DE102015017241B3 - Conveyor - Google Patents

Abstract

Conveying device (10) with at least one movable transport device (20), characterized in that - the conveying device (10) has an optical free-jet communication system (30) with two transmitting and receiving units (101, 102) each having a transmitter (110), a receiver (120) and a control unit (130) and one of which is fixed to the movable transport device (20) and the other to another section (11) of the conveyor (10), - wherein the two transmitting and receiving units ( 101, 102) in an optical free-jet connection (40) and allow a transmission of data packets, - wherein the control unit (130) at least one of the two transmitting and receiving units (101, 102), preferably the control unit (130) both transmit and Receiving units (101, 102), is configured such that it receives a received signal, in particular its data packets or at least one predetermined type of data packets to the Presence of a device identifier, which identifies the respective other transmitting and receiving unit (101, 102), checks and rejects the received signal, in particular the respective data packet, completely or in part, if in the received signal or the respective data packet none of the other transmitting The control unit (130) of at least one of the two transmitting and receiving units (101, 102) is designed in such a way that it inputs optical reception signals received via the optical free-jet connection (40) Receive clock signal generated, the times of rising and / or falling edge changes of the receive clock signal over a plurality of clock periods detected using the time points in the past estimates the time of each next edge change to form an estimated edge change time point and on the basis of the estimated Flankenwechselzei the control unit (130) of at least one of the two transmitting and receiving units (101, 102) is designed in such a way that it additionally the distance change value determines an absolute distance measured value indicating the distance between the transmitting and receiving units (101, 102), and wherein the control unit (130) of at least one of the two transmitting and receiving units (101, 102) is designed such that it adds the distance change value and the absolute distance measurement value, and continues to use the sum value as the actual distance measurement value.

Description

The invention relates to conveyors and methods for their operation.

The patent DE 600 16 933 T2 describes a position location system for determining the position of a mobile communication device, and more particularly, a system including two-way transmission of spread spectrum propagation signals between the mobile communication device and reference communication devices Relatively low accuracy clocks are used to quickly and accurately determine the position of the mobile communication device in the presence of severe multipath interference.

The patent DE 602 22 606 T2 relates to the improvement of position estimation systems having the ability to accurately determine the physical position of a target communication device using direct ranging techniques between search communication devices and the destination communication device.

The German utility model DE 20 2013 105 384 U1 discloses an opto-electronic device for optical data communication with a first sensor unit and a second sensor unit, each having a light emitter, a light receiver and an evaluation unit to exchange data along a bidirectional optical transmission path in the space between the sensor units by a sensor unit based on a communication protocol modulated on an emitted light signal and the other sensor unit receives the light signal and the data read out by demodulation based on the communication protocol from the light signal, wherein between the two sensor units an additional transmission channel is provided by the evaluation unit of a sensor unit is designed for the light signal with a modulate additional signal and the evaluation unit of the other sensor unit detects the additional signal.

Methods for checksum generation, clock recovery and localization using GPS can be found in the online library Wiki-pedia.

The German patent DE 693 31 361 T2 discloses communication systems, namely, those that operate for time division multiple access (TDMA) two-way communication.

The US patent US 4,425,647 A describes a remote control system for a television receiver. The remote control system includes a transmitter and a receiver, wherein the transmitter is adapted to transmit a single-word multi-bit code that identifies a selected function of the television receiver.

The German patent DE 44 35 056 B4 describes - in connection with a method and a device for storing goods - a conveyor having movable transport means in the form of so-called conveyors.

The invention has for its object to provide a conveyor that allows a particularly safe operation.

This object is achieved by a conveyor with the features of claim 1. Advantageous embodiments of the conveyor according to the invention are specified in subclaims.

A significant advantage of the conveyor according to the invention is the fact that in this a particularly secure and error-free transmission of data or information is possible because only data packets are used with the correct device identifier and others can be discarded. This is of particular importance if, for example, distance information is transmitted in the context of the data packets or distance information is obtained from or with the data packets, for example by clock edge evaluation, and an area between the movable transport device and the other section of the conveyor is to be released on the basis of this distance information, for example for other vehicles or passing persons. In other words, the evaluation of the device identifiers in connection with the transmission and / or acquisition of distance information according to the invention makes it possible to prevent accidents. But also in connection with the control of the conveyor as such, the safe and error-free transmission of data packets is advantageous.

It is regarded as advantageous if the control units of both transmitting and receiving units (or at least the control unit of one of the transmitting and receiving units) are designed such that they allow the spatial distance between the two transmitting and receiving units using a determination of the distance or this support information or more of such information received by the respective other transmitting and receiving unit, and the control units are also each configured such that they a received data packet having a distance detection enabling or supporting information on the presence of the device identifier that identifies the other transmitting and receiving unit, check and use the information contained in the respective data package for determining the spatial distance exclusively when in the respective data packet, the device identifier is included, and otherwise leave the received signal in the distance determination unconsidered.

Preferably, the control units of both transmitting and receiving units (or at least the control unit of one of the transmitting and receiving units) in each case a distance determination module which is designed such that it the spatial distance between the two transmitting and receiving units using one or more information information determined, which are received by the other transmitting and receiving unit.

In addition, the control units of both transmitting and receiving units (or at least the control unit of one of the transmitting and receiving units) preferably each have a verification module which is designed such that it has a received data packet which provides the distance detection enabling or supporting information, checked for the presence of the device identifier, which identifies the respective other transmitting and receiving unit, and the information contained in the data packet for determining the spatial distance only for evaluation by the distance determination module releases if in the received signal, the other transmitting and receiving unit identifying device identifier is contained, and otherwise blocking the utilization of the information.

A checksum control module of the verification module is preferably designed such that it carries out a predetermined checksum control in a data packet to be tested and releases information contained in the data packet for determining the spatial distance exclusively for evaluation by the distance determination module, if the checksum control the accuracy of the received device identifier confirmed or correct errors contained in the device identifier based on the respective checksum, and otherwise blocked the utilization of the information.

Alternatively or additionally, the checksum control module of the verification module can also be designed such that it performs a predetermined checksum control in a data packet to be tested and releases information contained in the data packet for determining the spatial distance exclusively for evaluation by the distance determination module, if the checksum control the Correctness of the information to determine the spatial distance confirmed or corrected errors can be corrected, and otherwise blocked the utilization of the information.

The control units, in particular their checksum control modules, are preferably designed such that they perform a cyclic redundancy check in the case of data packets to be tested.

It is also advantageous if the control units, in particular their distance determination modules, are designed such that they exchange and compare determined distance values which indicate the spatial distance between the two transmitting and receiving units, and in the event that the deviation between the self-determined , own distance values and the distance values received from the respective other transmitting and receiving unit reaches or exceeds a predetermined maximum difference, generate an error signal. Before, during or after the transmission of the distance values, a checksum is preferably formed for each of these, which is transmitted together with the distance values or separately from these to the respective other transmitting and receiving unit, so that the latter control of the distance values for freedom from errors and possibly one Error correction can make.

The two transmitting and receiving units are preferably configured in such a way that they transmit user data packets, in particular for the transmission of process data and / or control data for controlling and operating the conveying device.

It is also advantageous if the two transmitting and receiving units allow a transmission of user data packets with each other in a predetermined optical transmission channel, wherein the data transmission capacity of the transmission channel is sized larger than the minimum data transmission capacity required for transmitting the user data packets and the transmission channel thus provides a free channel area , One advantage of this embodiment is that both user data, for example for the transmission of control commands for controlling the conveyor, and information for determining the distance - as already explained - can be transmitted via the transmission channel.

Preferably, the control unit is at least one of, preferably both of the at least two, transmitting and receiving units - below called first transmitting and receiving unit - suitable to determine the spatial distance between the two transmitting and receiving units using information or a plurality of information on the optical free-jet connection, in particular the free channel area, from the other transmitting and receiving unit - below second transmitting and receiving unit called - to be received.

With regard to the second transmitting and receiving unit, it is considered advantageous if the control unit is designed such that it transmits the information, the information, parts of the information or parts of the information in unused packet sections of the user data packets by means of their transmitter.

Alternatively, the control unit of the second transmitting and receiving unit can be configured such that it transmits by means of its transmitter the information, the information, parts of the information or parts of the information in separate information packets sent between user data packets, in particular immediately before or after user data packets ,

With regard to the design of the control unit of the second transmitting and receiving unit, it is considered advantageous if it has a communication module for transmitting the user data packets and a distance determination module.

The distance determination module is preferably designed such that it detects or determines the time span which has elapsed or will pass between the receipt of a data packet transmitted by the first transmitting and receiving unit and the subsequent transmission of a data packet to the first transmitting and receiving unit, and detected time span as the information or one of the information to the communication module of his (ie the second) transmitting and receiving unit for forwarding to the first transmitting and receiving unit transmitted.

The communication module is preferably designed such that it transmits the detected time span as the information or one of the information in unused packet sections of the user data packets and / or in separate information packets to the first transmitting and receiving unit.

The control unit of the first transmitting and receiving unit preferably has a distance determination module, which is designed such that it detects the total period of time between the transmission of the own data packet to the second transmitting and receiving unit and the reception of the received from the second transmitting and receiving unit Data packet passes, and determines the distance on the basis of the self-acquired total time span and detected by the second transmitting and receiving unit and received as information period.

Particularly preferably, the distance determination module of the control unit of the first transmitting and receiving unit is designed such that it determines the distance according to: S = ν · dT - dt / 2 where dT denotes the self-acquired total time period, where dt denotes the time period received by the second transmitting and receiving unit as information, where v denotes the propagation speed of the optical radiation and S denotes the distance.

The at least two transmitting and receiving units, in particular their distance determination modules, are preferably each designed such that they can operate both as the one and the other transmitting and receiving unit or as both the first and the second transmitting and receiving unit and both transmitting and receiving units can determine the spatial distance between the two transmitting and receiving units individually based on received information or a plurality of received information of the respective other transmitting and receiving unit.

In addition, it is advantageous if at least one of, preferably both, of the at least two transmitting and receiving units is suitable for generating a reception clock signal from optical reception signals received via the optical free-jet connection, the points in time of rising and / or falling edge changes of the reception clock signal to acquire a plurality of clock periods using the timings in the past to estimate the time of each next edge change to form an estimated edge change timing, and to form a distance change value indicative of a change in distance between the transmission and reception units based on the estimated edge switching timing and the actual edge switching timing. An advantage of this embodiment is that in this a change in distance between the transmitting and receiving units and thus a change in distance between the movable transport device and the other portion of the conveyor can be detected in a simple and reliable manner, solely on the basis of the optical free-jet communication system transmitted clock edges. It is thus possible, for example, to others Way distance measurements obtained, in particular on the basis of information in data packets determined absolute distance measured values, promptly correct. This is of particular importance when an area between the movable transport device and the other section of the conveyor is to be released, for example for other vehicles or passing persons.

In order to determine the change in distance, the transmitting and receiving unit, in particular its control unit, preferably has a distance change detection module.

It is regarded as advantageous if the transmitting and receiving unit, in particular its distance change detection module, determines the time difference between the estimated edge change time and the actual edge change time and forms the distance change value using the time difference.

The temporal difference can be determined particularly simply and thus advantageously if the transmitting and receiving unit, in particular its distance change detection module, has a counter module which generates a time stamp, in particular a counter reading, each time the rising edge of the currently generated receive clock signal rises and / or falls.

The transmitting and receiving unit, in particular its distance change detection module, preferably determines the time difference between the estimated edge change time and the actual edge change time based on the difference between the estimated count at the estimated edge change time and the actual count at the actual edge change time.

It is also advantageous if the transmitting and receiving unit is designed in such a way that, in addition to the distance change value, it determines an absolute distance measured value indicating the distance between the transmitting and receiving units, for example based on information in data packets, as explained above.

In the latter variant, it is also advantageous if the transmitting and receiving unit is configured such that it adds the absolute distance measured value and the temporally related distance change value (signed correct) and further uses the sum value as a corrected new distance value or updated distance measured value.

For the corrected or updated distance measured value formed by addition, a checksum is preferably formed and the updated distance measured value and the checksum are respectively transmitted to the other transmitting and receiving units; The latter thus has the possibility of carrying out an examination of the respectively received updated distance measured value for freedom from errors and correct origin and subsequently to make a comparison of the checked distance measured values with self-determined own distance measured values.

The absolute distance measurement value is preferably determined by the above-mentioned distance determination module according to: S = ν · dT - dt / 2 where dT denotes the self-acquired total time period, where dt denotes the time period received by the other (second) transmitting and receiving unit as information, where v denotes the propagation velocity of the optical radiation and S denotes the distance or the abovementioned absolute distance measurement value.

The control unit preferably has a computer device and a memory in which software modules are stored, one of which, when executed by the computer device, the distance determination module, a distance change detection module when executed by the computer device, and a communication module when executed by the control unit the control unit forms the verification module and / or, when executed by the control unit, the checksum control module.

In addition, it is considered advantageous if the transmitting and receiving units each comprise a data buffer and the control units are each configured such that they each determine a buffer period for each data packet or at least for a given type of data packets before sending, for which the respective data packet is to be buffered before being sent to the respective other transmitting and receiving unit, store the data packet for the respective buffer time period in the data buffer and only then transmit it to the respective other transmitting and receiving unit. The buffer periods are preferably each determined such that they correspond to a predetermined maximum buffer period minus the predicted by the control unit term of the respective data packet to the respective other transmitting and receiving unit. By buffering can be achieved that all data packets arrive independently or at least largely independent of the respective spatial distance between the transmitting and receiving units always at the same time interval and the "packet clock" or the packet rate is distance-independent or at least largely independent of distance. Since the "packet clock" or the packet rate is fixed or quasi fixed, the processing of the data packets can be simplified because the arrival of the next data packet can be expected. It is also possible, for example, to recognize and discard foreign or corrupted data packets which have a different clock or arrive at an inopportune time.

With regard to the buffering, it is considered advantageous if the control units of both transmitting and receiving units are each configured such that they determine the spatial distance between the two transmitting and receiving units to form a distance value and taking into account this distance value, the duration of each Predict data packets.

The control units of both transmitting and receiving units preferably each have a delay module which determines a buffer time span for the data packets to be sent or at least for a given type of data packets, in particular user data packets or separate information packets, for which the respective data packet is sent to the computer before being sent each other transmitting and receiving unit to be cached.

Preferably, the delay module determines the buffer periods for each data packet according to PZS = PZSmax - tL, where PZS denotes the buffer time span to be determined, PZSmax denotes the predetermined maximum buffer time span and tL denotes the predicted runtime of the respective data packet to the respective other transmitting and receiving unit.

It is also advantageous if the delay module determines the predicted running time on the basis of a distance between the two transmitting and receiving units determined using a distance determination module and possibly a distance change detection module, according to: tL = S / v where v denotes the propagation velocity of the optical radiation, tL the predicted running time tL and S the distance.

If a distance change detection module is present, it is advantageous if its distance change value and an absolute distance measured value of the distance determination module are added (signed correct) and the sum value is used as the corrected or updated distance measured value for determining the predicted transit time tL.

Preferably, the delay module is configured such that it determines the predetermined maximum buffer time interval as a function of a predetermined maximum permissible distance Smax between the transmitting and receiving units in accordance with: PZSmax = Smax / v where Smax denotes the maximum allowable distance, PZSmax the predetermined maximum buffer period, and v the propagation velocity of the optical radiation.

The control units of both transmitting and receiving units preferably each have a delay buffer forming a data buffer whose memory size is at least as large as the product of the data rate on the optical free-jet communication connection and the maximum buffer time span. Preferably, then: SG ≥ PSmax · fd where SG denotes the memory size of the delay memory, PZSmax the maximum buffer period, and fd the data rate on the free jet optical communication link.

The conveyor preferably forms a lifting device, an elevator or a crane.

The movable transport device is preferably formed by a carriage of a bearing, in particular rack storage, a lifting element of a lifting device or a cabin or a movable lifting element of an elevator.

The movable transport device is preferably a linearly movable transport device.

The invention also relates to a method for operating a conveyor.

With regard to such a method, the invention provides that two transmitting and receiving units, one of which is fastened to a movable transport device of the conveyor and the other to another section of the conveyor, are in an optical free-jet connection and transmit data packets, the two transmitting and receiving units in each case a received signal, in particular its data packets or at least one predetermined type of data packets, for the presence of a device identifier, which identifies the other transmitting and receiving unit, check and reject the received signal, in particular the respective data packet, in whole or in part, if in the received signal or the respective data packet none other Transmitter and receiver unit identifying device identifier is included.

With regard to the advantages of the method, reference is made to the above explanations in connection with the conveying device according to the invention, since the advantages of the conveying device according to the invention correspond to those of the method according to the invention.

In addition, a conveyor with at least one movable transport device is considered as an invention, is provided in accordance with the invention that the conveyor has a free-jet optical communication system with two transmitting and receiving units, each comprising a transmitter, a receiver and a control unit and one of which the movable transport device and the other is attached to another section of the conveyor, wherein the two transmitting and receiving units are in an optical free-jet connection and allow transmission of data packets, and wherein the control unit at least one of the two transmitting and receiving units, preferably the control units both transmitting and receiving units, is configured such that it receives a received signal, in particular its data packets or at least a predetermined type of data packets, for the presence of a device identifier, the respective other transmitting and receiving unit identified, checked and the received signal, in particular the respective data packet, completely or partially discarded if in the received signal or the respective data packet no the other transmitting and receiving unit identifying device identifier is included.

The invention will be explained in more detail below with reference to exemplary embodiments, in which:

1 in a simplified schematic representation of an embodiment of a conveyor according to the invention,

2 an embodiment of a control device for transmitting and receiving units of the conveyor according to 1 .

3 - 5 for example, the transmission of data packets between the transmitting and receiving units of the conveyor according to 1 over time,

6 an embodiment of a distance determination based on information between the transmitting and receiving units of the conveyor according to 1 be transferred, and

7 - 8th by way of example, the determination of a change in distance by estimation of edge change times and comparison of the estimated edge change times with the actual edge change times.

In the figures, the same reference numerals are used for identical or comparable components.

The 1 shows in a simplified schematic representation of an embodiment of a conveyor according to the invention 10 , which may be, for example, a lifting device, an elevator, a crane or the like. In the embodiment according to 1 forms the conveyor 10 a component of an automated shelf warehouse and includes, inter alia, a movable transport device 20 , For example, in the form of a linearly movable along the direction of the arrow X Verfahrwagens.

The conveyor 10 shows a free jet optical communication system 30 This is a free-jet optical communication link 40 between the movable transport device 20 and at another section 11 For example, stationary section or other Verfahrwagen, the conveyor 10 allows.

The free jet communication system 30 includes one on the movable transport device 20 attached first transmitting and receiving unit 101 and one on the other section 11 the conveyor 10 attached second transmitting and receiving unit 102 , The two transmitting and receiving units 101 and 102 are preferably identical and can therefore be operated in an identical manner. The examples below for the first transmitting and receiving unit 101 explained mode of operation can accordingly in a corresponding manner by the second transmitting and receiving units 102 be executed, and vice versa.

The two transmitting and receiving units 101 and 102 each include a transmitter 110 , a receiver 120 and a control unit 130 and stand in the open beam optical communication link 40 for the purpose of transmitting user data packets NDP.

The user data packets NDP are preferably transmitted in a predetermined optical transmission channel. It will be advantageous considered when the data transmission capacity of the transmission channel is sized larger than the minimum data transmission capacity required for transmitting the user data packets NDP, so that the transmission channel provides a free channel area available. In the case of such a design of the free jet optical communication link 40 For example, it is possible to additionally transmit information that is a determination of the distance S or the spatial distance between the two transmitting and receiving units 101 and 102 enable.

The distance S can be used to control the conveyor 10 be used, for example, an area between the movable transport device 20 and the other section 11 the conveyor 10 be released, for example, for other vehicles or passing persons. It is important for this reason that the distance S is determined as accurately as possible and transmitted as error-free as possible; because a faulty distance indication could cause an accident.

The 2 shows an embodiment of a control unit 130 in the two transmitting and receiving units 101 and 102 according to 1 can be used.

The control unit 130 includes a computing device 200 , which is preferably a microprocessor device, and a memory 210 , In the store 210 There is a multitude of program modules stored by the computer 200 can be executed and executed by the computing device 200 preferably a communication module 220 , a distance determination module 230 , a distance change detection module 240 , a delay module 250 and a verification module 260 form.

The communication module 220 stands with the transmitter 110 and the receiver 120 and wraps the open beam optical communication link 40 between the two transmitting and receiving units 101 and 102 from.

The 3 shows by way of example a stream of user data packets NDP over the time t transmitted by the communication module 220 generated for the purpose of sending or by the communication module 220 the other transmitting and receiving unit can be received. In the user data packets NDP, process data and control data for controlling and operating the conveyor 10 be transmitted.

With the communication module 220 is the distance determination module 230 in connection. The task of the distance determination module 230 consists of evaluating information I, which is transmitted over the free-jet communication link 40 be transmitted between the two transmitting and receiving units and allow a distance determination.

The information I can be transmitted in unused packet sections of the user data packets NDP, as in the 4 is shown by way of example, or in separate information packets I2, as in the 5 is shown by way of example.

At the information I, over the free-jet communication link 40 are preferably timestamps.

In connection with 2 and 6 is explained below by way of example, as based on received timestamps of the second transmitting and receiving unit 102 the first transmitting and receiving unit 101 the distance S to the second transmitting and receiving unit 102 can determine:
The distance determination module 230 the first transmitting and receiving unit 101 detects the total time span dT between the transmission of a separate data packet DP1 (eg user data packet or separate information packet) to the second transmitting and receiving unit 102 (see time t1 in 6 ) and the subsequent reception of one of the second transmitting and receiving unit 102 received data packets DP2, hereinafter also called response data packet, passes (see time t4 in 6 ).

The distance determination module 230 the second transmitting and receiving unit 102 determines the time span dt that elapses between the reception of the from the first transmitting and receiving unit 101 sent data packet DP1 (see time t2 in 6 ) and the subsequent transmission of the response data packet (see time t3 in FIG 6 ) to the first transmitting and receiving unit 101 has passed or will pass, and transmits this detected time interval dt as information I to the first transmitting and receiving unit 101 , The time span dt is formed by subtracting the times t2 and t3.

• – wobei dT die von der ersten Sende- und Empfangseinheit 101 selbst erfasste Gesamtzeitspanne bezeichnet,
• – wobei dt die von der zweiten Sende- und Empfangseinheit 102 als Information I gesendete und von der ersten Sende- und Empfangseinheit 101 empfangene Zeitspanne bezeichnet,
• – wobei v die Ausbreitungsgeschwindigkeit der optischen Strahlung bezeichnet und
• – wobei S den Abstand bzw. einen absoluten Abstandsmesswert, der den Abstand zum Zeitpunkt t4 des Datenpaketempfangs in 6 angibt, bezeichnet.

Based on the information I, the distance determination module 230 the first transmitting and receiving unit 101 now determine the distance according to: S = ν · dT - dt / 2

• Where dT is the one from the first transmitting and receiving unit 101 self-recorded total time period,
• Where dt is the one from the second transmitting and receiving unit 102 sent as information I and from the first transmitting and receiving unit 101 term received,
• Where v denotes the propagation velocity of the optical radiation and
• Where S is the distance or an absolute distance measured value which determines the distance at the time t4 of the data packet reception in 6 indicates.

To the distance determination module 230 the second transmitting and receiving unit 102 to allow a distance determination in an identical manner, transmits the distance determination module 230 the first transmitting and receiving unit 101 also in each case the time interval (information I ') between the reception of one of the second transmitting and receiving unit 102 sent data packet (in 6 not shown) and the subsequent transmission of the data packet DP1 to the second transmitting and receiving unit 102 has passed or will pass. Based on the received information I ', the distance determination module 230 the second transmitting and receiving unit 102 calculate the distance S in a corresponding or identical manner, as in connection with the first transmitting and receiving unit 101 has been explained.

The distance determination modules 230 The two transmitting and receiving units thus allow a regular absolute measurement of the distance S or a regular determination of a corresponding absolute distance measurement value S between the transmitting and receiving units, in accordance with the temporal rate of the transmitted data packets.

The distance determination modules 230 The two transmitting and receiving units preferably exchange the distance values determined by them with each other and compare them. In the event that the deviation between the own distance values and the distance values received from the respectively other two transmitting and receiving unit reaches or exceeds a predetermined maximum difference, the distance determination modules generate 230 preferably an error signal.

To be particularly fast, and in particular faster than with the distance determination module 230 , a change of the distance determination module 230 to be able to recognize the determined distance S is the control device 130 according to 2 with the distance change detection module 240 fitted.

The distance change detection module 240 stands with the communication module 220 Connected and generated with the via the optical free-jet connection 40 received optical received signal Pin (t), ie with the stream of incoming data packets (see 3 to 5 ) a receive clock signal Ta (t), which is exemplified in the 7 is shown over time t.

Based on the receive clock signal Ta (t), the distance change detection module 240 to detect the time points of rising and / or falling edge changes of the receive clock signal over a plurality of clock periods. In the embodiment according to 7 For example, it is assumed that the distance change detection module 240 in each case evaluates the times of the rising edge changes; These dates are in the 7 denoted by the reference numerals t1 to t4.

Using the times t1 to t4 in the past, the distance change detection module may 240 by means of calculating the mean period length T and using the average period length T and the time of the last edge change to estimate the time of the respectively next edge change to form an estimated subsequent edge change time t5 '(see 7 ) according to: t5 '= t4 + T

Based on the estimated edge change time t5 'and the actual measured edge change time t5 (see 8th ) or on the basis of the time difference dT between these edge change times, the change of the distance S between the transmitting and receiving units 101 and 102 and a corresponding distance change value dS are determined according to: dS = vdT = v (t5 '- t5) where v denotes the propagation speed of the optical radiation.

To determine the time difference dT, the distance change detection module 240 a counter module 241 have, each of which generates a time stamp in the form of the respective meter reading at rising edge of the currently generated receive clock signal Ta (t).

The time difference dT between the estimated edge change time t5 'and the actual edge change time t5 can be determined in such an embodiment from the difference between the estimated count Zg at the estimated edge change time t5' and the actual count Zt at the actual edge change time t5 according to: dT = (Zg - Zt) / fT where fT denotes the counter rate or the counter clock frequency.

In the embodiment according to the 7 and 8th becomes the distance change detection module 240 So determine that the distance S between the two transmitting and receiving units 101 and 102 by the distance change value dS has decreased since the rising edge has arrived earlier than predicted.

The distance change detection module 240 the distance change value dS is preferably sent to the distance determination module 230 transmit, which will correct the previously determined distance value Sa accordingly and generates a new distance value S by sign-correct addition with the distance change value dS (here dS <0) according to: S = Sa + ds

The distance determination modules 230 The two transmitting and receiving units can exchange and compare the corrected new distance values. In the event that the deviation between the own corrected distance values and the corrected distance values received from the respective other transmitting and receiving unit reaches or exceeds a predetermined maximum difference, the distance determination modules generate 230 preferably an error signal.

In order to be able to recognize whether the corrected new distance values actually originate from the respective other assigned transmitting and receiving unit and / or have been transmitted without errors, preferably a respective checksum is formed with or from the corrected new distance values and the checksums are combined with the corrected new distance measured values are transmitted to the respective other transmitting and receiving units, so that the latter can make an examination of the received distance measured values for accuracy or correct origin. For the transmission-side formation of the checksums have the communication modules 220 preferably in each case a checksum module 221 on.

The above related to the 2 mentioned delay module 250 the control device 130 is preferably connected to the communication module 220 and the distance determination module 230 in connection.

The function of the delay module 250 the control device 130 consists of for the data packets to be sent, or at least for a given type of data packets such as the user data packets NDP or the separate information packets IP according to the 2 to 5 , each determine a buffer period PTS for which the respective data packet is to be buffered before being sent to the respective other transmitting and receiving unit. For buffering the data packets serves a data buffer forming delay memory 251 in 2 ,

The buffer periods PZS are respectively determined for each data packet such that they have a predetermined maximum buffer period minus that of the delay module 250 Predicted run time of the respective data packet to the respective other transmitting and receiving unit correspond. In other words, the following should be preferred: PZS = PZSmax - tL, wherein PZS denotes the buffer period, PZSmax the predetermined maximum buffer period and tL the predicted term of the respective data packet to the respective other transmitting and receiving unit.

The delay module evaluates the predicted running time tL 250 preferably that of the distance determination module 230 determined distance S between the two transmitting and receiving units 101 and 102 as well as that of the distance change detection module 240 determined distance change value dS and determines the predicted running time tL according to: tL = Sk / v where v is the propagation velocity of the optical radiation and Sk is the distance change value dS of the distance change detection module 240 corrected distance value S of the distance determination module 230 (Sk = S + ds).

The predetermined maximum buffer time period PZSmax is preferably determined as a function of the maximum possible or permissible distance Smax between the transmitting and receiving units 101 and 102 , Preferably, the maximum buffer time period PZSmax is determined according to: PZSmax = Smax / v

The memory size SG of the delay memory 251 is preferably selected such that it can store data for the maximum buffer time period PZSmax. In the case of a data rate fd on the optical free-jet communication link 40 the minimum memory size SGmin results as follows: SG ≥ SGmin = PSmax · fd

By buffering by means of the delay module 250 in the delay memory 251 It is achieved that all data packets regardless of the respective spatial distance between the transmitting and receiving units 101 and 102 always arrive at the same time interval, and the "packet clock" or the packet rate is independent of distance.

The above related to the 2 mentioned verification module 260 the control device 130 is preferably connected to the communication module 230 in connection and monitors the incoming received signal Pin (t) and thus with the received signal Pin (t) transmitted data packets or a predetermined selection of data packets to the presence of a device identifier, the other transmitting and receiving unit 101 respectively. 102 clearly identified.

The verification module 260 can check all data packets with respect to the device identifier, that is, regardless of whether they contain distance or time stamp information suitable for distance determination or not, or alternatively for discharge only data packets with distance or time stamp information. For example, in the case that separate information packets IP with distance or time stamp information are received (see 5 ), preferably only the separate information packets IP are examined for the valid device identifier.

Preferably, the verification module becomes 260 Data packets or at least their information for determining the spatial distance between the two transmitting and receiving units 101 and 102 Block or discard if no correct, so none the other transmitting and receiving unit 101 respectively. 102 uniquely identifying, device identifier is found.

If the verification module 260 is used exclusively in connection with the evaluation of distance or time stamp information, it is advantageous if the verification module 260 with the distance determination module 230 or preferably even exclusively with the distance determination module 230 and performs an originator validation check only in the context of data packets due to the presence of distance or timestamp information from the distance determination module 230 to be recycled.

It is considered particularly advantageous if the verification module 260 for verification, a checksum control module 261 having.

• – jeweils für jedes Datenpaket,
• – jeweils für die im jeweiligen Datenpaket enthaltene Gerätekennung und/oder
• – jeweils für die im jeweiligen Datenpaket enthaltene Abstands- oder Zeitstempelinformation.

The checksum control module 261 evaluates one in the received signal Pin (t) (see. 3 to 5 ), in particular in the respectively received data packet contained checksum and examines these for accuracy of the received data. In order to enable such error checking and possibly even an error correction, send the communication modules 220 the two transmitting and receiving units 101 respectively. 102 prefers a checksum

• - for each data packet,
• - in each case for the device identifier contained in the respective data packet and / or
• - in each case for the distance or time stamp information contained in the respective data packet.

The checksum is preferably a CRC code (cyclic redundancy check code).

Preferably, the checksum control module becomes 261 in the context of the error check in the received signal pin (t) contained distance or time stamp information exclusively for further use and further evaluation (ie distance determination) by the distance determination module 230 release if the error check the accuracy of the received device identifier and / or the accuracy of the distance or time stamp information confirmed or can correct existing errors. Otherwise, the checksum control module becomes 261 the further use and further evaluation of the erroneous data packets by the distance determination module 230 To block.

The checksum control module 261 is preferably configured to handle CRC codes and to perform error checking and error correction in the context of a cyclic redundancy check.

• – jeweils für jedes Datenpaket,
• – jeweils für die im jeweiligen Datenpaket enthaltene Gerätekennung und/oder
• – jeweils für die im jeweiligen Datenpaket enthaltene Abstands- oder Zeitstempelinformation.

In order to be able to send corresponding checksums in or with the data packets at the transmitting end, this is done by the receiver-side checksum control module 261 can be evaluated, have the communication modules 220 one checksum module each 221 on. The checksum module 221 forms and sends checksums preferred

• - for each data packet,
• - in each case for the device identifier contained in the respective data packet and / or
• - in each case for the distance or time stamp information contained in the respective data packet.

While the invention has been illustrated and described in detail by way of preferred embodiments, the invention is not limited to the disclosed examples. Other variations can be derived by those skilled in the art from the disclosed examples without departing from the scope of the invention.

LIST OF REFERENCE NUMBERS

10

Conveyor

11

Section of the conveyor

10

first transmitting and receiving unit

20

movable transport device

30

Free jet communication system

40

optical free-jet communication link

102

second transmitting and receiving unit

110

transmitter

120

receiver

130

control unit

200

computing device

210

Storage

220

communication module

221

Prüfsummenbildungsmodul

230

Distance determination module

240

Distance change detection module

241

counters block

250

delay module

251

delay memory

260

verification module

261

Prüfsummenkontrollmodul

dS

Distance change value

dT, dt

periods

DP1, DP2

data packets

I

information

IP

information packet

NDP

user data packets

Pint)

receive signal

PZS

Buffer period

S

Distance / spatial distance

t

Time

t1-t5, t5 '

timings

T

period length

Did)

Receive clock signal

X

arrow

Claims (15)

Conveyor ( 10 ) with at least one movable transport device ( 20 ), characterized in that - the conveyor ( 10 ) a free jet optical communication system ( 30 ) with two transmitting and receiving units ( 101 . 102 ), each one transmitter ( 110 ), a receiver ( 120 ) and a control unit ( 130 ) and one of which on the movable transport device ( 20 ) and the other at another section ( 11 ) of the conveyor ( 10 ), the two transmitting and receiving units ( 101 . 102 ) in an optical free-jet connection ( 40 ) and allow a transmission of data packets, - wherein the control unit ( 130 ) at least one of the two transmitting and receiving units ( 101 . 102 ), preferably the control unit ( 130 ) of both transmitting and receiving units ( 101 . 102 ), is configured such that it transmits a received signal, in particular its data packets or at least one predetermined type of data packets, to the presence of a device identifier which the respective other transmitting and receiving unit ( 101 . 102 ) identifies, checks and rejects the received signal, in particular the respective data packet, completely or in parts, if in the received signal or the respective data packet none of the other transmitting and receiving unit ( 101 . 102 ) Identifying device identifier is included, - wherein the control unit ( 130 ) at least one of the two transmitting and receiving units ( 101 . 102 ) is configured in such a way that it is emitted via the optical free-jet connection ( 40 ) receives a timing clock signal that detects times of rising and / or falling edge changes of the reception clock signal over a plurality of clock periods, estimates the time of each next edge change in forming an estimated edge change time point based on the estimated edge change time point and the actual edge change time a change in distance between the transmitting and receiving units ( 101 . 102 ) indicating the change in distance value, 130 ) at least one of the two transmitting and receiving units ( 101 . 102 ) is configured such that, in addition to the distance change value, the distance between the transmitting and receiving units ( 101 . 102 ), the absolute distance measured value, and - wherein the control unit ( 130 ) at least one of the two transmitting and receiving units ( 101 . 102 ) is configured to add the distance change value and the absolute distance measurement value and to further use the sum value as the actual distance measurement value. Conveyor ( 10 ) according to claim 1, characterized in that - the control unit ( 130 ) at least one of the two transmitting and receiving units ( 101 . 102 ), preferably the control unit ( 130 ) of both transmitting and receiving units ( 101 . 102 ), is configured such that it the spatial distance between the two transmitting and receiving units ( 101 . 102 ) using one or more of the information enabling or facilitating the determination of the distance, which from the other transmitting and receiving unit ( 101 . 102 ), and - the control unit ( 130 ) is further configured to receive a received data packet having information enabling or supporting the distance detection for the presence of the device identifier that the respective other transmitting and receiving unit ( 101 . 102 ) identifies, checks and uses the information contained in the respective data packet for determining the spatial distance exclusively if the device identifier is contained in the respective data packet, and otherwise disregards the received signal in the distance determination. Conveyor ( 10 ) according to one of the preceding claims, characterized in that - the control unit ( 130 ) at least one of the two transmitting and receiving units ( 101 . 102 ), preferably the control unit ( 130 ) of both transmitting and receiving units ( 101 . 102 ), a distance determination module ( 230 ) and a verification module ( 260 ), wherein the distance determination module ( 230 ) is designed such that it the spatial distance between the two transmitting and receiving units ( 101 . 102 ) using one or more pieces of information received from the other transmitting and receiving unit (s) ( 101 . 102 ), and - wherein the verification module ( 260 ) is configured such that it has a received data packet which has a distance determination enabling or supporting information on the presence of the device identifier that the respective other transmitting and receiving unit ( 101 . 102 ) and checks the information contained in the data packet for determining the spatial distance exclusively for evaluation by the distance determination module ( 230 ), if in the data packet the other transmitting and receiving unit ( 101 . 102 ) identifying device identifier, and otherwise blocks the utilization of the information. Conveyor ( 10 ) according to one of the preceding claims, characterized in that the control unit ( 130 ) at least one of the two transmitting and receiving units ( 101 . 102 ), preferably the control unit ( 130 ) of both transmitting and receiving units ( 101 . 102 ), a verification module ( 260 ) with a checksum control module ( 261 ), which is configured such that it carries out a predetermined checksum control in a data packet to be tested and an information contained in the data packet for determining the spatial distance exclusively for evaluation by the distance determination module ( 230 ) if the checksum control confirms the accuracy of the received device identifier or if errors contained in the device identifier can be corrected using the respective checksum, and otherwise blocks the utilization of the information. Conveyor ( 10 ) according to one of the preceding claims, characterized in that the control unit ( 130 ) at least one of the two transmitting and receiving units ( 101 . 102 ), preferably the control unit ( 130 ) of both transmitting and receiving units ( 101 . 102 ), a verification module ( 260 ) with a checksum control module ( 261 ) configured to perform a predetermined checksum control on a data packet to be tested, and information for determining the spatial distance contained in the data packet exclusively for evaluation by the distance determination module (10). 230 ), if the checksum control confirms the accuracy of the information to determine the spatial distance, or correct errors that have been found, and otherwise blocks the exploitation of the information. Conveyor ( 10 ) according to one of the preceding claims, characterized in that the control unit ( 130 ) at least one of the two transmitting and receiving units ( 101 . 102 ), preferably the control unit ( 130 ) of both transmitting and receiving units ( 101 . 102 ), in particular its checksum control module ( 261 ), is designed such that it carries out a cyclic redundancy check for data packets to be tested. Conveyor ( 10 ) according to one of the preceding claims, characterized in that the control units ( 130 ), in particular their distance determination modules, are designed such that they determine the distance values which determine the spatial distance between the two transmitting and receiving units ( 101 . 102 ), exchange and compare with one another and in the event that the deviation between the self-determined own distance values and those of the respective other transmitting and receiving unit ( 101 . 102 ) distance values reaches or exceeds a predetermined maximum difference, generate an error signal. Conveyor ( 10 ) according to one of the preceding claims, characterized in that the transmitting and receiving units ( 101 . 102 ) are configured such that they mutually user data packets, in particular for the transmission of process data and / or control data for controlling and operating the conveyor ( 10 ), transfer. Conveyor ( 10 ) according to one of the preceding claims, characterized in that the control unit ( 130 ) of both transmitting and receiving units ( 101 . 102 ), is designed such that it comes out via the optical free-jet connection ( 40 ) receives a timing clock signal that detects times of rising and / or falling edge changes of the reception clock signal over a plurality of clock periods, estimates the time of each next edge change in forming an estimated edge change time point based on the estimated edge change time point and the actual edge change time a change in distance between the transmitting and receiving units ( 101 . 102 ) indicating the distance change value. Conveyor ( 10 ) according to one of the preceding claims, characterized in that the control unit ( 130 ) of both transmitting and receiving units ( 101 . 102 ) is configured such that, in addition to the distance change value, the distance between the transmitting and receiving units ( 101 . 102 ), absolute distance measured value determined. Conveyor ( 10 ) according to one of the preceding claims, characterized in that the control unit ( 130 ) of both transmitting and receiving units ( 101 . 102 ) is configured to add the distance change value and the absolute distance measurement value (signed correct) and to further use the sum value as the actual distance measurement value. Conveyor ( 10 ) according to one of the preceding claims, characterized in that the control unit ( 130 ) at least one of the two transmitting and receiving units ( 101 . 102 ), preferably the control unit ( 130 ) of both transmitting and receiving units ( 101 . 102 ) is configured to add the distance change value and an absolute distance measurement and to continue to use the sum value as the updated distance measurement and to check the updated distance measurement to the other transmitter and receiver unit ( 101 . 102 ) transmitted. Conveyor ( 10 ) according to one of the preceding claims, characterized in that the control unit ( 130 ) at least one of the two transmitting and receiving units ( 101 . 102 ), preferably the control unit ( 130 ) of both transmitting and receiving units ( 101 . 102 ), is designed such that it determines the distance, in particular the abovementioned absolute distance measured value, according to: S = ν · dT - dt / 2 - where dT denotes a self-acquired total time period, - dt one from the other transmitting and receiving unit ( 101 . 102 ) denotes the time period received as information, where v denotes the propagation speed of the optical radiation, and S denotes the distance or the absolute distance measurement value. Conveyor ( 10 ) according to one of the preceding claims, characterized in that the control unit ( 130 ) at least one of the two transmitting and receiving units ( 101 . 102 ), preferably the control unit ( 130 ) of both transmitting and receiving units ( 101 . 102 ), is configured in such a way that it determines, for each data packet or at least for a given type of data packets, a buffer time span before transmission, for which the respective data packet is sent to the respective other transmitting and receiving unit ( 101 . 102 ) is to be buffered, stores the data packet for the respective buffer period in the data buffer and only then to the respective other transmitting and receiving unit ( 101 . 102 ), wherein the buffer time intervals are each determined such that these a predetermined maximum buffer period less that of the control unit ( 130 ) predicted runtime of the respective data packet to the respective other transmitting and receiving unit ( 101 . 102 ) correspond. Method for operating a conveyor ( 10 ), characterized in that - two transmitting and receiving units ( 101 . 102 ), one of which is attached to a movable transport device ( 20 ) of the conveyor ( 10 ) and the other at another section ( 11 ) of the conveyor ( 10 ), in an optical free-jet connection ( 40 ) and transmit data packets, - wherein the two transmitting and receiving units ( 101 . 102 ) in each case a received signal, in particular its data packets or at least one predetermined type of data packets, for the presence of a device identifier, which is the respective other transmitting and receiving unit ( 101 . 102 ), and reject the received signal, in particular the respective data packet, completely or partially, if in the received signal or the respective data packet none of the other transmitting and receiving unit ( 101 . 102 ) Identifying device identifier is included, - wherein the control unit ( 130 ) at least one of the two transmitting and receiving units ( 101 . 102 ), preferably the control unit ( 130 ) of both transmitting and receiving units ( 101 . 102 ), via the optical free-jet connection ( 40 received received optical signals, a receive clock signal estimating the timing of rising and / or falling edge changes of the reception clock signal over a plurality of clock periods, estimating the timing of each next edge change forming an estimated edge change timing using the timings in the past, and one using the estimated edge switching timing and the actual edge switching timing Change in distance between the transmitting and receiving units ( 101 . 102 ) indicating the change in distance value, 130 ) at least one of the two transmitting and receiving units ( 101 . 102 ), preferably the control unit ( 130 ) of both transmitting and receiving units ( 101 . 102 ), in addition to the distance change value a the distance between the transmitting and receiving units ( 101 . 102 ), the absolute distance measured value, and - wherein the control unit ( 130 ) at least one of the two transmitting and receiving units ( 101 . 102 ), preferably the control unit ( 130 ) of both transmitting and receiving units ( 101 . 102 ), the distance change value and the absolute distance measurement value are added, and the sum value is further used as the actual distance measurement value.

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