Braiding machine

Abstract

The present invention provides a means for shutting down a braiding machine to prevent damage to a product to which the braided yarn is applied under failure conditions such as when a yarn breaks. Failure of the yarn or the tensioning of the yarn causes an imbalance in the tensioning on the product causing it to be displaced from its normal position and this displacement is detected to shut the braiding machine down.

Claims

1. A control system for a braiding machine arranged for applying a braided yarn sheath to a substrate, the control system comprising: a detector including a die having an orifice through which said substrate is arranged to pass and wherein deviation of said substrate from a predetermined path causes said substrate to engage and apply a load to said die, said load being detected by said detector; and a controller arranged to output a stop signal for stopping said braiding machine in response to said detected load.

2. A control system according to claim 1 wherein said controller is arranged to output said stop signal when said load exceeds a first threshold.

3. A control system according to claim 2 wherein said controller monitors said load for a period of time during normal operation to determine said first threshold.

4. A control system according to claim 2 wherein said controller is arranged to output a warning signal when said load exceeds a second threshold.

5. A control system according to claim 4 wherein said controller is arranged to output a stop signal to said braiding machine when said load exceeds said second threshold for a predetermined period of time.

6. A control system according to claim 3 wherein said controller is arranged to output a warning signal when said load exceeds a second threshold.

7. A control system according to claim 6 wherein said controller is arranged to output a stop signal to said braiding machine when said load exceeds said second threshold for a predetermined period of time.

8. A control system according to claim 1 wherein said detector further comprises one or more load cells engaged with said die to detect said load applied to said die by said deviation of said substrate.

9. A method for controlling a braiding machine arranged for applying a braided yarn sheath to a substrate, the method comprising: passing said substrate through an orifice in a die such that deviation of said substrate from a predetermined path causes said substrate to engage and apply a load to said die; detecting said load due to said deviation of said substrate from said predetermined path; and outputting a stop signal for stopping said braiding machine in response to said detected load.

10. A method according to claim 9, further comprising outputting said stop signal to said braiding machine when said load exceeds a first threshold.

11. A method according to claim 10, further comprising monitoring the detected load for a period of time during normal operation to determine said first threshold.

12. A method according to claim 10, further comprising outputting a warning signal when said detected load exceeds a second threshold.

13. A method according to claim 12, further comprising outputting a stop signal to said braiding machine when said detected load exceeds said second threshold for a predetermined period of time.

14. A method according to claim 11, further comprising outputting a warning signal when said detected load exceeds a second threshold.

15. A method according to claim 14, further comprising outputting a stop signal to said braiding machine when said detected load exceeds said second threshold for a predetermined period of time.

16. A method according to claim 9, wherein one or more load cells are engaged with said die to detect said load applied to said die by said deviation of said substrate and wherein said detecting of said load comprises measuring the respective loads in at least one of said load cells.

17. A braiding machine for applying a braided yarn sheath to a substrate having a control system, comprising: a detector including a die having an orifice through which said substrate is arranged to pass and wherein deviation of said substrate from a predetermined path causes said substrate to engage and apply a load to said die, said load being detected by said detector; and a controller arranged to output a stop signal for stopping said braiding machine in response to said detected load.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) A preferred embodiment of the present invention will now be more particularly described by way of example only with reference to the accompanying drawings, wherein:

(2) FIG. 1 shows schematically the pathways followed by bobbins on a braiding machine;

(3) FIG. 2 shows the basic structure of a braiding process;

(4) FIG. 3 shows a more detailed view of a braiding machine;

(5) FIG. 4a shows the tensioning of the braiding around a braiding point;

(6) FIG. 4b shows the displacement effect of a broken yarn;

(7) FIG. 5a shows the load cell of the present invention arranged around the substrate under normal conditions;

(8) FIG. 5b shows the present invention under failure conditions; and

(9) FIG. 6 shows a detailed view of the detector of the invention.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

(10) FIG. 5a shows the arrangement of the yarns and substrate near the braiding point 25, the yarns are formed into the braid around the substrate. In this embodiment of the invention, a detector 50 is provided. The detector 50 includes a die 51 which includes an orifice 60 through which the substrate 21 is fed towards the braiding point 25. The die is selected so that the orifice through it can receive the substrate 21 with a small amount of clearance such that as the substrate is fed through it, it can run substantially freely without the die interfering with the passage of the substrate through it.

(11) The die is supported by a number of load cells 52, in this embodiment arranged circumferentially around the outside of the die. The load cells 52 are designed to detect the load applied to them by the die. The load cells are attached to the body of the machine and the die is supported between them.

(12) FIG. 6 shows an end view of the die 51 with the four load cells 52 arranged around it. Although it is not shown in FIGS. 5 and 6, the load cells are mounted on the body of the braiding machine or some other suitable mounting bracket. In this way, the die is suspended by the load cells. Any force applied to the die is therefore transferred to the load cells.

(13) Under normal operating conditions, the substrate 21 would pass through the orifice in the die 51 and the load on the load cells 52 will remain substantially constant. Each load cell 52 is independent and records the load applied which is used to provide an indication of the deflection of the substrate.

(14) However, if one of the yarns breaks, as in the example of FIG. 4b, or some other failure event occurs such as the yarns becoming snagged or one of the clutch mechanisms providing the tension to the yarns failing, the tension on the yarns will become imbalanced. As indicated above, this will cause the substrate 21 to be displaced away from its normal axis of travel. As shown in FIG. 5b, substrate 21 is pushed against the side of the die applying a force to it. This force will in turn be transferred to the load cells, varying the load detected by the load cells. The load measured by the load cells is passed to a controller (not shown) which monitors the detected loads. As the detected loads move outside of an acceptable tolerance, eventually a failure mode is identified and remedial action can be taken to stop the braiding machine and prevent damage to the substrate or the braided product.

(15) The controller may be designed to determine that a failure has occurred when the load variance exceeds a threshold. This would allow minor variations to be ignored as normal operational variations. The braiding process is a complex mechanical process with a large number of moving parts and with yarn and substrate material which will have some minor imperfections. This will lead to some limited movement of the substrate under normal operation. This movement may apply a small but measurable force to the die 51 which in turn will affect the forces measured by the load cells 52. By setting the threshold above appropriately, such normal variations can be ignored and only when the loads experience by the load cells exceed the threshold will action need to be taken.

(16) At the start of a production run, the load in the load cells can be measured. This measured load will represent the variance due to a small amount of deflection difference between load cells. Once the maximum and minimum deflection has been identified, these can then be used to determine a tolerance to work to. This tolerance can then be used to define the threshold referred to above. This may be done manually by displaying the measured load or displacement on a display and allowing the operator to set the required threshold value, or it may be automated.

(17) As the bobbins are rotating at high speed, a broken yarn will cause the direction of the imbalance in the tension to rotate and so the effective displacing force on the substrate will also appear to rotate. Furthermore the yarn could break at any point on the cycle and so initial displacement of the die could be in any direction. Using the four load cells 52 shown in FIG. 6, displacement in any direction will affect at least one of the four load cells 52. In this way, regardless of where the yarn breaks, the displacement of the substrate will be detected by at least one of the load cells, if not all.

(18) It will be appreciated that a different number of more or less load cells could be used and still be able to detect the displacement of the die and hence the substrate.

(19) Once the controller has detected sufficient displacement of the substrate to determine that a significant fault has occurred, the braiding machine can be shut down. The shutting down of the machine will occur substantially faster than relying on an operator to detect a fault visually or any existing mechanisms to detect a catastrophic failure. For example, some braiding machines are provided with a loop catcher that can detect slack loops in the product. If a yarn does become slack, the loose material is caught on a spike in a die. Once caught, this pulls the die displacing it from its normal position which breaks a circuit causing the machine to stop.

(20) Such mechanisms only operate when a yarn becomes slack and typically do not respond quickly enough to prevent damage to the workpiece and so generally do not solve the problem of having to restart the entire job. Some machine have no method of detecting faults and simply rely on an operator to spot a problem and manually shut the machine down. Relying on the operator is again too slow to stop the machine before irreparable damage has occurred.

(21) By shutting down the machine rapidly, the potential damage caused by running the machine with yarn tensions unbalanced may be avoided or at least the duration minimised. This should ensure that the machine is shut down before any significant damage to the substrate occurs. In this way, the yarn may be reattached or repaired and the braiding operation restarted and the product already produced saved from being wasted.

(22) In the above-described situation, a yarn breaking will cause a significant imbalance in the tensioning at the braiding point 25. However, as indicated above, each bobbin includes its own tensioning system and these systems may also fail either completely or partially. For example, if one of the tensioning mechanisms on one of the bobbins fails such that it does not apply the correct tension to the yarn extending from it, then this may initially not adversely affect the braiding operation and have no damaging effect on the substrate or the finished product. However, a small imbalance caused by incorrect tensioning may still lead the substrate to deflect and engage the die 51.

(23) If the tension is only slightly out of tolerance then the displacement may be relatively small compared to a complete failure of a yarn and the change in the load on the load cells 52 may not be as large. The value of the load at which shut down occurs may be selected at a first threshold level but between that level and a lower second threshold level of the measured load, the machine is not shut down but a warning state is set to indicate that at least one of the bobbin tensions is not at its optimum value. The operator may then determine whether or not to shut down the machine and rectify the problem.

(24) In this way, minor imbalances of tension can be detected without causing a full shut down of the machine while still providing protection against a substantial catastrophic failure in the braiding operation. Such minor imbalances may be tolerated for a significant period of time so that the current run can be completed and the problem rectified when the machine is shut down, for example to replenish the bobbins etc.

(25) By selecting suitable tolerance levels, the operator can set values for when the machine shuts down automatically under a fault condition or when it simply provides a warning. Again, the controller may have further intelligent controls such that above a certain tolerance the machine will always shut down but below that level and above a lower level, the machine continues to operate in an out of tolerance condition. The machine controller may determine that this out of tolerance condition may continue for a limited period of time before shutting the machine down.

(26) Whilst the embodiment above utilises load cells to measure the movement of the substrate from the central position, other methods of detecting the displacement may be used. For example, the dye may be arranged so that it can be displaced against a resilient mounting such by mounting it on springs. This displacement may then be measured using known methods such as optically, mechanically, acoustically etc.

(27) Furthermore, the die may be dispensed with completely and the position of the substrate monitored. For example, a beam of light may be shone across the path of the substrate and the amount of transmitted light either side of the substrate measured with variations in the amount of light indicating displacement form the neutral position. This may be duplicated at different angles to measure displacement in different directions. Yet further methods could also be used and it is not intend that the invention be limited to the embodiment described above.