GB2055235A - Control and monitoring system for cigarette packaging machines - Google Patents

Abstract

A control and monitoring system for cigarette packaging machines comprises a control station (1) connected in cascade to each of a plurality of remote stations (2 and 3) in turn, in a ring. The control station 1 supplies an interrogation signal to a D- type latch of the first remote station, which changes state on the next clock pulse edge and applies an interrogation signal to the D-type latch of the second remote station so that the stations are sequentially interrogated in essentially non- overlapping time periods. An interrogated station communicates with the control station (1) via an information line (16) either to receive machine control signals to be passed on to a machine or machine part with which the remote station is associated, or to send machine fault signals indicating a fault in the associated machine or machine part. <IMAGE>

Description

SPECIFICATION Cigarette packaging machine control and monitoring system The present invention relates to a cigarette packaging machine control and monitoring system, e.g. for supplying periodic control signals to each of a plurality of parts of a packaging machine or to each of a plurality of packaging machines, and for monitoring faults or other special conditions in such machines or machine parts.

A cigarette packaging operation comprises a large number of often delicate operations which need to be initiated reliably and rapidly in predetermined and periodically repeated sequences. In addition the machine parts performing these delicate operations are subject to faults and it is highly desirable in the cigarette industry for such faults to be determined and located quickly.

Normally cigarette packaging machines have control and monitoring systems which require separate wires running from a central control to each of the plurality of machines or machine parts.

Such systems result in complex wiring systems which are expensive, difficult to install and maintain, and tend to be unreliable as wires can break, thus affecting the operation of the system without being noticed immediately. The complexity of such known systems also renders them not easily adaptable to expansion to control and monitor a larger number of machine operations.

According to one aspect of the present invention there is provided a packaging machine, for packaging cigarettes or other rod-like articles of the cigarette industry, comprising: a plurality of separate machine parts for effecting respective operations associated with such packaging; a plurality of remote stations respectively connected to some or all of said parts, each station comprising an input station arranged (when interrogated) to receive signals from the respective part signifying the presence of a fault or other special condition, or comprising an output station being arranged (when interrogated) to supply a machine control signal to the associated part; a control centre station connected with all the remote stations in cascade, and including means for interrogating the first remote station in the cascade, each station including means for relaying an interrogation signal to the next station so that the remote stations are sequentially interrogated in turn, the system including also an information line for transferring fault and control signals between the remote stations and the control centre station.

Preferably the stations are connected in cascade in a ring so that interrogation control signals propagate from the control station, through all the remote stations and return to the control station.

Hence according to a second aspect of the invention there is provided a control system comprising: a plurality of stations including a plurality of remote stations and a control station for interrogating the remote stations; connecting means coupling the stations in cascade in a ring; an information line connected to all the stations for transferring information between the control stations and an interrogated remote station; the control station including means for generating an interrogation control signal and being arranged to supply the interrogation signal to the first station in the ring; and each station including means for relaying a received interrogation signal after a delay to the next station in the ring so that the stations are repeatedly sequentially interrogated during respective essentially non-overlapping time periods.

A warning device may be operated, if the interrogation signal does not return to the control station within a preset time, to indicate line faults.

Each remote station preferably includes an indicating device, e.g. an LED for indicating when the associated remote station is being interrogated.

Hence the location of a line fault may be identified if the control station has means for manually applying an interrogation signal to the remote stations to light all the LED's between the control station and the line fault.

The information line is preferably a two-way closed loop line.

The relay means may comprise a bistable device such as a D-type latch.

According to the third aspect of the present invention there is provided a control system comprising a control centre station; a plurality of remote stations; a transmission line network interconnecting the control centre station and the remote stations and including a clock line and an information line, each common to all the stations, and a control line connecting the stations in cascade so that a control signal from the control centre sequentially enables the stations during successive essentially non-overlapping time periods to communicate with the information line, each station comprising a first bistable device arranged to be clocked from the clock line and a second bistable device arranged to be clocked by the output of the first bistable device for communicating with the information line during the respective time period.

The second bistable devices of each input station are preferably arranged for storing a fault (or other special condition) when it occurs so that it can be transmitted to the control station when the associated remote input station is next interrogated.

Multiplexing means is preferably provided in the control centre station to enable a signal to be routed between input/output stations and output/input ports at the control centre, each output/input port being uniquely associated with a station.

For a better understanding of the present invention and to show how the same may be carried into effect, reference will now be made to the accompanying drawings, in which: Figure 1 is a schematic block diagram of a system according to the present invention; Figure 2 is a circuit diagram of an input station of the system of Figure 1; Figure 3 is a circuit diagram of an output station of the system of Figure 1; Figure 4 is a circuit diagram of the control centre of the system of Figure 1; Figure 5 is a timing diagram of signals pertaining to the system of Figure 1.

Figure 1 shows a control centre 1 and four remote stations 2 and 3 connected together in a ring by wires 4. In practice, more than four stations will be connected in the ring, as is indicated by the chain dotted line in the wires 4.

Each station may be associated with a machine or with a part of a machine to be controlled or monitored and is either an input station 2 (Figure 2) for detecting faults in its associated machine or machine part, or an output station 3 (Figure 3) for controlling, e.g. switching on or off, its associated machine or machine part.

The control centre 1 controls the stations 2 and 3 by sequentially interrogating them in a time division manner, to be explained hereinafter, so that the input stations 2 deiiver information to the control centre 1, and the output stations 3 receive information from the control centre 1, each in its own discreet time slot which identifies the station which is communicating.

Information received from or to be sent to each station 2 and 3 is delivered to or from the control centre 1 via linking circuitry 5 and interface lines 6 and 7 respectively. The number of interface lines 6 corresponds to the number of stations. Interface lines 6 are linked to input stations 2 and receive, for example, fault signals delivered by the input stations 2 to the control centre 1. Line 6 consists of a buffer amplifier 8 with a feedback resistor 9 connected across it to keep information, once received from the control centre 1, at the output of line 6 even after the information signal is removed from the input to amplifier 8 while the other stations are interrogated. An indicating device such as an LED (not shown) may be connected to the line 6 to lightup when the information signal indicates that a station has detected a machine fault.

Line 7 has an amplifier 10 for feeding in signals for an output station 3.

The wires 4 comprise a clock line 12, an interrogation control line 14, an information line 1 6 and a reset line 1 8 together with power lines + and 0. These lines run, as shown, from the control centre 1 to each station 2 and 3 in turn and back to the control centre 1.

Figures 2 and 3 show an input and an output station 2 and 3 respectively. Each comprises two positive edge triggered D-type bistabies 20, 22 and 30, 32 respectively, connected as shown.

The first bistable of each station (20, 30) receives interrogation control signals on control line 14 from the previous station (or from the control centre 1 in the case of the first station), delays the interrogation control signal and passes it on to the next station. Light emitting semiconductor devices such as LED's 24, 25 are provided at the output of each first bistable 20, 30 to indicate when that station is being interrogated.

The second bistable of each station (22, 32) acts as a store for the information to be transferred to or from the control centre 1. After the first bistable in a station receives the interrogation control signal via line 14, then the second bistable 22, 32 communicates such information with the control centre 1 via information line 16.

Control centre 1 supplies clock pulses ("a" in Figure 5) on clock line 12 to the first bistable of each station 20 (Figure 2) and 30 (Figure 3) continuously. At the start of each interrogation cycle, the control centre 1 sends a reset pulse on line 1 8 to reset the first bistables 20 (Figure 2) and 30 (Figure 3). Sequentially an interrogation control pulse is generated ("b" Figure 5) by the control centre 1 and received at the "D" input of the first bistable 20 of the first station 2 (Figure 1) in the ring at time t, (Figure 5). The first bistable 20 changes state at the next positive-going clock pulse edge, at time t2 in Figure 5, causing its "Q" output to go "high" and pulse "c" in Figure 5 to be generated and propagated to the next station 3 (Figure 1).Simultaneously the 'IT" output of the first bistable 20 goes "low" and this negativegoing pulse is applied to the clock input of the second bistable 22. Bistable 22 has its "D" and "R" inputs connected to ground and its "S" input connected to receive a positive voltage if there is a fault in the machine or machine part associated with that station. This is achieved, in this example, using an opto-coupler device 26 whose output goes "high" when a transducer feeding it (not shown) detects a machine fault. Of course the input station could be used to monitor any specified condition so long as a suitable transducer for detecting the condition is available and connected to the opto-coupler 26. Hence if a machine fault (or other specified condition) is present then the "S" input of bistable 22 is "high"; hence bistable 22 is set, i.e. its "0" output is "high".The output of the first bistable 20 interrogates bistable 22 to determine its state, i.e.

to determine whether a fault exists at the machine associated with that station. It does this via diodes 31 and 33 which act as an "AND" gate. If the "Q" outputs of both bistables 20 and 22 are "high", then point 35 is "high" and transistor 37 is switched on. This causes a negative pulse, coincident with the positive pulse at the "Q" output of bistable 20, to appear on the information line 16 in a unique time slot t2-t3 ("d" in Figure 5) identified with the first station. When the "Q" output of bistable 20 goes "low" again, the "u" output goes "high" resetting bistable 22 if the fault has disappeared, i.e. if "S" is "low".

The positive pulse at the "0" output of the first bistable 20 of the first station 2 ("c" in Figure 5) is propagated to the next station, e.g. to the output station 3 illustrated in Figure 3. The operation of this output station will now be described. This delayed control pulse is received at the "D" input of the first bistable 30, causing bistable 30 to change state at the next positive-going clock pulse edge, i.e. at time t3 in Figure 5. Hence pulse "e" (Figure 5) appears at the "Q" output of bistable 30 and propagates to the next station. Pulse "e" (Figure 5) is also applied to the clock input of the second bistable 32 of this output station 3.If the control centre 1 desires to pass a machine control signal to a machine or device associated with this output station 3 then the control centre 1 will apply the machine control signal to "information" line 16, which is connected to the "D" input of the second bistable 32, in the appropriate time slot for this station, which is t3 to t4 (Figure 5). The clock input to bistable 32 will cause the machine control signal applied to the "D" input to be passed to the "Q" output (not shown) of bistable 32 causing the '7' output to adopt the complementary logic state (i.e. "low" in this example). The machine control signal is then passed to the device to be operated, in this example from the "5" output of bistable 32 via buffer amplifier 27, opto-coupler 28 and output transistor 29.

Hence in this example it can be seen that the first station 2 is interrogated in the period t2 to t3 and passes a machine fault signal to the control centre 1 via line 1 6 during that period, and subsequently station 3 is interrogated during period t3 to t4 during which time it receives a machine control signal from the control centre 1 via line 1 6. Subsequent stations are interrogated in the same way in subsequent time periods. Race hazards are prevented by connecting capacitors in the interrogation control line, as shown, so that the interrogation control pulses are slightly elongated, as shown at (b) and (c) in Figure 5.

Figure 4 shows the circuit of the control centre 1. There are four output terminals 12, 14, 1 6, 18 and four input terminals 12A, 14A, 16A, 18A corresponding to the start and finish respectively of the lines 12,14, 16 and 18 of Figures 1 to 3.

The control circuit comprises a pulse generator 34 connected to a counter 36 which drives a multiplexer 38. Information such as machine control signals for output stations 3 and fault signals from input stations 2 are applied from/to the multiplexer 38 via terminals 1 6, 1 6A, transistor 40 and information terminal 42. A number of multiplexer output ports 44 is provided which corresponds to the number of input/output stations in the system. These output ports are connected via linking circuit 5 to appropriate interface lines 6 and 7 (Figure 1). The multiplexer 38 and the counter 36 operate to connect each output port in turn to information terminal 42 in such a way that signals can pass in either direction.

Other circuit elements are provided for selfchecking purposes for detecting faults in the operation of the control circuit itself. Bistable 45 detects if there is a break in the system ring by monitoring whether or not the control signal returns to terminal 1 4A within a predetermined time period, i.e. before the counter 36 has overloaded. Bistable 46 checks that the reset signal returns, via terminal 1 8A. If either the control signal or the reset signal does not return, a fault signal is generated, after a delay by delay circuit 47, at terminal 48 which may light an LED or operate an audible warning device (not shown).

Bistable 50 and "AND" gate 52 provide the interrogation control signal at terminal 14 to be delivered to the stations via line 14. Bistable 54 together with gates 56, 57, 58 provides a "RESET" signal via terminal 18 at the start of each interrogation cycle.

The operation of the control circuit 1 will now be explained in more detail.

When the power (Vcc) to control centre 1 is first turned on, capacitor 59 at the input to NAND gate 57 is uncharged, so the output of gate 57 is "high". Once capacitor 59 is charged, the output of gate 57 goes "low". Hence a pulse signal is generated at the output of gate 57 and forms an internal reset pulse at the output of "OR" gate 56.

This resets counter 36, bistables 54, 45 and causes the output of "AND" gate 58 to go "high" generating a "RESET" signal at output terminal 18 which propagates round line 1 8 resetting the first bistables (e.g. 20, 30) of all the input/output stations 2, 3. The internal reset signal also sets bistables 46 and 50. Bistable 46 is reset almost instantaneously as the "RESET" signal reappears at "RESET IN" terminal 1 8A. IF there is a break in the reset line 18 and the "RESET" signal does not reappear at terminal 1 8A then the "high" "Q" output of bistable 46 will causes a fault signal to be generated, via "OR" gate 60, delay circuit 47 and "NAND" gate 62, at terminal 48.

The "Q" output of bistable 50 remains "high" until the next clock pulse so that the"0'' output is a negative-going pulse having a length equal to the clock pulse period. This is applied to gate 52 to generate a positive-going control pulse at terminal 14 (signal "b" in Figure 5).

The interrogation control pulse then propagates sequentially through the stations 2 and 3 along line 14 as explained above with reference to Figures 2 and 3. Counter 36 drives multiplexer 38 through its states, exchanging "information" between each of the terminals 44 in turn and line terminal 42 in time periods appropriate to the station being addressed.

When the interrogation control pulse has propagated through all the stations it arrives back at the control centre at terminal 15A "CONTROL IN" signifying the end of an interrogation cycle. It causes bistable 54 to change state at the next positive going clock pulse, applying a positivegoing pulse pulse from the "Q" output of bistable 54 to an input of "OR" gate 56, causing an internal reset and a "RESET" pulse to be generated again, resetting the whole system and starting the interrogation cycle off again by generating another interrogation control pulse at terminal 14.

If there is a break in the control line 14 then the interrogation control pulse will not return to terminal 14A. The counter 36 will reach its maximum count and generate an "OVERLOAD" signal to deactivate multiplexer 38 via gate 61 and to clock bistable 45, via AND gate 63, to generate a fault signal at terminal 48, via elements 60, 47 and 62. The "OVERLOAD" signal also stops counter 36 via gate 65.

To find out where the break in the circuit has occurred an operator will activate switch 64 which applies a positive-going edge to line 14 via gate 52. This causes the "Q" outputs of all the first bistables of those stations whose control lines 14 are before the break and are still connected to terminal 14 of the control centre 1 , to go "high", lighting all the LED's before the break. Hence the break point is easily determined. It should be noted that a break in the information line is not as serious as a break in the interrogation control and reset lines. A single break will not stop the transfer of information because the information can travel either way round the loop formed by line 16. A double break would stop the transfer of information to/from the stations between the breaks.

To ensure that the multiplexer 38 is properly synchronised to the appropriate time periods for each station, the clock pulse is fed back to the control centre at terminal 1 2A and the "CLOCK OUT" and "CLOCK IN" pulse phases are compared in "exclusive OR" gate 67. This is important as the clock pulses obviously take a finite time to propagate around the ring of stations.

Hence it can be seen that a system as described herein is particularly reliable and has a selfchecking mechanism which provides for simple location of many station or control centre faults.

The system is also very easy to expand as extra stations can be added into the ring in any position without need for fundamental change to the control circuit (so long as the capacity of the multiplexer is not exceeded).

It will be appreciated that alternative equivalent combinations of logic elements to those illustrated and herein described may be used to equal effect.

A control system as herein described is particularly useful for cigarette packing machines but it may also be used to advantage on cigarette handling or making machines or indeed on machines not connected with the cigarette industry.

As a specific example, the control system herein described may be used on the Molins HLP 4 cigarette packaging machine.

In this case input stations will be connected to, for example, a cigarette ends detector, a missing cigarette detector, a foil "run out" detector, a missing bundle detector, a broken packet detector, and a missing long flap detector, amongst others.

Output stations will be connected to control a reject solenoid, a gum flow solenoid, a gum lift solenoid, a main motor brake solenoid, blank reservoir solenoids, and a wrapper link up, amongst others.

Some of the information collected by input stations will be fed to a memory and used to determine the information fed to output stations.

For example if a missing cigarette detector determined that a cigarette was missing, this information would be fed to the appropriate input station. Upon interrogation, that input system would send the missing cigarette information to the control station which would route the information to a memory. The memory would then store the information for an appropriate time, i.e.

until the faulty packet had reached a rejection area. Whence it would send a signal back to the control centre station for passing onto the output station connected to the reject solenoid which would then reject the faulty packet. Obviously extra timing circuits are needed for controlling the memory in the case of some of the operations.

Claims (25)

1. A packaging machine, for packaging cigarettes or other rod-like articles of the cigarette industry, comprising: a plurality of separate machine parts for effecting respective Operations associated with such packaging: a plurality of remote stations respectively connected to some or all of said parts, each station comprising an input station arranged (when interrogated) to receive signals from the respective part signifying the presence of a fault or other special condition, or comprising an output station arranged (when interrogated) to supply a machine control signal to the associated part; a control centre station connected with all the remote stations in cascade, and including means for interrogating the first remote station in the cascade; each station including means for relaying an interrogation signal to the next station so that the remote stations are sequentially interrogated in turn, the system including also an information line for transferring fault and control signals between the remote stations and the control centre station.

2. A packaging machine according to claim 1 wherein the stations are connected in cascade in a ring.

3. A control system comprising: a plurality of stations including a plurality of remote stations and a control station for interrogating the remote stations; connecting means coupling the stations in cascade in a ring; an information line connected to all the stations for transferring information between the control station and each interrogated remote station; the control station including means for generating an interrogation control signal and being arranged to supply the interrogation signal to the first station in the ring; and each station including means for relaying a received interrogation signal, after a delay, to the next station in the ring so that the stations are repeatedly sequentially interrogated during respective essentially non-overlapping time periods.

4. A packaging machine or a control system according to claim 1, 2 or 3 wherein the information line is a closed loop to which each of the stations is connected such that information signals can be transferred between the control station and an interrogated remote station in either one of the two opposite directions round the loop.

5. A packaging machine or a control system according to claims 2, 3 or 4 wherein the control station comprises means for operating a warning device if the interrogation control signal is not received back at the control station within a preset time, thereby to determine line faults in the system.

6. A packaging machine or a control system according to any one of claims 1 to 5 wherein each remote station comprises an indicating device for indicating when a remote station is being interrogated.

7. A packaging machine or control system according to claim 6 when appended to claim 5 wherein the control station comprises means for manually generating a check interrogation control signal which will interrogate all the remote stations between the check signal output and the line fault, to activate the indicating devices of those remote stations.

8. A packaging machine or a control system according to claim 6 or 7 wherein the indicating devices are light emitting diodes.

9. A packaging machine or a control system according to any one of claims 1 to 8 wherein said relaying means of each station comprises a bistable device having its input connected to the output of the bistable device of the previous station, and its output connected to the input of the next station.

10. A packaging machine or a control system according to claim 9 wherein the control centre station comprises means for generating a clock pulse train on a clock line which is connected to all the stations to clock the bistable devices thereof.

11. A packaging machine or control system according to any one of claims 1 to 10 wherein each input station includes a latching circuit arranged for storing a fault, or other special condition, signal when it occurs, so that it can be transmitted to the control station when the remote station is next interrogated.

12. A packaging machine or control system according to claim 11 wherein the latching circuit is a second bistable device.

1 3. A packaging machine or control system according to claim 12 when appended to claim 9 or 10 wherein the second bistable device is arranged to be clocked in synchronism with the output of the first bistable device.

1 4. A control system comprising a control centre station; a plurality of remote stations; a transmission line network interconnecting the control centre station and the remote stations and including a clock line and an information line each common to all the stations, and a control line connecting the stations in cascade so that a control signal from the control centre sequentially enables the stations during successive essentially non-overlapping time periods to communicate with the information line, each station comprising a first bistable device arranged to be clocked from the clock line and a second bistable device arranged to be clocked by the output of the first bistable device for communicating with the information line during the respective time period.

1 5. A control system according to claim 14 wherein at least one remote station has a light emitting indicator device for indicating that that remote station is being interrogated by the control station.

16. A control system according to claim 15 wherein the or each indicating device is a light emitting diode.

1 7. A packaging machine or a control system according to any one of claims 9, 10 or 13 to 1 6 comprising means for resetting all of said first bistable elements at the end of an interrogation cycle.

1 8. A packaging machine or a control system according to claim 1 7 wherein the resetting means comprises a resetting line connected in a loop to which each station is coupled, which loop starts and terminates at the control station and wherein the control station comprises means for sending a resetting signal along the line and for activating a warning device if the resetting signal is not received back at the control station within a predetermined time.

1 9. A packaging machine or a control system according to any one of claims 9 to 1 8 wherein the first and/or the second bistable devices are Dtype bistables.

20. A packaging machine or a control system according to any one of the preceding claims wherein said control centre station comprises a set of input/output ports and multiplexing means arranged for connecting respective input/output ports to their associated remote stations.

21. A packaging machine or a control system according to claim 20 wherein each of said input/output ports has a light emitting device for indicating that a signal has been received from or set to its associated remote station.

22. A control system as claimed in any one of claims 3 to 21 when arranged and used for detecting faults in a plurality of machines or of machine parts.

23. A control system substantially as hereinbefore described with reference to the accompanying drawings.

24. A machine having a control system as claimed in any one of claims 1 to 24.

25. The subject matter of any preceding claim (ignoring any dependency of one claim on another) considered separately or in combination with the subject matter of any one or more of the other claims (again ignoring dependency).