is complete when the drive device 32 has reached the final start-up drive speed V _EA .

The door leaf 14 is then opened in a manner similar to that described above, and the instantaneous drive speed V _A is steadily increased to the final drive speed V _E (region II). As a result, the main closing edge 16 moves at an almost constant instantaneous main closing edge speed V _HS close to but just below the maximum main closing edge speed V _HSMAX , at which the maximum permissible operating forces and operating speeds are just maintained (area II).

If the door leaf 14, more precisely the main closing edge 16, has reached a position of about 2.5 m to 3.0 m above the ground ( 3 , Position III), the controller 42 increases the instantaneous drive speed V _A from the final drive speed V _E to a maximum drive speed V _H (range III). As in 6 indicated in the diagram, the main closing edge 16 accelerates to an instantaneous main closing edge speed V _HS which is above the permitted maximum main closing edge speed V _HSMAX . The main closing edge speed V _HS thus reaches a main closing edge maximum speed V _HSH which lies within the forbidden range VB. This is possible because at a height above 2.5 m, a collision of the main closing edge 16 with an obstacle is generally not to be assumed, particularly not when opening.

After the instantaneous drive speed V _A has reached the maximum drive speed V _H , the instantaneous drive speed V _A is again reduced to a standstill V _A =0 (region IV). Consequently, the instantaneous main closing edge speed V _HS also decreases until it comes to a standstill. The overhead gate 10 is now in the open state (position IV). It should be noted that for a closing operation, the process is essentially reversed.

In a variation that 7 is shown, the rapid travel (area III) of the door leaf 14 can also be designed in such a way that the current drive speed V _A is quickly increased to the maximum drive speed V _H and is maintained for a range of high-speed travel before the current drive speed V _A again is lowered to a standstill. As in the diagram in 7 , Lower half, recognizable, due to the kinematics of the overhead door 10, the current main closing edge speed V _HS increases to the main closing edge maximum speed V _HSH despite the constant current drive speed V _A =V _H (area III). The main closing edge 16 then comes to a standstill again as a result of the stopping (area IV). The overhead door 10 is now open (position IV).

It will be referred to below Figures 8 to 12 Reference is made to FIG. 10 which shows an embodiment of an overhead door 110. FIG. In this example, the overhead door 110 is designed as a roller door 112 .

The roller door 112 includes a door leaf 114 with a main closing edge 116. The door leaf 114 is composed of a plurality of hollow profile bars 118 which are connected to one another in an articulated manner. Other configurations are also conceivable, for example as solid roller shutter curtain rods or as hollow profile rods filled with thermal insulation material. The main closing edge 116 is provided on the bottom hollow profile bar 118 .

The overhead door 110 also includes a door shaft 120 which is designed as a winding shaft 122 . When the overhead door 110 is opened, the door leaf 114 acting as a roller shutter curtain is wound up on the door shaft 120 to form a roll 124 . The winding bale thickness d consequently increases as the opening of the overhead gate 110 increases.

A gate drive mechanism 130 is provided for opening the overhead gate 110 . The door drive device 130 includes a drive device 132 for driving the door shaft 120. The drive device 132 has a drive motor 134 for this purpose. The drive motor 134 is preferably an electric motor 136 with a motor gear 138. Together, the electric motor 136 and the motor gear 138 are also referred to as an electric geared motor 140. The drive device 132 is connected to the door shaft 120 . This can, for example, take place directly or via a further transmission, such as a chain drive 141 .

The door drive device 130 also has a control device 142 which is operatively connected to the drive device 132 in such a way that the control device 142 can control an instantaneous drive speed V _A at which the door shaft 120 is driven. The control device 142 can be embodied as a microcontroller, for example, or can also be formed from discrete components.

The functioning of the control device 142 is described below with reference to FIG Figures 8 to 12 explained in more detail.

Initially, the door leaf 114 is in the closed position (position I). To open, the control device 142 controls the drive device 132 in such a way that the instantaneous drive speed V _A is brought from V _A =0 to a final drive speed V _EA (range I). The drive device 132 transmits the movement to the door shaft 120, which in turn transmits this to the door leaf 114, so that the instantaneous main closing edge speed V _HS is accelerated from V _HS = 0 to a main closing edge final approach speed V _HSEA (region I). The launch is complete as soon as the instantaneous drive speed V _A has reached the final launch drive speed V _EA .

The winding up of the door leaf 114 into the wound roll 124 results in the roll thickness d increasing as the movement of the door leaf 114 progresses. If the instantaneous drive speed V _A remained the same, the instantaneous main closing edge speed would continue to increase. To counteract this, the control device 142 controls the drive device 132 in such a way that the instantaneous drive speed V _A is reduced from the final drive speed V _EA to a final drive speed V _E according to the movement characteristics of the overhead door 110 (region II). In particular, the instantaneous drive speed V _A is continuously, strictly monotonically and linearly reduced from the final drive speed V _E to the final drive speed V _E .

The movement is transmitted from the drive device 132 to the door leaf 114 via the door shaft 120 and the winding barrel 124 . As in the diagram below 12 to recognize, such a change in the instantaneous drive speed V _A means that the instantaneous main closing edge speed V _HS remains essentially constant (area II). The final drive speed V _EA and the final drive speed V _E are selected so that the current main closing edge speed V _HS is always below the permitted maximum main closing edge speed V _HSMAX , at which the maximum permissible operating forces and operating speeds are just kept. The opening drive is complete as soon as the instantaneous drive speed V _A has reached the final drive speed V _E .

The control device 142 then controls the drive device 132 in such a way that the instantaneous drive speed V _A is reduced from the final drive speed V _E to a standstill (region IV). Consequently, the instantaneous main closing edge speed V _HS also decreases from the main closing edge final driving speed V _HSE to standstill (area IV). The overhead door 110 is now in the open condition (position IV). It should be noted that for a closing operation of an embodiment not in accordance with the invention, the process is essentially reversed.

It will be referred to below Figures 8 to 11 and 13 referenced. In the upper half shows 13 shows the instantaneous drive speed V _A over the position of the door leaf 114. In the lower half 13 a diagram of the instantaneous main closing edge speed V _HS over the position of the door leaf 114.

The following is based on the 13 an opening movement of the overhead gate 110 is described.

The door leaf 114 is initially in the closed state (position I). For starting, the control device 142 controls the drive device 132 in such a way that the instantaneous drive speed V _A is brought from V _A =0 to a final start-up drive speed V _EA (range I). As previously described, this accelerates the main closing edge 116 from standstill to the main closing edge final approach speed V _HSEA (region I).

During the subsequent opening drive, the instantaneous drive speed V _A is reduced from the final drive speed V _EA to the final drive speed V _E in accordance with the characteristics of the overhead door 110 (area II).

For subsequent high-speed driving, the instantaneous drive speed V _A is left essentially constant or slightly increased from the final drive speed V _E (region III). Consequently, when driving fast, the instantaneous main closing edge speed V _HS increases and can also exceed the maximum main closing edge speed V _HSMAX . The instantaneous main closing edge speed V _HS thus reaches a main closing edge maximum speed V _HSH which is within the forbidden range VB (range III).

The movement of the door leaf 114 is then stopped again by reducing the instantaneous drive speed V _A to a standstill (range IV). Accordingly, the instantaneous main closing edge speed V _HS also decreases from the main closing edge maximum speed V _HSH to standstill (area IV).

It will be referred to below 14 Reference is made to describe an example of closing travel of the overhead door 110 according to the present invention.

The overhead door 110 is initially in the open condition (position IV). To start off, the control device 142 controls the drive device 132 in such a way that the instantaneous drive speed V _A is increased from V _A =0 to the maximum drive speed V _H (region IV). As a result, the instantaneous main closing edge speed V _HS increases from V _HS = 0 to the main closing edge maximum speed V _HSH (area IV). The main closing edge maximum speed V _HSH is above the permitted maximum main closing edge speed V _HSMAX , ie within the forbidden range VB.

After reaching the maximum drive speed V _H , the control device 142 controls the drive device 132 in such a way that the instantaneous drive speed V _A is reduced from the maximum drive speed V _H to the final starting drive speed V _EA (region III). Consequently, the instantaneous main closing edge speed V _HS also decreases from the main closing edge maximum speed V _HSH to the main closing edge final approach speed V _HSEA (region III). The main closing edge final approach speed V _HSEA is below the permitted maximum main closing edge speed V _HSMAX , ie outside the forbidden range VB. The transition from fast driving to normal closing driving is selected in such a way that a collision of the door leaf 114 with an obstacle during fast driving is unlikely. This is the case, for example, with a height of the main closing edge 116 of more than 2.5 m.

When closing, the instantaneous drive speed V _A is reduced from the final drive speed V _EA to the final drive speed V _E , so that the current main closing edge speed V _HS remains essentially constant or decreases slightly (region II).

During the subsequent stop, the instantaneous drive speed V _A is reduced from the final drive speed V _E to a standstill (region I). Consequently, the instantaneous main closing edge speed V _HS also decreases from the main closing edge final driving speed V _HSE to a standstill (range I). The overhead door 110 is now in the closed condition (position I).

In the case of sectional doors with conical cable drums (vertical fittings and fittings with higher guidance), a constant door leaf speed is not possible if the speed of the shaft drive is constant. The door leaf speed decreases due to the conical part when opening the door. There is a similar problem with roller shutters. Here, however, the speed of the gate leaf decreases when the gate closes due to the smaller bale diameter. Frequency-controlled drives enable soft start and soft stop ramps and usually an additional freely programmable point at which the speed can be increased or reduced. This point (beginning of ramp travel) is usually programmed when the door opens about 3 m above OFF, because the normatively permissible operating forces must be observed from 2.5 m above OFF. Today's drives do not allow the continuous and stepless control of the door leaf speed depending on the current cable drum diameter (conical part) for sectional doors or the winding shaft/barrel diameter for roller doors.

Input or programming of the fitting type, if necessary the door height (if not automatically determined during the learn run) and a chain wheel transmission when using chain boxes in connection with sectional doors. input or programming the door type (winding shaft diameter and door curtain), if necessary the door height (if not automatically determined during the learn run) and a chain wheel transmission for roller doors.

In the case of sectional doors, this allows the door to open and close more quickly, resulting in increased comfort and energy savings (reduction in cold or heat losses) without meeting the normative requirements with regard to the maximum operating forces and/or the maximum door leaf speeds in the direction of the door (max 500 mm/sec. without apron protection).

This leads to the same advantages with roller shutters, since with this solution the drive does not have to turn constantly slowly from 2.5 m above OFF, but can continue to accelerate up to a soft stop in order to keep the door leaf speed constant.

Reference list:

10

overhead gate

12

sectional door

14

gate leaf

16

main closing edge

18

door leaf panel

20

gate wave

22

winding drum

24

conical winding drum

26

traction means

28

steel cable

30

gate drive device

32

drive device

34

drive motor

36

electric motor

38

Engine / gear

40

electric gear motor

42

control device

110

overhead gate

112

rolling gate

114

gate leaf

116

main closing edge

118

hollow section bar

120

gate wave

122

winding shaft

124

wrap bale

130

gate drive device

132

drive device

134

drive motor

136

electric motor

138

Engine / gear

140

electric gear motor

141

chain drive

142

control device

i.e

bale thickness

v.a

instantaneous drive speed

VEA

Final Drive Speed

PU

final drive speed

VH

maximum drive speed

vhs

Current main closing edge speed

VHSEA

Main closing edge final approach speed

VHSE

Main closing edge speed

VHSH

Main closing edge maximum speed

VHSMAX

Maximum main closing edge speed

Claims (5)

1. Sectional door (12) or roller door (112), having a door leaf (14, 114) which can be moved between an open position and a closed position and has a main closing edge (16), a door shaft (20, 120) which is operatively connected for moving the door leaf (14, 114) between the open position and the closed position, and a door drive device (30) which is designed to drive the door shaft (20, 120), the door drive device (30) comprising:

   drive device (32, 132) adapted to drive the door shaft (20, 120) at an instantaneous driving speed (V_A) and connected to the door shaft (20, 120), the drive device (32, 132) comprising a drive motor (34, 134); and

   control device (42, 142) adapted to control the drive device (32, 132) such that during a start-up, the instantaneous driving speed (V_A) is brought to a final start-up driving speed (V_EA),

   wherein the control device (42, 142) is further designed to control the drive device (32, 132) in such a way that, during a closing travel following the start-up, the instantaneous driving speed (V_A) is continuously increased or continuously decreased from the final start-up driving speed (V_EA) to a final travel driving speed (V_E) as a function of the design of the door (12, 112), so that, in the case of a sectional door (12), during the closing travel which follows the start-up, the instantaneous driving speed (V_A) is continuously reduced from the final start-up driving speed (V_EA) to a final travel driving speed (V_E), and, in the case of a roller door (112), during the closing travel which follows the start-up, the instantaneous driving speed (V_A) is continuously increased from the final start-up driving speed (V_EA) to the final travel driving speed (V_E), wherein the instantaneous main closing edge speed (V_H) remains substantially constant or steadily decreases during the closing travel of the roller door (112), characterized in that

   the control device (42) is further designed to control the drive device (32) in such a way that, during the start-up preceding the closing travel, the instantaneous driving speed (V_A) is increased up to a drive maximum speed (V_H) so that the main closing edge (16) is accelerated to a main closing edge maximum speed (V_HSH) lying within a range (VB) prohibited by the normative requirements with respect to the maximum operating forces and/or the maximum door leaf speed, as long as the main closing edge (16) is in a position above 2.5 m, the instantaneous driving speed (V_A) then being continuously reduced to the final start-up driving speed (V_EA).
2. Sectional door (12) or roller door (112) according to claim 1, characterized in that the control device (42, 142) is further designed to control the drive device (32, 132) in such a way that, during a stop following the opening travel and/or during a stop following the closing travel, the instantaneous driving speed (V_A) is steadily reduced from the final travel driving speed (V_E) to a standstill.
3. Sectional door (12) or roller door (112) according to claim 1 or 2, characterized in that the control device (42, 142) is further designed to control the drive device (32, 132) in such a way that, during a fast travel following the opening travel, the instantaneous driving speed (V_A) is continuously increased from the final travel driving speed (V_E) to the maximum driving speed (V_H).
4. Sectional door (12) or roller door (112) according to claim 3, characterized in that the control device (42, 142) is further designed to control the drive device (32, 132) in such a way that, during a stop following the fast travel, the instantaneous driving speed (V_A) is continuously reduced from the maximum driving speed (V_H) to a standstill.
5. Method of operating a sectional door (12) or a roller door (112) according to one of claims 1 to 4, comprising the steps:

   starting-up the door shaft (20, 120) by increasing the instantaneous driving speed (V_A) to a final start-up driving speed (V_EA) such that the main closing edge speed (V_HS) steadily increases; and

   closing travel of the door shaft (20, 120) by continuously increasing or by continuously decreasing the instantaneous driving speed (V_A) depending on the design of the door (12, 112) from the final start-up driving speed (V_EA) to a final driving speed (V_E), so that, in the case of a sectional door (12), during the closing travel following the start-up travel, the instantaneous main driving speed (V_A) is continuously reduced from the final start-up driving speed (V_EA) to the final travel driving speed (V_E), and, in the case of a roller door (112), during the closing travel following the start-up travel, the instantaneous main driving speed (V_A) is continuously increased from the final start-up driving speed (V_EA) to the final travel driving speed (V_E) in such a way that the instantaneous main closing edge speed (V_HS) remains substantially constant or decreases continuously during the closing travel,

   characterized in that the start-up preceding the closing travel is performed by continuously increasing the instantaneous driving speed (V_A) up to a maximum driving speed (V_H) so that the main closing edge (16) is accelerated to a maximum main closing edge speed (V_HSH) lying within a range (VB) prohibited by the normative requirements with respect to the maximum operating forces and/or the maximum door leaf speed, as long as the main closing edge (16) is in a position above 2.5 m, and then by continuously decreasing the instantaneous driving speed (V_A) to the final start-up driving speed (V_EA).

Images