Filtration system for collecting and filtering particles and fumes from ablative imaging plates
First Claim
1. A filtration process, comprising the steps of:
- operating a filtration system to filter ablative particles generated by thermal imaging of media;
transmitting a signal representing a current state of the operation of the filtration system; and
generating, responsive to the transmitted signal, at least one of (i) operator information associated with the current state operation and (ii) an instruction to prevent the imaging of the media.
1 Assignment
0 Petitions
Accused Products
Abstract
A filtration system, includes a filtration unit and processor. The filtration unit operates to filter ablative particles generated by thermal imaging of media and transmits a signal corresponding to a parameter, such as a pressure or pressure differential, representing a current state of the operation of the filtration unit, such as the state of the filters, during the filtering of the ablative particles. The processor receives the transmitted signals and generates, responsive to the receipt of the transmitted signal, a signal representing operator information associated with the current state operation, such as a warning or instructions for correcting a deficiency, and/or a signal to stop the imaging of the media.
33 Citations
34 Claims
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1. A filtration process, comprising the steps of:
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operating a filtration system to filter ablative particles generated by thermal imaging of media;
transmitting a signal representing a current state of the operation of the filtration system; and
generating, responsive to the transmitted signal, at least one of (i) operator information associated with the current state operation and (ii) an instruction to prevent the imaging of the media. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10)
sensing one of a pressure related parameter and a power related parameter;
wherein the transmitted signal corresponds to the sensed parameter.
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3. The filtration process of claim 2, wherein:
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the pressure related parameter is a change in pressure exceeding a predetermined threshold value; and
the power related parameter is one of a current and a voltage.
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4. The filtration process of claim 1, wherein:
the represented current state of operation is a current state of a filter.
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5. The filtration process of claim 4, wherein the represented current state of the filter is one of fully saturated, improperly installed and not installed.
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6. The filtration process of claim 1, wherein:
the represented current state of operation is a current state of an air-mover.
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7. The filtration process of claim 6, wherein the represented current state of the air-mover is one of improperly operating and not operating.
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8. The filtration process of claim 1, wherein:
the represented current state of operation is a current state of a filter access door.
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9. The filtration process of claim 8, wherein the represented current state of the filter access door is not properly closed.
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10. The filtration process of claim 1, wherein:
the represented current state of operation is a current state of a physical location of the filtration system.
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11. A filtration process, comprising the steps of:
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filtering ablative particles generated by thermal imaging of media using a plurality of filters;
detecting a parameter representing a current state of said filters using a plurality of first sensors;
providing a movable access door, said access door operable to provide access to at least one of said plurality of filters;
providing a second sensor operable to represent a current state of said access door; and
detecting a parameter representing a current state of said access door using said second sensor. - View Dependent Claims (12, 13, 14, 15, 16, 17)
moving the ablative particles to each of the plurality of filters with an air-mover; and
wherein the parameter detected by one of the plurality of first sensors represents a current state of the air-mover.
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15. The filtration process of claim 11, further comprising:
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moving the ablative particles along a flow path using an air mover; and
illuminating a respective one of a plurality of indicator lights if the parameter detected by a respective one of the plurality of first sensors corresponds to a predefined threshold value.
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16. The filtration process of claim 11, further comprising:
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illuminating each of a plurality of indicator lights if the parameter detected by an associated one of the plurality of first sensors corresponds to a predefined threshold value;
moving the ablative particles along a flow path using an air-mover;
wherein the filtering includes coarse ablative particle filtering, fine ablative particle filtering and odor filtering in series along the flow path;
wherein the parameter representing a current state of the filtering is detected (i) downstream of the coarse ablative particle filtering, (ii) downstream of the fine ablative particle filtering and (iii) downstream of the fine ablative particle filtering and upstream of the air-mover; and
wherein the odor filtering is performed downstream of the air mover.
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17. The filtration process of claim 11, wherein the filtering is performed in a filtration unit, said filtration process further comprising the steps of:
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generating the ablative particles in an imaging unit;
positioning the filtration unit relative to the imaging unit; and
wherein the parameter detected by one of the plurality of first sensors represents the relative positioning of the filtration unit to the imaging unit.
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18. A filtration system, comprising:
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a filtration unit operable to filter ablative particles generated by thermal imaging of media, and configured to transmit a signal corresponding to a parameter representing a current state of the operation of the filtration unit;
a processor configured to receive the transmitted signals and to generate, responsive to the receipt of the transmitted signal, at least one of a first signal representing operator information associated with the current state operation and a second signal to prevent the imaging of the media. - View Dependent Claims (19, 20, 21, 22, 23, 24, 25, 26, 27)
the filtration unit includes a filter; and
the represented current state of operation is a current state of the filter.
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22. The filtration system of claim 21, wherein the represented current state of the filter is one of fully saturated, improperly installed and not installed.
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23. The filtration system of claim 18, wherein:
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the filtration unit includes an air mover; and
the represented current state of operation is a current state of the air-mover.
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24. The filtration system of claim 23, wherein the represented current state of the air-mover is one of improperly operating and not operating.
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25. The filtration system of claim 18, wherein:
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the filtration unit includes a filter access door; and
the represented current state of operation is a current state of the filter access door.
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26. The filtration system of claim 25, wherein the represented current state of the filter access door is not properly closed.
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27. The filtration system of claim 18, wherein the filtration unit includes a sensor for generating the transmitted signal.
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28. A filtration unit, comprising:
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a housing;
a plurality of filters configured to filter ablative particles generated by thermal imaging of media and positioned within the housing;
a plurality of first sensors positioned within said housing, each one of said plurality of first sensors configured to detect a parameter representing a current state of a respective one of said plurality of filters;
an air-mover configured to move the ablative particles to each of said plurality of filters, said air-mover positioned within said housing; and
a second sensor positioned within said housing, said second sensor configured to detect a parameter representing a current state of said air-mover. - View Dependent Claims (29, 30, 31, 32, 33, 34)
a plurality of indicator lights, each configured to illuminate if the parameter detected by a respective one of the plurality of first sensors corresponds to a predefined threshold value.
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30. The filtration unit of claim 29, wherein the illumination of each of the plurality of indicator lights represents one of saturation and non-installation of a respective one of the filters.
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31. The filtration unit of claim 28, further comprising:
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a plurality of indicator lights; and
wherein each of said plurality of indicator lights is configured to illuminate if the parameter detected by a respective one of said plurality of first sensors or said second sensor corresponds to a predefined threshold value.
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32. The filtration unit of claim 28, further comprising:
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a filter clamp; and
a third sensor positioned within said housing, said third sensor configured to detect a parameter representing a current state of the filter clamp.
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33. The filtration unit of claim 28, further comprising:
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an access door movable to provide access to one of the plurality of filters; and
a third sensor positioned within said housing, said third sensor configured to detect a parameter representing a current state of the access door.
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34. The filtration unit of claim 28, further comprising:
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a plurality of indicator lights attached to an outer surface of said housing, each of said plurality of indicator lights configured to illuminate if the parameter detected by a respective one of the plurality of first sensors corresponds to a predefined threshold value;
wherein the plurality of filters include a coarse ablative particle filter, a fine ablative particle filter and an adsorbent cell disposed in series along the flow path;
wherein the plurality of first sensors includes a third sensor disposed downstream of the coarse ablative particle filter, a fourth sensor disposed downstream of the fine ablative particle filter; and
wherein said second sensor is disposed upstream of the air-mover and downstream of the fine ablative particle filter.
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Specification