• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    The invention relates to a method for operating a storage and retrieval unit (3), in which a rail track (1) / power supply rail (6) is placed under a hazardous operating voltage when a hazard formed by the stacker crane (3) is detected. In the storage and retrieval unit (3), the height of the voltage applied to the rail track (1) / power rail (6) voltage and a current path between the rail track (1) / power rail (6) and a drive motor (5, 5a..5c) of the storage and retrieval device (3) disconnected if the measured voltage is below a threshold associated with a hazardous event. Furthermore, a shelf operating device (3) and an automated rack storage system for performing the proposed method is specified.
    公开号:AT518556A4
    申请号:T50111/2017
    申请日:2017-02-10
    公开日:2017-11-15
    发明作者:
    申请人:Tgw Mechanics Gmbh;
    IPC主号:
    专利说明:

    The invention relates to a method for operating a mobile on a rail track storage and retrieval device in an automated storage system with at least one arranged along the rail track storage rack, the storage and retrieval device is supplied via a power line electrically connected to the rail track and / or a power rail with electrical energy and with the storage and retrieval unit general cargo is stored in the storage rack or outsourced from the storage rack. In normal operation, the rail route / power supply rail is set below a normal operating voltage, provided that no danger formed by the stacker crane is detected. In the case of danger, if a hazard formed by the storage and retrieval unit is determined, the rail track / power rail is, however, set below a hazardous operating voltage, which is below the normal operating voltage. Furthermore, the invention relates to a storage and retrieval unit with a plurality of rail wheels, a motor controller and at least one connected to the engine control drive motor. The motor controller is electrically connected to at least one rail wheel or a current collector, which is designed for electrical connection to the power supply rail. Finally, the invention also relates to an automated rack storage system with a rail track, at least one arranged along the rail track storage rack, and a mobile on the railway track storage and retrieval unit of the type mentioned above. In addition, the said automated rack storage system comprises an electrically connected to the rail track power supply and / or a Power supply rail, which is in contact with the storage and retrieval unit.
    Such an automated rack storage system or such a method are basically known from the prior art. For example, there is said rail track arranged in a rack aisle between two rows of shelves, so that the storage and retrieval unit can serve the storage bins left and right of the rail track, that store piece goods in the storage rack or outsource piece goods from this. Of course, several rows of shelves and rail routes can be arranged one above the other, so that a warehouse with multiple storage levels arises. A vertical conveyor connects the storage levels and transports the piece goods. The vertical conveyor connects to a conveyor system, by means of which the piece goods are transported to the vertical conveyor and piece goods are transported away from the vertical conveyor.
    Although such shelf storage systems are usually operated fully automatically via a central control computer, it is from time to time required that an operator enters a rack aisle, for example to perform maintenance on the storage and retrieval unit, on the rail track or on the storage rack itself, or even to piece goods, which have become wedged during manipulation by the stacker crane. Since the stacker cranes reach high speeds and also have a relatively high mass, special security measures must be taken to protect the operator when entering the rack aisle or rail route before the stacker crane.
    WO 2016/033628 A1 discloses a method for the secure operation of an automated rack storage system with storage racks and a rack aisle extending between the storage racks and a storage and retrieval unit moving therein. The storage and retrieval unit has a control unit, a travel drive and a load-receiving device. If the access is registered by an operator in one of the storage areas at a switching device, is switched from an automatic mode to a safety mode. In safety operation, those storage and retrieval units which would move in a protected area are moved to a holding position. In this holds the respective shelf control unit and is placed in a safe for the operator idle state until the control unit receives a release signal again.
    From WO 2014/153584 A1 a method is further known in which the rail track / power supply rail is set below a hazardous operating voltage whose rectification value / RMS value below a necessary for moving the stacker crane minimum rectifier / minimum effective value, but above zero, if one by the Storage and retrieval unit formed hazard is detected.
    A disadvantage of this method is that the danger operating voltage must be comparatively accurately dimensioned in order to avoid an undesired movement of the storage and retrieval unit. Inevitable tolerances in the production of stacker cranes, different types of storage and retrieval equipment and ultimately also partially difficult to predict operating conditions and, for example, voltage fluctuations cause a movement of the stacker crane can not be ruled out with the utmost security. This applies in particular to starting situations in which the storage and retrieval unit - possibly loaded with a heavy load - is in motion and, due to the inertia and a relatively high hazard operating voltage, moves on unexpectedly far.
    An object of the invention is therefore to provide an improved method for operating a storage and retrieval unit, an improved storage and retrieval unit and an improved automated storage system with a storage and retrieval unit. In particular, a driving movement of the storage and retrieval device is effectively prevented in the event of danger, a minimum energy supply of the same, however, be ensured.
    The object of the invention is achieved by a method of the aforementioned type in which a height of a voltage applied to the rail track / power supply rail is measured in the stacker crane and in the stacker crane a current path between the rail track / power supply rail and at least one drive motor of the storage and retrieval unit is disconnected when the measured voltage drops below a threshold associated with the hazard.
    This means that the voltage applied to the rail track / power rail only to a drive motor of the storage and retrieval device (eg drive motor for the travel movement of the storage and retrieval device along the rail line (x-direction) and / or drive motor for the adjusting movement of the load receiving device transversely to the rail track (z-). Direction)) when the measured voltage is less than the said threshold value. In particular, the threshold is below the normal operating voltage, but is greater than or equal to the hazardous operating voltage.
    Furthermore, the object of the invention with a storage and retrieval device of the type mentioned above, which additionally comprises a detection device which is adapted to measure a height of the voltage applied to the at least one rail / the current collector and a current path between the rail / the current collector and a drive motor of the storage and retrieval unit to disconnect, when the measured voltage is less than the threshold, which is associated with a hazardous event.
    Finally, the invention is also achieved by an automated rack storage system, which has a stacker crane (or more stacker cranes) of the type mentioned above, and a driving control, which is set up to detect an endangerment formed by the stacker crane (or the stacker cranes) and the rail line / In normal operation, the power supply rail should be set below a normal operating voltage in the absence of danger and below the hazardous operating voltage in the event of danger.
    The proposed measures make it possible to supply the storage and retrieval unit (also called a "shuttle" in the case of a single-level rack operating device) in the event of danger, for example to keep important electronic components without a backup capacitor or backup battery in operation. For example, this may relate to a communication module or a Positionge or other sensors of the storage and retrieval unit, so that the normal operation after a dangerous operation can be easily resumed. It is also advantageous that an error analysis and troubleshooting on the supplied stacker crane is facilitated. For example, error codes can be displayed on the storage and retrieval unit and, for example, the setting of sensors is facilitated by the maintained power supply.
    Although the storage and retrieval unit is also supplied with energy in the event of danger, the measures taken ensure effective protection of a person in the range of movement of the storage and retrieval unit. The dimensioning of the danger operating voltage is relatively uncritical, since in any case a safe operating state is achieved by interrupting the current path to a drive motor or more drive motors of the storage and retrieval unit, even in unexpected and unforeseen situations. Tolerances in the stacker cranes are not critical, and the proposed procedure is also suitable for different types of stacker cranes. In order for the current path to be safely disconnected when the danger operating voltage is present, the threshold value can be, in particular, below the normal operating voltage and greater than or equal to the danger operating voltage.
    A "danger case" is generally present when a hazard formed by the storage and retrieval unit has been determined. A hazard can be of a different nature, but in particular there is a risk if a person enters or has reached the effective range or range of motion of the storage and retrieval unit. For example, a successful entry of a person into the effective range and / or range of movement of the storage and retrieval device with a sensor, in particular an optical sensor, for example a light barrier, can be detected, which is arranged in the area of an access to the effective range / range of motion of the storage and retrieval unit or also in the effective range / range of motion is. Analogously, it would be conceivable that the access area is secured with a door which is equipped with a switching contact. With the help of this switch contact can also be determined access of a person in the effective range / range of motion of the storage and retrieval device. In addition, an entry request of a
    Person are detected in the effective range / range of motion of the storage and retrieval unit at a arranged in the immediate vicinity of the effective range / range of motion switching device, for example with the aid of a button that presses the person concerned. Although there is currently no danger to the person at this time, it is imminent. Even such imminent danger is considered within the scope of the invention as a hazard. In other words, the shelf storage system may include a device for detecting access of a person to the effective range or range of movement of the storage and retrieval device (eg, a sensor and / or a switch contact and / or a switching device, as described above), which is electrically connected to the travel control , The current path between the rail track / power supply rail and a drive motor of the storage and retrieval unit is thus separated in particular when the measured voltage drops below a threshold, which is associated with a hazardous situation of the type mentioned above.
    The "operating voltage" is generally the voltage applied by the power supply to the rail track / power rail and provided to the stacker crane. The "hazardous operating voltage" is that special case of the operating voltage that is applied to the rail track / power rail in case of danger. The "normal operating voltage" is the special case of the operating voltage that is applied to the rail track / power rail when there is no danger. The "minimum travel voltage" is that amount of operating voltage that is at least necessary for a movement of the shelf control unit and also refers to the moving storage and retrieval unit. This means that the storage and retrieval unit remains in any case when applying the minimum travel voltage, even out of motion. The "starting voltage" is the amount of operating voltage that is at least necessary for a movement of the storage and retrieval unit from standstill.
    The starting voltage is thus usually higher than the minimum driving voltage. In particular, the normal operating voltage is above a starting voltage of the storage and retrieval unit.
    In general, it is advantageous if the danger operating voltage is below a dangerous to humans touch voltage, as thus even bare parts of the automated rack storage system, which carry the danger operating voltage, pose no danger to humans.
    Basically, the height of the hazardous operating voltage due to the proposed measures may be such that it is sufficiently high for moving the storage and retrieval unit. In other words, the rectifier value / effective value of the hazardous operating voltage is then above a minimum rectifier value / minimum effective value necessary for moving the storage and retrieval unit. This is possible because the separation of the current path leads to the drive motor anyway to a safe operating condition. In this way, consumers can be supplied with electrical energy in case of emergency operation in the storage and retrieval unit, which require a relatively high voltage.
    Nevertheless, it is advantageous if the rectification value / effective value of the hazardous operating voltage is below a minimum rectification value / minimum effective value necessary for moving the storage and retrieval unit, but above zero. In this case, a travel movement of the storage and retrieval unit is excluded for physical reasons alone. In other words, too little energy is supplied to the drive or drive motor of the storage and retrieval unit, as this could move the storage and retrieval unit. Personal protection is therefore particularly effective. With this measure, a double security against undesired movement of the storage and retrieval device (eg a travel movement of the storage and retrieval device along the rail track (x-direction) and / or an adjusting movement of the load receiving device transversely to the rail line (z-direction) achieved because this even then stand still remains if the separation of the current path to the drive motor (eg drive motor for the travel movement of the storage and retrieval device along the rail track (x-direction) and / or drive motor for the actuating movement of the load-receiving device transverse to the rail track (z-direction) should fail for some reason.
    The maximum value of the hazard operating voltage is preferably below a minimum travel voltage required for moving the storage and retrieval unit. In this way, even greater safety can be achieved when operating the storage and retrieval unit.
    The "RMS value" is calculated by squaring and subsequent averaging, the "Rectification value" by rectification and subsequent averaging. For unipolar tensions, the "rectification value" therefore corresponds at the same time to the (arithmetic) "mean value".
    The storage and retrieval unit can be a drive motor for a travel movement of the storage and retrieval device along the rail line (x-direction) and a drive motor for the adjustment movement of a load-receiving device transverse to the rail line (z-direction). The load handling device can store a piece goods in the storage rack and outsource from the storage rack. The range of motion and effective range can be defined by the travel movement of the storage and retrieval device along the rail track and adjusting movement of the load receiving device transverse to the rail track.
    In the context of the invention, the term "driving" primarily refers to the movement of the entire storage and retrieval unit, that is to say to drive it on the rail track (x-direction). "Driving" but can also be applied to parts of the storage and retrieval unit, for example, the extension and retraction of a load-receiving device (z-direction). If the load-carrying device is mounted on a lifting frame, the term "driving" can also refer to a movement in the y-direction. Depending on the inertia of the moving unit and its drive power different minimum Gleichrichtwer te / minimum effective values come into play. It should also be noted that the drive motor is not necessarily electrical, but that the electrical energy can be previously converted into another form, for example pneumatic or hydraulic energy.
    Further advantageous embodiments and modifications of the invention will become apparent from the dependent claims and from the description in conjunction with the figures.
    It is advantageous if the separation of the current path takes place by switching off a relay, which is arranged in the current path to the drive motor. For example, the height of the voltage applied to the rail track / power rail can be measured by means of a comparator whose output is fed to the control coil of the relay. As a result, the relay can be turned off when the measured voltage is less than the threshold associated with the hazard.
    It is also advantageous if the separation of the current path by deactivating / switching off a driver takes place, which is the output side connected to a control input of a power side arranged in the current path transistor. Frequently, transistors are present in the current path to the drive motor or the drive motors, which are used for the control of the storage and retrieval unit. For example, the drive motors can be switched on and off and their speed and direction of rotation can be changed. Advantageously, these transistors are now used to shut down the storage and retrieval unit in case of danger, thereby deactivating / switching off the said driver, whereby the said transistors and thus the associated drive motors are turned off. For example, the height of the voltage applied to the rail track / power rail can be measured by means of a comparator whose output is fed to an input of said driver.
    It is also advantageous if the separation of the current path takes place by blocking an input signal supplied to a driver speed signal, the driver is the output side connected to a control input of a power side arranged in the current path transistor. In this variant, the speed signal that is generated during normal operation for the control of the drive motor or the drive motors, blocked when a danger occurs. In this way, the target speed "zero" is reported to the said driver, which shuts down the associated drive motor or the associated drive motors in a row. This can be done by deactivating / deactivating a controller which generates the speed signal. For example, the height of the voltage applied to the rail track / power rail can be measured by means of a comparator whose output is fed to an input of said regulator. However, the current path can also be separated by preventing the forwarding of the speed signal to the driver, for example by ANDing the speed signal to the output of a comparator, which measures the magnitude of the voltage applied to the rail track / power rail.
    It is also advantageous if, with the separation of the current path, a brake acting on rail wheels of the storage and retrieval device is actuated for applying a braking torque or holding torque. The brake can be integrated in particular in the current path of the drive motor and be designed as a self-holding brake. If an electrical supply is lost, braking is initiated automatically. Since the storage and retrieval unit is supplied in the event of danger but anyway with the hazardous operating voltage, the use of a self-ventilating brake is possible, which is actively operated in case of danger.
    In general, it is advantageous if the level of the normal operating voltage is around 60V and / or the level of the hazardous operating voltage around 24V and / or the voltage threshold between 30V and 45V and in particular around 32V. As a result, the voltage applied to the rail track / power supply rail is sufficiently high for both normal operation and hazardous operation without the hazard voltage representing a hazard to a person in the effective range (work area) and / or range of motion of the storage and retrieval device. By fixing the voltage threshold value to the above-mentioned values, the current path is safely disconnected when the hazardous operating voltage is present and safely closed when the normal operating voltage is present.
    It is also advantageous if the danger operating voltage in the same polarity as the normal operating voltage to the Schienenstre bridge / power rail is applied. In this way, special circuit measures in the storage and retrieval unit, such as the provision of a rectifier eliminated. The engine control can be kept simple.
    But it is also advantageous if the danger operating voltage is applied in a polarity opposite to the normal operating voltage polarity to the rail track / power rail. With appropriate wiring of the storage and retrieval unit, which prevents the forwarding of the oppositely polarized danger operating voltage to the drive motor, the danger operating voltage can be arbitrarily high in itself. For example, a diode can be switched into the current path to the drive motor, which is conductive for the normal operating voltage, but blocks at the opposite polarity polarity operating voltage. By the proposed measures components can be supplied in emergency operation, which require a relatively high voltage, in particular a voltage which is on average above the necessary for moving the storage and retrieval device minimum travel voltage. Optionally, in the storage and retrieval unit electrical energy storage (for example, accumulators or capacitors) may be provided to bridge the time necessary for the polarity reversal of the voltage. It is advantageous if the danger operating voltage essentially has only a direct component, that is to say essentially designed as a direct voltage. In this way, the driving control and the engine control can be kept very simple and robust. Failures and disruptions thereof can therefore be largely avoided. It is also favorable if the hazard operating voltage essentially has only one alternating component. In particular, when using a DC motor and a sufficiently high compared to the inertia of the storage and retrieval device frequency of the danger operating voltage can be prevented from starting the storage and retrieval unit without special circuit measures in the stacker crane. This is because the danger operating voltage in this case does not have a DC component on average which would be necessary for moving a DC motor. It is also advantageous if the hazard operating voltage has a DC component and a AC component. Again, the DC component of the hazard voltage can be kept so small that it is not sufficient for moving a DC motor, whereas the AC component can be relatively high. In this way, components can also be supplied in hazardous operation, which require a relatively high voltage. It is also favorable when the danger operating voltage control signals are superimposed. For example, this control signal may be formed by a sinusoidal AC voltage or may be formed as a digital signal. A sinusoidal alternating signal can be particularly easily coupled into the operating voltage or decoupled from this again. For example, in the storage and retrieval unit to a transformer or a filter may be provided. With the aid of a digital signal even complex control commands can be transmitted to the storage and retrieval system. In addition, it is largely insensitive to disturbances. For example, the frequency-flopping method or the spread-spectrum method can be used to transmit control commands with high data security. For example, with the control commands drive motors (or just a drive motor) of the storage and retrieval device can be turned off. Finally, it is also favorable in the above context if an alternating voltage component (for example the entire alternating component or a specific frequency component thereof) coupled out of the operating voltage is switched to the control coil of a relay located in the current path to a drive motor. Depending on whether the operating voltage applied to the storage and retrieval unit has an alternating component (in particular with a certain frequency), the relay can now be opened or closed and the drive motor can be controlled in this way. In particular, the alternating component can be coupled out via a transformer and / or a filter and, if appropriate, subsequently rectified.
    It should be noted at this point that the variants mentioned for the method of operation according to the invention and the resulting advantages relate equally to the presented stacker crane and the automated rack storage system presented, and vice versa.
    Furthermore, it is noted that the proposed measures for switching off the drive motor or the drive motors or to shut down the storage and retrieval unit can be used individually or in any combination, whereby the safety in case of danger is further increased.
    For a better understanding of the invention, this will be explained in more detail with reference to the following figures. Show it:
    Figure 1 is an exemplary and schematically illustrated automated rack storage system with a moving therein storage and retrieval device in plan view.
    2 shows an exemplary and schematically illustrated (stationary) drive control for lowering the operating voltage in the event of danger;
    3 is a schematic diagram of an exemplary (mobile) engine control;
    4 shows an exemplary and schematically illustrated drive control for reversing the operating voltage in case of danger;
    5 shows an exemplary and schematically illustrated motor control for operating the stacker crane with a reversed hazard operating voltage.
    6 shows an exemplary and schematically illustrated drive control for modulating an alternating signal to the operating voltage.
    7 shows an exemplary operating voltage with DC component and sinusoidal alternating component;
    FIG. 8 an exemplary operating voltage without DC component with sinusoidal alternating component modulated onto a sinusoidal fundamental wave; FIG.
    9 an exemplary operating voltage with DC component and modulated digital signal;
    10 shows an exemplary and schematically illustrated motor controller for decoding a modulated alternating signal and
    11 shows an exemplary and schematically illustrated motor control, in which a relay in the motor circuit is kept in a switching state by an alternating component in the operating voltage.
    By way of introduction, it should be noted that in the differently described embodiments, the same parts are provided with the same reference numerals or the same component names, the disclosures contained in the entire description can be mutatis mutandis to the same parts with the same reference numerals or component names. Also, the location information chosen in the description, such as top, bottom, side, etc. related to the immediately described and illustrated figure and to transmit mutatis mutandis to the new situation in a change in position. Furthermore, individual features or combinations of features from the illustrated and described different embodiments may represent for themselves, inventive or inventive solutions. It should also be noted that the specified voltage values may include a deviation of ± 10% from a reference value.
    1 shows an automated rack storage system with a rail track 1, at least one storage rack 2 arranged along the rail track 1 and a storage and retrieval device 3 that can be moved on the rail track 1. The automated rack storage system can also have several stacker cranes 3. The storage and retrieval unit 3 has rail wheels 4 and a drive motor 5. In addition, the exemplary storage and retrieval unit 3 comprises a support frame on which the rail wheels 4 are mounted and on which the drive motor 5 for the
    Travel drive is mounted, a load receiving device for storing piece goods in the storage rack 2 and for outsourcing piece goods from the storage rack 2, and a drive motor or multiple drive motors for the load-receiving device. The load-receiving device may for example be designed as a lifting fork and in particular also have conveyor belts or conveyor rollers for moving the piece goods. In addition, the exemplary storage and retrieval unit 3 has a control unit which is connected to a higher-level, central control (not shown) of the rack storage system.
    Furthermore, the automated rack storage system comprises a power supply rail 6 and a drive control 70 electrically connected thereto, which in turn is connected to a power supply / voltage source 8. In the example shown, the supply voltage via a sliding contact / pantograph 9 is removed from the power supply rail 6 and forwarded to a motor controller 100 which controls the drive motor 5 for the drive and, if a drive motor 5 is provided for the load receiving device, the drive motor 5 for the Load picking device controls. The engine control unit 100 can also take over further control tasks, such as the loading and unloading of piece goods (for example packing units (colli), containers, trays and the like) into or out of the storage rack 2. The engine controller 100 may be part of the control unit of the storage and retrieval unit 3, which is connected to a higher-level, central control of the rack storage system.
    In FIG. 1, the power supply rail 6 is arranged next to the rail track 1, of course the power supply rail 6 can also be arranged within the rail track 1. In addition, it is conceivable that the electrical energy is supplied to the storage and retrieval unit 3 directly via the rail track 1 or the rail wheels 4.
    The right end of the rack aisle is closed in this example with a door 11 whose closed state is monitored by a switch 12 connected to the drive control 70. Finally, the automated shelf storage system shown by way of example also includes a light barrier 13 and a push-button 14, which are connected to the drive control 70.
    The function of the automated rack storage system shown in FIG. 1 is now as follows:
    In normal operation, the storage and retrieval device 3 receives commands from a higher-level control, not shown, to pick up piece goods from a transfer point and store them in the storage rack 2 or outsource piece goods from this and deliver them to a transfer point. A transfer station can be provided at one end of the rail track 1 or be arranged between the ends of the rail track 1 in the storage rack 2. A vertical conveyor may also be provided in the area of the transfer station so that a plurality of rail sections 1 can be arranged one above the other and thus form a warehouse with several storage levels. According to this embodiment, storage and retrieval units 3 are provided in some of the storage levels or in each storage level. It is also conceivable that a horizontal conveying device (for example conveyor belts or conveying rollers) is arranged at the transfer station or at the vertical conveying device in order to supply or transport the piece goods accordingly. It is also conceivable that a picking workstation is arranged at the transfer point or at the vertical conveyor.
    In normal operation, the storage and retrieval unit 3 operates completely automatically. For this purpose, a normal operating voltage applied to the rail track 1 / power supply rail 6 in normal operation is forwarded via the motor control 100 of the stacker crane 3 to the drive motor 5 connected to the motor control 100 for the traction drive and / or to the drive motor 5 connected to the motor control 100 for the load handling device. or this drive motor or these drive motors 5 is controlled / regulated in a manner known per se by the motor controller 100.
    In certain situations, however, the intervention of an operator may be required, for example if piece goods are wedged, the storage and retrieval unit 3 is defective or the delivery flow is disturbed in some other way. Since the storage and retrieval unit 3 moves at a relatively high speed, the operator must be protected when she enters the rack aisle, respectively the railroad track 1. For this purpose, she presses the button 14, whereupon the stacker crane 3 is stopped in a controlled manner. In addition, the entrance to the rack aisle can also be monitored by the light barrier 13. As an additional protection is located at the right end of the aisle the door 11, which can be monitored with the switch 12. In this way, there is a protection zone 15. In addition, a protective fence can be arranged around the storage racks 2.
    If entering the rack aisle is detected by a person, be it from left or right, then the storage and retrieval unit 3 automatically, that is, without the button 14 must be pressed explicitly, shut down. In Fig. 1 both sides of the rack aisle are monitored. Of course, it is also possible to equip only one of the sides of the rack aisle with a light barrier 13 and / or a button 14 and / or a door 11 with switch 12. It is also conceivable that alternatively or additionally other security measures are taken, such as the operation of barriers or monitoring with other sensors, for example proximity sensors or video cameras.
    The driving control 70 sets the rail route 1 / power supply rail 6 now under a hazardous operating voltage, which is below the normal operating voltage when a threat formed by the stacker crane 3 is detected and thus a danger exists, that is, when the button 14 is pressed or the light barrier 13 or the switch 12 reports entering the rack aisle.
    In the stacker crane 3, the height at the rail track 1 / power supply rail 6 voltage applied (running) is measured, and it is in the stacker crane 3, a current path between the rail section 1 / power supply rail 6 and a drive motor 5 of the storage and retrieval device 3 separated when the measured voltage under a Threshold, which is assigned to the hazard. This means that the voltage applied to the rail section 1 / power supply rail 6 is forwarded to a drive motor 5 of the storage and retrieval unit 3 only if the measured voltage is less than the said threshold value. The disconnection of the current path leads directly to a stop of the stacker crane 3.
    Operation can be shortened by a brake which is actuated by a drop in the voltage applied to the rail track 1 / power supply rail 6 or by a separation of said current path. For example, a self-holding brake can be used, which automatically brakes when disconnecting a power supply.
    The proposed measures an electronic control system of the stacker crane 3 can still be powered electrically, although the stacker crane 3 is unable to move due to the separate current path.
    In general, the danger operating voltage can be so dimensioned that it is basically sufficiently high for moving the stacker crane 3. In other words, the rectification value / rms value of the hazardous operating voltage is above a minimum rectification value / minimum effective value necessary for moving the stacker crane 3. This is possible because the current path to drive the storage and retrieval unit 3 is disconnected.
    It is also conceivable, however, for the rectification value / effective value of the hazard operating voltage to be below a minimum rectification value / minimum effective value necessary for moving the storage and retrieval unit 3, but above zero. As a result of these measures, the safety for the operating personnel can be increased still further, since the storage and retrieval unit 3 also stops when the detection device which separates the current path, at least to a drive motor 5 of the stacker crane 3 in the event of danger, should fail. Due to the inertia of the storage and retrieval unit 3, it is generally sufficient if the rectification value / effective value of the hazardous operating voltage is below a necessary for moving the stacker crane 3 rectification / RMS value of the minimum travel voltage. For even greater safety, however, provision can also be made for the maximum value of the hazard operating voltage to be below the minimum driving voltage.
    FIG. 3 now shows an example of a motor control 101 arranged in the storage and retrieval unit 3, which supplies three drive motors here, namely a drive motor 5a for a travel movement in the x-direction, a drive motor 5b for a width adjustment of a load-receiving device and a drive motor 5c for input. and outsourcing of general cargo.
    The motor controller 101 comprises a plurality of half bridges Ba..Bc with transistors, a driver circuit D for the half bridges Ba..Bc, a microprocessor uP for controlling the stacker crane 3 and in particular for generating a speed signal PWMa.PWMc for the drive motors 5a..5c, a first comparator OP1 with upstream voltage dividers and a second comparator OP2 with upstream voltage dividers.
    A function of the engine controller 101 is now as follows:
    In normal operation, speed signals PWMa.PWMc for the drive motors 5a..5c are fed to the inputs of the driver circuit D, which are converted by the driver circuit D into corresponding control signals for the half bridges Ba..Bc connected on the output side. In normal operation, the measuring voltage fed to the first comparator OP1, which is derived from the voltage US applied to the power supply rail 6, is greater than the reference voltage derived from a supply voltage U1 of the motor control 101. The output of the comparator OP1 therefore assumes a low voltage potential, whereby the transistors connected on the output side are blocked and a high voltage potential is present at the inputs Ea..Ec of the driver circuit D or else at the input Ed of the microprocessor uP. This high voltage potential thus signals that the normal operating voltage is applied to the power supply rail 6. In the driver circuit D, the speed signals PWMa.PWMc and the inputs Ea..Ec are ANDed so that the speed signals PWMa.PWMc are forwarded to the internal circuits of the driver circuit D, which generates the signals for the half bridges Ba..Bc , Also, the microprocessor uP is signaled in this way that is applied to the power rail 6, the normal operating voltage.
    If now the danger operating voltage is applied to the power supply rail 6, the output of the first comparator OP1 assumes a high voltage potential, whereby the transistors connected on the output side are Runaway controls and at the inputs Ea..Ec the driver circuit D or at the input Ed of the microprocessor uP generate a low voltage potential. This low voltage potential thus signals that the danger operating voltage is applied to the power supply rail 6. In the driver circuit D, the speed signals PWMa.PWMc, which are AND-linked to the inputs Ea..Ec, thus no longer forwarded to the internal circuits of the driver circuit D, or is therefore passed to the internal circuits, the speed signal zero. The drive motors 5a..5c are therefore stopped.
    Additionally or alternatively, the low voltage signal at the input Ed in the microprocessor uP may cause no speed signal PWMa.PWMc or the speed signal PWMa.PWMc to be zero generated and passed to the driver circuit D. This also causes a stop of the drive motors 5a..5c.
    Another option for stopping the drive motors 5a..5c is to deactivate or switch off the driver circuit D as such. In the motor controller 101 this is effected by the second comparator OP2. In normal operation, the measuring voltage fed to the second comparator OP2, which is derived from the voltage US applied to the power supply rail 6, is greater than the reference voltage derived from a supply voltage U1. The output of the second comparator OP2 therefore assumes a low voltage potential, whereby the transistor connected on the output side is turned on and a high voltage potential is present at the input Ee of the driver circuit D or else at the input Ef of the microprocessor uP. This high voltage potential thus signals that the normal operating voltage is applied to the power supply rail 6.
    If now the danger operating voltage is applied to the power supply rail 6, the output of the second comparator OP2 assumes a high voltage potential, whereby the transistor connected on the output side blocks and generates a low voltage potential at the input Ee of the driver circuit D or also at the input Ef of the microprocessor uP. This low
    Voltage potential thus signals that at the power supply rail 6 is the danger operating voltage. The driver circuit D is thereby deactivated or switched off. In the microprocessor μP, too, this low voltage potential can cause no speed signal PWMa.PWMc or the speed signal PWMa.PWMc to be zero and sent to the driver circuit D.
    As a further option for stopping the drive motors 5a..5c, a measuring voltage is also fed to the microprocessor uP, which voltage is derived from the voltage US applied to the power supply rail 6. If the normal operating voltage is applied to the power supply rail 6, a high voltage signal is present at the input Eg of the microprocessor uP. If the danger operating voltage is applied to the power supply rail 6, a low voltage signal is present at the input Eg of the microprocessor uP. This voltage signal can also be used to generate the speed signal PWMa.PWMc or not or to produce the speed signal PWMa.PWMc zero.
    In FIG. 3, the speed signals PWMa.PWMc may be pulse width modulated signals. Of course, it is also conceivable to use other signals. In addition, the output signals of the comparators OP1, OP2 acting as detection device can also be subject to hysteresis, so that the output signal does not frequently change state at a voltage input value close to the voltage threshold, but remains stable. Another option would be an embodiment without width adjustment of a load-receiving device, so that only two drive motors 5a, 5c are provided. In the stacker crane 3, the height at the rail track 1 / power supply rail 6 applied voltage (running) measured, and it is in the storage and retrieval unit 3, a current path between the rail section 1 / power supply rail 6 and the drive motor 5a for the movement along the rail track 1 and the drive motor 5c for the adjusting movement of the load receiving device transversely to the rail track 1, separated, when the measured voltage is below a threshold, which is associated with the hazard.
    The proposed measures can be applied individually or in any combination. If several measures are applied together, the redundancy achieved can increase the safety of a person entering the rack aisle.
    FIG. 2 now shows a concrete example of a travel control 71, which comprises a voltage converter 16 and a changeover switch 17. The voltage converter 16 converts the voltage supplied by the power supply / voltage source 8 to a lower level, for example from 60V to 24V. With the aid of the changeover switch 17, the voltage supplied by the voltage source 8 can be switched directly to the power supply rail 6 (see illustrated state), or it is switched to the lower voltage level.
    The voltage level of the hazardous operating voltage can generally be chosen so that it is below the starting voltage and the stationary storage and retrieval unit 3 can not drive off, or it may even be below the minimum travel voltage, so that a moving storage and retrieval unit 3 stops. For example, the normal operating voltage may be less than or equal to 100V, in particular at 60V, at 48V or 24V, whereas the danger operating voltage may be less than or equal to 24V, for example 12V or 5V, which is usually sufficient for the supply of electronic components. Accordingly, the voltage threshold can be set in a range between 30V and 45V, more preferably 32V, 20V or 10V. It would also be conceivable that only important circuits are designed for operation by the danger operating voltage, other circuits including the drive motor 5, 5a..5c but shut down. For example, it can be provided that position encoders and communication modules as well as sensors continue to operate without restriction even when only the hazardous operating voltage is applied, so that a smooth resumption of normal operation after hazardous operation is ensured. Setting the voltage threshold to around 32V, 20V or 10V will add the current path
    Presence of the hazardous operating voltage is safely disconnected and safely closed when the normal operating voltage is present.
    In the example shown in FIG. 2, the hazard operating voltage has the same polarity as the normal operating voltage. It is also conceivable that the danger operating voltage is applied to the power supply rail 6 in a polarity opposite to the polarity of the normal operating voltage.
    4 shows an example of a travel control 72, in which the voltage supplied by the voltage source 8 can be switched directly to the power supply rail 6, but in different polarity, depending on the position of the changeover switch 17. In order to achieve the desired purpose, namely shut down the storage and retrieval unit 3, while still supplying important components with electrical voltage, the circuit shown in FIG. 3 can be provided in the storage and retrieval unit 3.
    FIG. 5 shows a section of an exemplary motor controller 102, in which the drive motor 5 is connected to the voltage source 8 via a diode 18. The diode 18 is also part of a full-wave bridge rectifier, which supplies the circuit 19. The circuit 19 may include important components such as a position sensor and communication devices, as well as the circuits shown in FIG. In normal operation (see the switching position of the changeover switch 17 shown in FIG. 4), the diode 18 is conductive and the drive motor 5 is supplied with power. The circuit 19 is powered by the rectifier with power. If the voltage is reversed on the power supply rail 6, so locks the diode 18, whereby the drive motor 5 is no longer supplied with power. Because of the rectifier, however, the circuit 19 is still supplied with electrical energy even when the voltage is reversed. Fig. 5 is intended to illustrate only the basic principle. Of course, behind the diode 18, a switch for the drive motor 5 may be arranged, with the aid of which the direction of rotation of the drive motor 5 can be reversed when the diode 18 is conductive. The proposed measure can be applied in addition to the measures disclosed in FIG. 3 in order to further increase the safety of a person entering the aisle alley.
    In the combination illustrated in Figures 4 and 5, the hazard operating voltage may be designed as a DC voltage (i.e., having substantially only a DC component) with the DC voltage applied to the power rail 6 at different poles, respectively.
    It would also be conceivable, however, that the normal operating voltage is a DC voltage and the danger operating voltage essentially has only one alternating component, that is to say an AC voltage. Also in this case, the circuit 19 would be supplied in both operating cases with electrical energy, whereas the drive motor 5 is supplied with electrical energy only at every second Flalbwelle the AC voltage. On average, the voltage therefore drops to a lower value. It would also be conceivable to connect the drive motor 5, which is assumed to be a direct voltage motor for the following consideration, directly to the voltage source 8, ie without the interposition of the diode 18. Because the danger operating voltage has substantially no DC component, the drive motor 5 remains at a sufficiently high frequency of the hazardous operating voltage due to its inertia simply stand, whereas the circuit 19 continues to be supplied with electrical energy.
    Finally, it would also be conceivable for an additional fuse to be installed in the travel control 72 in the current path active when the hazardous operating voltage is applied, which is designed for the current for supplying the stacker crane 3 in the event of danger, but not for the motor current of the drive motor 5. This can prevent that the stacker crane 3 is set in motion when the diode 18 breaks through and becomes conductive. If this case occurs, the mentioned fuse in the travel control 72 would trigger and prevent the storage and retrieval device 3 from moving.
    It would also be conceivable that the danger operating voltage is superimposed on a control signal. FIG. 6 shows an example of a travel control 73 in which a signal can be modulated onto the voltage of the voltage source 8 with the aid of a modulator 20 and a coupling transformer 21. For example, the modulator 20 may generate a sinusoidal signal which is modulated by means of the coupling transformer 21 to a DC voltage supplied by the voltage source 8. Fig. 7 shows an example of the resulting voltage. It would also be conceivable for the voltage source 8 to supply an alternating voltage to which an alternating voltage with a higher frequency is modulated. Fig. 8 shows an example of the resulting voltage. Furthermore, it would also be conceivable that the modulator 20 generates a digital code which is modulated onto a DC voltage supplied by the voltage source 8. Fig. 9 shows an example of the resulting voltage. Analogously to FIG. 7, it would also be conceivable for the digital signal to be modulated onto an AC voltage.
    The modulated sinusoidal signal has a constant frequency and a constant amplitude in the examples shown. Of course this is not necessarily the case. It would also be conceivable that the frequency and / or amplitude of the modulated sine signal is variable, that is, the sinusoidal signal is frequency and / or amplitude modulated. In addition, signals can generally be superimposed unipolar or bipolar, that is, starting from a base voltage have only one polarity or both.
    These components contained in the supply voltage for the stacker crane 3 can now be used to shut down the stacker crane 3 in case of danger. FIG. 10 shows a section of an exemplary motor controller 103 which comprises a decoder 22 and a switch 23 in the motor circuit which is driven by the decoder 22.
    In a first example, it is now assumed that the normal operating voltage contains the digital signal predefined in FIG. 9, but that the hazard operating voltage does not contain this first digital signal. That is, the travel controller 73 modulates the digital signal to the supply voltage only when there is no hazard. Accordingly, the decoder 22 keeps the switch 23 closed as long as it can determine the agreed digital signal in the supply voltage. If he can no longer detect this, there is a danger from the storage and retrieval unit 3 and the switch 23 is opened accordingly.
    It would also be conceivable that the danger operating voltage contains the predefined digital signal and does not contain the normal operating voltage of this digital signal. The danger operating voltage thus has a DC component and an AC component. In this case, the above-mentioned conditions are merely reversed, so that the switch 23 remains open as long as the decoder 22 can determine the agreed digital signal in the supply voltage.
    Finally, it would also be conceivable that the normal operating voltage contains a predefined first digital signal and the hazard operating voltage contains a predefined second, different digital signal. The switch 23 remains open in this case as long as the decoder 22 can determine the agreed second digital signal in the supply voltage. On the other hand, if the decoder 22 detects the first digital signal in the supply voltage, the switch 23 is closed.
    Of course, a digital signal does not necessarily have to be modulated for the safety method described above, but sinusoidal alternating signals can also be modulated (see FIGS. 7 and 8). These can be detected by means of a digital circuit, but can be provided as a decoder 22 but also an active or passive filter, or the decoder 22 may include such.
    In general, the alternating signal does not have to be continuously modulated or constantly monitored during normal operation or during hazardous operation. It is also conceivable that the modulating and monitoring is carried out only periodically.
    11 now shows an example of a motor control 104 in which an AC voltage component of the operating voltage is decoupled by means of an output coupler 24 in the stacker crane 3 and switched to the control coil of a relay 25 for disconnecting the operating voltage from the drive motor 5 via the rectifier 26. This is thereby kept in a switching state. For example, an alternating component contained in the normal operating voltage would result in a voltage being applied to the control coil of the relay 25 and keeping it connected. If the alternating component drops when switching over to the hazardous operating voltage, the relay 25 drops out and the drive motor 5 is disconnected from the operating voltage. The relay 25 is thus designed as a closer in this case. But it could also be reversed conditions and the AC component are modulated on the danger operating voltage, so that the relay 25 is formed as an opener.
    For example, the output coupler 24 could be designed as a transformer and thus the entire alternating component of the operating voltage is coupled out and fed via the optional rectifier 26 to the control coil of the relay 25. It would also be conceivable that the output coupler is designed as a filter and thus only a certain frequency component is coupled out of the operating voltage. This is particularly advantageous if both the normal operating voltage and the hazardous operating voltage have a change component. If the relay 25 is designed as a make contact, then the filter 24 is designed for the frequency of the alternating component contained in the normal operating voltage. On the other hand, if the relay 25 is designed as an opener, the filter 24 is designed for the frequency of the alternating component contained in the hazardous operating voltage. Of course, transformer and filter can also be combined.
    The embodiments show possible embodiments of driving controls 70..73 and motor controls 100..104, which should be noted at this point that the invention is not limited to the specifically illustrated embodiments thereof, but a possibility of variation due to the teaching of technical flanders by subject invention in the knowledge of the person working in this technical field.
    In particular, the illustrated variants can be combined as desired. For example, the engine controller 101 shown in FIG. 3 may be wholly or partially combined with one or more of the securing measures illustrated in FIGS. 2 and 4-11. Accordingly, a separation of the current path to a drive motor 5, 5a..5c of the shelf iengeräts 3 can be combined with the Aufmodulation of an alternating signal / digital signal on the Normalbetriebsspan voltage / hazard operation voltage. It would also be conceivable to additional Umpolung the hazard operating voltage relative to the normal operating voltage or a combination of the variant shown in FIG. 10 with the variant shown in FIG. 11. In this case, the decoder 22 could analyze the operating voltage for an included digital code, while the output coupler 24 merely decouples the alternating component from the operating voltage caused by the digital signal and thus keeps the relay 25 open or closed. In this way, the presence of a hazardous condition is detected in two different ways.
    By combining several security measures, the security for the operation of the storage and retrieval device 3 can be increased compared to a single measure. In particular, it is advantageous if the drive motor 5, 5a..5c is only supplied with the normal operating voltage if all or at least the majority of the units mentioned arrive at the same decision. It is particularly advantageous if the units are constructed differently or come from different Fierstellern.
    In general, it is advantageous if the threshold value for disconnecting the current path to the drive motor 5, 5a..5c, in particular the drive motor 5a for the travel movement along the rail track 1 or the drive motor 5b for the width adjustment of the load receiving device and the drive motor 5c for input and outsourcing of piece goods, is below the normal operating voltage, but greater than or equal to the hazardous operating voltage. As a result, the current path is reliably disconnected when the danger operating voltage is present and safely closed when the normal operating voltage is present. For the various proposed measures different or equal voltage thresholds can be provided for disconnecting the current path.
    To further increase the security can be provided that with the separation of the current path acting on rail wheels 4 of the stacker crane 3 brake is actuated. The brake can in particular be incorporated in the current path of the drive motor 5, 5a..5c and designed as a self-holding brake. If there is no electrical supply, the braking is then automatically initiated. Since the storage and retrieval unit 3 is in any case supplied with the hazardous operating voltage in case of danger, the use of a self-ventilating brake is possible.
    In general, the embodiments have been explained with reference to a DC motor. The invention is, however, fully applicable, of course, for AC motors and three-phase motors.
    At this point, it is also noted that the power supply rail 6 may comprise a plurality of mutually insulated conductors, in particular one each for the positive and negative potential respectively ground (DC) or one per phase and optionally for neutral (AC).
    Furthermore, the storage and retrieval unit 3 was shown movable in the examples in only horizontal direction. However, this is not mandatory. The storage and retrieval unit 3 can also move vertically, diagonally, as well as horizontally and vertically. The latter is formed for example by a horizontally movable lift with lifting fork.
    In addition, it is noted that the (mechanical) switches 17, 23 and 25 used in the figures for the sake of ease of understanding can equally be replaced by electronic switches. For example, in FIG. 10, instead of the switch 18, it is also possible to use transistors, in particular FETs or IGBTs.
    In particular, it is also noted that the illustrated controls and the automated rack storage system may in reality also comprise more or fewer components than shown and are sometimes shown greatly simplified in the figures.
    For the sake of the order, it should finally be pointed out that the illustrated travel controls 70..73, motor controls 100..104 and the automated rack storage system from FIG. 1 as well as their components are also partially scaled and / or enlarged and / or reduced for a better understanding of their construction were presented.
    The task underlying the independent inventive solutions can be taken from the description.
    LIST OF REFERENCES 1 Rail track 2 Storage rack 3 Storage and retrieval unit 4 Wheel 5, 5a..5c Drive motor 6 Power supply rail 70 .. 73 (stationary) drive control 8 Power source / power supply 9 Sliding contact 100 .. 104 (mobile) Motor control 11 Door 12 Switch 13 Light barrier 14 Push button 15 Protection zone 16 Voltage converter 17 Switch 18 Diode 19 Electronic circuit 20 Modulator 21 Transformer 22 Decoder / demodulator 23 Switch 24 Output coupler 25 Relay 26 Rectifier
    Ba..Bc half-bridge D driver circuit
    Ea..Eg input OP1 first comparator OP2 second comparator PWMa.PWMc speed signal t time U voltage U1 supply voltage motor control US voltage at power supply rail / rail track
    权利要求:
    Claims (14)
    [1]
    claims
    1. A method for operating a mobile on a rail track (1) storage and retrieval device (3) in an automated storage system with at least one along the rail track (1) arranged storage rack (2), wherein the storage and retrieval unit (3) via a with the rail track (1) electrically connected power supply (8) and / or a power supply rail (6) is supplied with electrical energy, stored with the storage and retrieval unit (3) piece goods in the storage rack (2) or from the storage rack (2), the rail track (1) / Power supply rail (6) is set in normal operation below a normal operating voltage, if no danger formed by the stacker crane (3) is detected, and the rail track (1) / power rail (6) is set in case of danger below a hazardous operating voltage, which is below the normal operating voltage, if a danger formed by the stacker crane (3) is detected, dadurc h characterized in that in the stacker crane (3) a height of the rail track (1) / power supply rail (6) voltage is measured and in the stacker crane (3) a current path between the rail track (1) / power supply rail (6) and a drive motor ( 5, 5a..5c) of the storage and retrieval unit (3) is disconnected when the measured voltage drops below a threshold, which is associated with the hazard.
    [2]
    2. The method according to claim 1, characterized in that the threshold value is below the normal operating voltage, but greater than or equal to the hazardous operating voltage.
    [3]
    3. The method according to claim 1 or 2, characterized in that the separation of the current path by switching off a relay (25) takes place, which is arranged in the current path.
    [4]
    4. The method according to any one of claims 1 to 3, characterized in that the separation of the current path by deactivating / switching off a driver (D), which is connected on the output side to a control input of a power side in the current path arranged transistor (Ba..Bc).
    [5]
    5. The method according to any one of claims 1 to 4, characterized in that the separation of the current path by blocking an input side to a driver (D) guided speed signal (PWMa.PWMc), wherein the driver (D) on the output side with a control input of a power side in the current path arranged transistor (Ba..Bc) is connected.
    [6]
    6. The method according to claim 5, characterized in that the separation of the current path by deactivating / switching off a controller (uP), which generates the rotational speed signal (PWMa.PWMc), or in that the forwarding of the rotational speed signal (PWMa.PWMc) to the driver (D) is prevented.
    [7]
    7. The method according to any one of claims 1 to 6, characterized in that with the separation of the current path on a rail wheels (4) of the stacker crane (3) acting brake is actuated. 8. The method according to claim 1, wherein the level of the normal operating voltage is approximately 60V and / or the level of the hazardous operating voltage is approximately 24V and / or the voltage threshold is between 30V and 45V.
    [9]
    9. The method according to any one of claims 1 to 8, characterized in that the danger operating voltage for moving the stacker crane (3) is sufficiently high.
    [10]
    10. The method according to any one of claims 1 to 8, characterized in that the rectification value / RMS value of the danger operating voltage below a for moving the storage and retrieval device (3) necessary minimum rectification value / minimum effective value, but above zero.
    [11]
    11. The method according to claim 10, characterized in that the maximum value of the danger operating voltage is in terms of amount under a for moving the storage and retrieval device (3) necessary minimum travel voltage.
    [12]
    12. The method according to any one of claims 1 to 11, characterized in that the danger operating voltage in the same polarity as the normal operating voltage to the rail track (1) / power supply rail (6) is applied or in a polarity opposite to the normal operating voltage polarity.
    [13]
    13. The method according to any one of claims 1 to 12, characterized in that the danger operating voltage substantially only has a DC component, substantially only has an AC component or a DC component and a AC component.
    [14]
    14. A storage and retrieval unit (3), comprising a plurality of rail wheels (4), a motor control (100..104), which is formed with at least one rail wheel (4) or a current collector (9), which for electrically connecting a power supply rail (6) is electrically connected, at least one to the motor controller (100..104) connected to the drive motor (5, 5a..5c), characterized by a detection device (OP1, OP2), which is adapted to a height of the at least one rail wheel ( 4) / to measure the current collector (9) voltage and to separate a current path between the rail wheel (4) / the current collector (9) and a drive motor (5, 5a..5c) of the storage and retrieval device (3), if the measured voltage is below a threshold associated with a hazard.
    [15]
    15. Automated rack storage system, comprising a rail track (1), at least one along the rail track (1) arranged storage rack (2), on the rail track (1) mobile storage and retrieval unit (3) according to claim 14, for the storage and retrieval of general cargo in and out of the storage rack (2) is formed, and with the rail track (1) electrically connected power supply (8) and / or a power supply rail (6) which is in contact with the storage and retrieval unit (3), characterized by a driving control (70..73), which is set up to detect an endangered by the stacker crane (3) and set the rail track (1) / power rail (6) in normal operation in the absence of risk below a normal operating voltage and in case of danger under hazardous operating voltage.
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    同族专利:
    公开号 | 公开日
    EP3580151A1|2019-12-18|
    AT518556B1|2017-11-15|
    US20200017303A1|2020-01-16|
    WO2018145138A1|2018-08-16|
    DE112018000753A5|2019-11-07|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    WO2014153584A1|2013-03-27|2014-10-02|Tgw Mechanics Gmbh|Arrangement and method for operating a storage and retrieval unit|
    JP2014201402A|2013-04-05|2014-10-27|西部電機株式会社|Stacker crane|
    WO2016033628A1|2014-09-05|2016-03-10|Tgw Mechanics Gmbh|Automated rack storage system and method for safely operating it|US11254503B2|2018-03-12|2022-02-22|Knapp Ag|Racking for storing articles in storage locations of racks|JP4905306B2|2007-09-20|2012-03-28|株式会社豊田自動織機|Operation control method and apparatus for stacker crane in automatic warehouse|
    KR20120083471A|2009-11-19|2012-07-25|가부시끼가이샤 오까무라세이사꾸쇼|Article conveyance device|
    AT516633A1|2014-12-18|2016-07-15|Tgw Logistics Group Gmbh|Bearing arrangement with improved energy balance between storage and retrieval units|AT519050A1|2016-09-13|2018-03-15|Tgw Mechanics Gmbh|Rail system for a conveyor vehicle and storage system|
    DE102019204797A1|2019-04-04|2020-10-08|Zf Friedrichshafen Ag|Method for triggering an emergency stop of a vehicle|
    CN112224029A|2020-10-15|2021-01-15|中车青岛四方车辆研究所有限公司|Redundancy control method for electromechanical brake system of rail vehicle|
    法律状态:
    优先权:
    申请号 | 申请日 | 专利标题
    ATA50111/2017A|AT518556B1|2017-02-10|2017-02-10|Automated shelf storage system, storage and retrieval unit and method for operating a storage and retrieval unit|ATA50111/2017A| AT518556B1|2017-02-10|2017-02-10|Automated shelf storage system, storage and retrieval unit and method for operating a storage and retrieval unit|
    EP18721257.6A| EP3580151A1|2017-02-10|2018-02-09|Automated rack storage system, storage-and-retrieval unit and method for operating a storage-and-retrieval unit|
    PCT/AT2018/060035| WO2018145138A1|2017-02-10|2018-02-09|Automated rack storage system, storage-and-retrieval unit and method for operating a storage-and-retrieval unit|
    US16/484,137| US20200017303A1|2017-02-10|2018-02-09|Automated rack storage system, storage-and-retrieval unit and method for operating a storage-and-retrieval unit|
    DE112018000753.7T| DE112018000753A5|2017-02-10|2018-02-09|Automated shelf storage system, storage and retrieval unit and method for operating a storage and retrieval unit|
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