[version en cours de rédaction] | [version en cours de rédaction] |
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The flowline cannot machine anything where the gripper is, or at the very end of the bar. To cope with this, the software looks at each piece to see if there are any operations near the ends – i.e. if this piece was at the end, the operation would be unmachinable. | The flowline cannot machine anything where the gripper is, or at the very end of the bar. To cope with this, the software looks at each piece to see if there are any operations near the ends – i.e. if this piece was at the end, the operation would be unmachinable. | ||
− | * The unmachinable area at the gripper end is defined by the “minable” parameter in sparams.mul | + | *The unmachinable area at the gripper end is defined by the “minable” parameter in sparams.mul |
− | * The area at the end of the bar is defined by the “maxable” parameter. | + | *The area at the end of the bar is defined by the “maxable” parameter. |
This diagram shows the minable and maxable areas on a machine where the gripper is on the left hand side - the position of the gripper could be the other end depending on the feed direction or hand of the machine, and the machine type. '''The minable is always the gripper end''' | This diagram shows the minable and maxable areas on a machine where the gripper is on the left hand side - the position of the gripper could be the other end depending on the feed direction or hand of the machine, and the machine type. '''The minable is always the gripper end''' | ||
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The actual size of the minable and maxable is dependent on the physical distances of the machine. | The actual size of the minable and maxable is dependent on the physical distances of the machine. | ||
− | * minable depends on how big the gripper is | + | *minable depends on how big the gripper is |
− | * maxable depends on the distance from the spindle centreline to the next supporting clamp area | + | *maxable depends on the distance from the spindle centreline to the next supporting clamp area |
− | = Footprint = | + | =Footprint= |
The software also takes account of the footprint of the operation. It checks the X axis movements in a positive and negative direction and checks to see if this footprint would overlap the minable or maxable area | The software also takes account of the footprint of the operation. It checks the X axis movements in a positive and negative direction and checks to see if this footprint would overlap the minable or maxable area | ||
− | = End Prep Modification = | + | =End Prep Modification= |
If there is an operation on a piece that is in the minable / maxable area, the end prep is modified to a “mechanical” prep. | If there is an operation on a piece that is in the minable / maxable area, the end prep is modified to a “mechanical” prep. | ||
{| class="wikitable" border="1" cellspacing="0" cellpadding="0" | {| class="wikitable" border="1" cellspacing="0" cellpadding="0" | ||
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− | = Gaps Calculations and Optimisation = | + | =Gaps Calculations and Optimisation= |
The optimiser uses these end prep symbols during the optimisation process to work out the least wasteful use of the profile. Th actual gap used is defined in a file named gaps.mul or gaps.saw. This is a table of the calculations used for each and every end prep calculation | The optimiser uses these end prep symbols during the optimisation process to work out the least wasteful use of the profile. Th actual gap used is defined in a file named gaps.mul or gaps.saw. This is a table of the calculations used for each and every end prep calculation | ||
On optimisation, the optimiser will determine that there is a large waste associated with putting a “mechanical” prep at the end of a bar, and will therefore try a different combination. If this is not possible (e.g. on a short offcut), the optimiser will allow for the waste at the start or end of the bar. | On optimisation, the optimiser will determine that there is a large waste associated with putting a “mechanical” prep at the end of a bar, and will therefore try a different combination. If this is not possible (e.g. on a short offcut), the optimiser will allow for the waste at the start or end of the bar. | ||
+ | |||
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{{Warning|...Do not change minable or maxable half way through a batch. Always ensure the transfer table is clear of bars and exit both sides of the machine}} | {{Warning|...Do not change minable or maxable half way through a batch. Always ensure the transfer table is clear of bars and exit both sides of the machine}} | ||
− | = Complications = | + | =Complications= |
− | === Gripper Clash with Ring === | + | ===Gripper Clash with Ring=== |
When an operation is close to the gripper, such that the gripper is inside the ring area, there are Y and Z positions on the tootling system that will clash with the gripper. This regularly happens if the V notching heads are required, when the V notching is on the ring, ie flowline, ZX3 and Microline machines whan the Z axis position is at its very maximum. | When an operation is close to the gripper, such that the gripper is inside the ring area, there are Y and Z positions on the tootling system that will clash with the gripper. This regularly happens if the V notching heads are required, when the V notching is on the ring, ie flowline, ZX3 and Microline machines whan the Z axis position is at its very maximum. | ||
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|} | |} | ||
− | === Spindle Assembly Clash with Gripper === | + | ===Spindle Assembly Clash with Gripper=== |
On toothed gripper systems (eg ZX5), the high speed spindle assembly can clash with the gripper end when the tool is at an angle between 90 and 180 degrees, and the profile is narrow. This happens because the mechanism that plunges the spindle is exposed to the area that the gripper wants to be. | On toothed gripper systems (eg ZX5), the high speed spindle assembly can clash with the gripper end when the tool is at an angle between 90 and 180 degrees, and the profile is narrow. This happens because the mechanism that plunges the spindle is exposed to the area that the gripper wants to be. | ||
− | The simple | + | The simple solution to this would be to increase the minable in all situations to a bigger amount. This has been the case on all ZX5s where the gripper is quite small and can work with a minable of 40. |
+ | |||
+ | However, due to this clash problem, the minable has to be set to 140mm. This has had a consequential effect of creating a problem on the saw side. The 140mm minable creates a sizeable offcut on the gripper end of the bar, which is challenging to dispose of - it is too big to go down the chute, but too small to be pushed across to eject as a piece. It cannot be chopped into smaller pieces to go down the chute because the top clamp of the saw cannot clamp it, as the gripper is in the way. This creates a disposal problem - see [https://vimeo.com/476371539/988d93468b Vimeo video] . This is especially a problem on wide door profiles with a mitre, as the large triangle created by the mitre makes the offcut even longer (+width) | ||
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These parameters will modify the minable amount if this situation arises | These parameters will modify the minable amount if this situation arises | ||
if profile width > gripClashProfileWidth and tool angle between gripClashAngleMin and gripClashAngleMax THEN minable=gripClashMinable | if profile width > gripClashProfileWidth and tool angle between gripClashAngleMin and gripClashAngleMax THEN minable=gripClashMinable | ||
− | </translate> | + | This means there only needs to be a large 'minable' offcut when absolutely necessary, avoiding the issue created in the saw. </translate> |
{{PageLang | {{PageLang | ||
|Language=en | |Language=en |
Description and definition of minable and maxable on a Stuga flowline. Why and how this leads to larger trim and waste amounts at the start and end of the bar
Auteur Gareth Green | Dernière modification 2/09/2022 par Gareth Green en cours de rédaction ⧼frevu-button-review-label⧽
Description and definition of minable and maxable on a Stuga flowline. Why and how this leads to larger trim and waste amounts at the start and end of the bar
minable, maxable, optimising, trim Minable_and_Maxable_-_Operations_at_the_ends_of_the_bar_Annotation_2019-09-20_124959.jpg
A major feature of the control software is its ability to optimise a batch for the best use of profile. This is absolutely necessary on the flowline because:
The flowline cannot machine anything where the gripper is, or at the very end of the bar. To cope with this, the software looks at each piece to see if there are any operations near the ends – i.e. if this piece was at the end, the operation would be unmachinable.
This diagram shows the minable and maxable areas on a machine where the gripper is on the left hand side - the position of the gripper could be the other end depending on the feed direction or hand of the machine, and the machine type. The minable is always the gripper end
The actual size of the minable and maxable is dependent on the physical distances of the machine.
The software also takes account of the footprint of the operation. It checks the X axis movements in a positive and negative direction and checks to see if this footprint would overlap the minable or maxable area
If there is an operation on a piece that is in the minable / maxable area, the end prep is modified to a “mechanical” prep.
Square Cut | | | Becomes | s |
Mitre Cut | \ | Becomes | m |
Mitre Cut | / | Becomes | i |
Arrow Head Cut | > | Becomes | a |
Front Y Notch | | | Becomes | f |
Rear Y Notch | | | Becomes | r |
In the above diagram:
1 | \ / | Becomes | m / |
2 | \ / | Becomes | \ / |
3 | \ / | Becomes | \ i |
The optimiser uses these end prep symbols during the optimisation process to work out the least wasteful use of the profile. Th actual gap used is defined in a file named gaps.mul or gaps.saw. This is a table of the calculations used for each and every end prep calculation
On optimisation, the optimiser will determine that there is a large waste associated with putting a “mechanical” prep at the end of a bar, and will therefore try a different combination. If this is not possible (e.g. on a short offcut), the optimiser will allow for the waste at the start or end of the bar.
Result:
The value of minable and maxable is set as parameters in the shared parameters file sparams.saw. To stop or reduce the frequency of bars with minable / maxable waste:
When an operation is close to the gripper, such that the gripper is inside the ring area, there are Y and Z positions on the tootling system that will clash with the gripper. This regularly happens if the V notching heads are required, when the V notching is on the ring, ie flowline, ZX3 and Microline machines whan the Z axis position is at its very maximum.
Two solutions are required for this
Scenario | What is needed | How solved | |
---|---|---|---|
V notch close to gripper end of piece | minable applied even though the V notch is not in minable area | use mrdummy.x command to force a minable end prep modifyer | |
Y notch at gripper end - minable is applied but it is not enough | apply an even bigger minable abount | Use the gaps file f and r end preps to add a bigger minable waste |
On toothed gripper systems (eg ZX5), the high speed spindle assembly can clash with the gripper end when the tool is at an angle between 90 and 180 degrees, and the profile is narrow. This happens because the mechanism that plunges the spindle is exposed to the area that the gripper wants to be.
The simple solution to this would be to increase the minable in all situations to a bigger amount. This has been the case on all ZX5s where the gripper is quite small and can work with a minable of 40.
However, due to this clash problem, the minable has to be set to 140mm. This has had a consequential effect of creating a problem on the saw side. The 140mm minable creates a sizeable offcut on the gripper end of the bar, which is challenging to dispose of - it is too big to go down the chute, but too small to be pushed across to eject as a piece. It cannot be chopped into smaller pieces to go down the chute because the top clamp of the saw cannot clamp it, as the gripper is in the way. This creates a disposal problem - see Vimeo video . This is especially a problem on wide door profiles with a mitre, as the large triangle created by the mitre makes the offcut even longer (+width)
This was solved on version 6.4.54.0 Nov 2020 with the addition of the following parameters
Parameter | Default Value ZX5 |
---|---|
gripClashMinable | 140 |
gripClashAngleMin | 100 |
gripClashAngleMax | 170 |
gripClashProfileWidth | 45 |
These parameters will modify the minable amount if this situation arises
if profile width > gripClashProfileWidth and tool angle between gripClashAngleMin and gripClashAngleMax THEN minable=gripClashMinable
This means there only needs to be a large 'minable' offcut when absolutely necessary, avoiding the issue created in the saw. en none 0
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