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| United States Patent | 5874049 |
| Link to this page | http://www.wikipatents.com/5874049.html |
| Inventor(s) | Ferri, Jr.; Edward T. (Gilroy, CA);
Geatz; J. Tobin (Wilmington, NC);
Green; Randall L. (Watsonville, CA) |
| Abstract | A chemical mixing system for mixing ingredients at desired concentrations
concentration within a qualification range. Batches of the mixed chemical
are mixed in a relatively small mix vessel and transferred to a relatively
large mix drum. The concentration of the chemical within the mix drum is
measured by a concentration monitor. If the measured concentration of the
chemical in the mix drum is within the qualification range, the batches of
chemical in the mix vessel are mixed to the desired concentration. If the
measured concentration of the chemical in the mix drum is below the
qualification range, the batches of chemical in the mix vessel are mixed
to a high concentration which is greater than the desired concentration.
If the measured concentration of the chemical in the mix drum is above the
qualification range, the batches of chemical in the mix vessel are mixed
to a low concentration which is less than the desired concentration. Batch
averaging is thereby performed to maintain the concentration of chemical
in the mix drum within the desired qualification range. |
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Title Information  |
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| Publication Date |
February 23, 1999 |
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| Filing Date |
January 23, 1997 |
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| Parent Case |
The present application is a continuation of application Ser. No.
08/554,787, filed Nov. 7, 1995. |
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Title Information |
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References |
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U.S. References |
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| Market Size |
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Market Review |
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Technical Review |
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Claims |
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What is claimed is:
1. A chemical mixing system for controlling a concentration of a chemical
species in an admixture such that the concentration of the chemical
species is maintained within a defined qualification range, said chemical
mixing system comprising:
(a) a mix vessel having an internal volume suitable for preparing a batch
from ingredients comprising a diluent and a concentrated solution
containing a relatively high concentration of the chemical species
relative to the qualification range, wherein the mix vessel is adapted to
receive the concentrated solution and the diluent from first and second
supply sources, respectively;
(b) a mix drum having an internal volume for holding a supply of the
admixture, wherein the internal volume of the mix drum is of a size
sufficient for holding a plurality of batches prepared in the mix vessel,
and wherein the mix drum is coupled to the mix vessel so that one or more
batches prepared in the mix vessel can be transported to the internal
volume of the mix drum in order to replenish the supply of, and
controllably adjust the concentration of the chemical species in, the
admixture; and
(c) a control system responsive to information comprising a measured
concentration of the chemical species in the admixture, wherein said
control system is capable of generating control signals for controlling
the amounts of the concentrated solution and the diluent which are
combined in the mix vessel when a batch is prepared so that the prepared
batch comprises a corrective concentration of the chemical species
relative to the measured concentration of the chemical species in the
admixture.
2. The chemical mixing system of claim 1, wherein the control signals are
valve control signals and the system further comprises a plurality of
control valves disposed in the chemical mixing system at positions
effective for regulating the amount of the concentrated solution and the
diluent added to the mix vessel from the first and second supply sources,
respectively, wherein the control valves are actuated in response to
information comprising the valve control signals generated by the control
system.
3. The chemical mixing system of claim 1, wherein the control system
further comprises a plurality of sensors disposed on the system at
positions effective to generate sensor signals representative of the
respective amounts of the concentrated solution and diluent which are
added to the internal volume of the mix vessel, and wherein the control
system is responsive to information comprising both the measured
concentration and the sensor signals.
4. The chemical mixing system of claim 3, wherein the plurality of sensors
comprises:
(a) a first sensor disposed on the system at a position effective for
detecting when a defined amount of one of the concentrated solution and
the diluent is added to the mix vessel;
(b) a second sensor disposed on the system at a position effective for
detecting when a combined amount of the concentrated solution and the
diluent in the mix vessel is effective to provide a batch having a
corrective concentration of the chemical species which is within the
qualification range;
(c) a third sensor disposed on the system at a position effective for
detecting when a combined amount of the concentrated solution and the
diluent in the mix vessel is effective to provide a batch having a
corrective concentration of the chemical species which is less than the
qualification range; and
a fourth sensor disposed on the system at a position effective for
detecting when a combined amount of the concentrated solution and the
diluent in the mix vessel is effective to provide a batch having a
corrective concentration of the chemical species which is greater than the
qualification range.
5. The chemical mixing system of claim 3, wherein the sensors are disposed
on the mix vessel.
6. The chemical mixing system of claim 1, wherein the ratio of the mix
vessel internal volume to the mix drum internal volume is about 1:10.
7. The chemical mixing system of claim 1, wherein the mix vessel and the
mix drum each comprise a corrosion resistant material selected from the
group consisting of an ultra high molecular weight polyethylene and a
perfluoroalkoxy material.
8. The chemical mixing system of claim 1, wherein the concentrated solution
is a concentrated aqueous HF solution and the diluent is ultra pure water.
9. The chemical mixing system of claim 1, wherein the mix drum further
comprises:
(a) a low level sensor disposed at a low volume level, said low level
sensor capable of generating a low level sensor signal indicative of when
the supply of admixture in the drum corresponds to the low volume level;
and
(b) a high level sensor disposed at a high volume level, said high level
sensor capable of generating high level sensor signals indicative of when
the supply of the admixture in the drum corresponds to the high volume
level; and
wherein the control system is responsive to such low and high level sensor
signals such that the control system causes batchwise replenishment and
chemical species concentration control of the admixture supply when the
low level sensor generates a signal indicating that the volume level of
the supply admixture in the mix drum corresponds to the low volume level
and such that the control system stops such batchwise replenishment and
chemical species concentration control when the high level sensor
generates a signal indicating that the volume of the admixture supply in
the mix drum corresponds to the high volume level.
10. The chemical mixing system of claim 1, wherein the chemical mixing
system further comprises a plurality of pressure vacuum vessels for
motivating the concentrated solution and the diluent through at least a
portion of the system.
11. The chemical mixing system of claim 1 further comprising:
(a) an exit line for transmitting the admixture from the mix drum to a
point of use; and
(b) a conductivity probe disposed on said exit line for measuring said
measured concentration of the chemical species in the admixture.
12. The chemical mixing system of claim 3, wherein said plurality of
sensors comprises:
(a) a first sensor disposed on the mix vessel at a level corresponding to a
predefined amount of diluent;
(b) a second sensor disposed on the mix vessel at a level higher than the
first sensor by an amount which corresponds approximately to a
concentrated solution volume that will yield a batch having a chemical
species concentration within the qualification range;
(c) a third sensor disposed on the mix vessel at a level higher than the
first sensor, but lower than the second sensor, to approximately
correspond to a concentrated solution volume that will provide a batch
having a chemical species concentration which is less than the
qualification range; and
(d) a fourth sensor disposed on the mix vessel at a level higher than the
second sensor at a position which corresponds approximately to a
concentrated solution volume that will yield a batch having a chemical
species concentration which is greater than the qualification range.
13. A process for controlling an amount of a chemical species in an
admixture, comprising the steps of:
(a) providing a supply of the admixture, wherein the admixture comprises a
concentration of the chemical species;
(b) measuring the concentration of the chemical species in the admixture;
(c) determining if the measured concentration is within a defined
qualification range;
(d) preparing a batch comprising a corrective concentration of the chemical
species relative to the measured concentration of the chemical species in
the admixture, wherein the step of preparing the batch comprises the steps
of:
(i) providing ingredients comprising a concentrated solution and a diluent,
wherein the concentrated solution contains a relatively high concentration
of the chemical species relative to the qualification range;
(ii) providing a mix vessel having an internal volume suitable for
preparing the batch, wherein the mix vessel is adapted to receive the
concentrated solution and the diluent from first and second supply
sources, respectively, and wherein the system is provided with a plurality
of sensors capable of generating sensor signals representative of the
respective amounts of the concentrated solution and the diluent which are
added to the internal volume of the mix vessel; and
(iii) adding amounts of said ingredients to the mix vessel effective to
provide the batch with the corrective concentration of the chemical
species, wherein the amount of said ingredients added to the mix vessel is
controlled in response to information comprising the sensor signals and to
the measured concentration of the chemical species in the admixture; and
(e) combining the batch with the admixture supply in order to controllably
adjust the concentration of the chemical species in the admixture.
14. The process of claim 13, wherein at least a portion of the admixture
supply is provided in a mix drum having an internal volume for holding
said portion of the admixture, and wherein a mix drum conduit assembly is
coupled to the mix drum, said mix drum conduit assembly including (i) a
line for transporting the admixture from the mix drum to a point of use
and (ii) a recirculation line for transporting the admixture to and from
the mix drum.
15. The process of claim 14, wherein the step of measuring the
concentration of the chemical species in the admixture comprises measuring
said concentration from a portion of the admixture which is being
transported through said mix drum conduit assembly.
16. The process of claim 14, wherein the internal volume of the mix vessel
is less than the internal volume of the mix drum, and wherein the mix
vessel is coupled to the mix drum by a conduit for transmitting batches
from the mix vessel to the mix drum.
17. The process of claim 16, wherein the ratio of the internal volume of
the mix vessel to the internal volume of the mix drum is about 1:10.
18. The process of claim 13, wherein the plurality of sensors comprises:
(a) a first sensor disposed on the system at a position effective for
detecting when a defined amount of one of the concentrated solution and
the diluent is added to the mix vessel;
(b) a second sensor disposed on the system at a position effective for
detecting when a combined amount of the concentrated solution and the
diluent in the mix vessel is effective to provide a batch having a
corrective concentration of the chemical species which is within the
qualification range;
(c) a third sensor disposed on the system at a position effective for
detecting when a combined amount of the concentrated solution and the
diluent in the mix vessel is effective to provide a batch having a
corrective concentration of the chemical species which is less than the
qualification range; and
(d) a fourth sensor disposed on the system at a position effective for
detecting when a combined amount of the concentrated solution and the
diluent in the mix vessel is effective to provide a batch having a
corrective concentration of the chemical species which is greater than the
qualification range.
19. The process of claim 16, wherein the chemical constituent sensors are
disposed on the mix vessel.
20. The process of claim 13, wherein said plurality of sensors comprises:
(a) a first sensor disposed on the mix vessel at a level corresponding to a
predefined amount of diluent;
(b) a second sensor disposed on the mix vessel at a level higher than the
first sensor by an amount which corresponds approximately to a
concentrated solution volume that will yield a batch having a chemical
species concentration within the qualification range;
(c) a third sensor disposed on the mix vessel at a level higher than the
first sensor, but lower than the second sensor, to approximately
correspond to a concentrated solution volume that will provide a batch
having a chemical species concentration which is less than the
qualification range; and
(d) a fourth sensor disposed on the mix vessel at a level higher than the
second sensor at a position which corresponds approximately to a
concentrated solution volume that will yield a batch having a chemical
species concentration which is greater than the qualification range.
21. The process of claim 16, wherein the mix vessel and the mix drum each
comprise a corrosion resistant material selected from the group consisting
of an ultra high molecular weight polyethylene and a perfluoroalkoxy
material.
22. The process of claim 13, wherein the concentrated solution is a
concentrated aqueous HF solution and the diluent is ultra pure water.
23. The process of claim 13, wherein the mix drum further comprises:
(a) a low level sensor disposed at a low volume level, said low level
sensor capable of generating a low level sensor signal indicative of when
the supply of admixture in the mix drum corresponds to the low volume
level; and
(b) a high level sensor disposed at a high volume level, said high level
sensor capable of generating high level sensor signals indicative of when
the supply of the admixture in the mix drum corresponds to the high volume
level; and
wherein the method further comprises providing a control system responsive
to such low and high level sensor signals such that the control system
causes batchwise replenishment and chemical species concentration control
of the admixture supply when the low level sensor generates a signal
indicating that the volume level of the supply admixture in the mix drum
corresponds to the low volume level and stops such batchwise replenishment
and chemical species concentration control when the high level sensor
generates a signal indicating that the volume of the admixture in the mix
drum corresponds to the high volume level.
24. The process of claim 16, further comprising the steps of:
(a) transporting respective volumes of the concentrated solution and the
diluent into the mix vessel in order to prepare the batch having a
corrective concentration of the chemical species;
(b) transporting the batch from the mix vessel to the mix drum; and
(c) transporting the admixture from the mix drum to a point of use;
wherein said transporting steps are caused by a plurality of pressure
vacuum vessels.
25. A process for controlling an amount of a chemical species in an
admixture, comprising the steps of:
(a) providing a supply of the admixture, wherein the admixture comprises a
concentration of the chemical species;
(b) measuring the concentration of the chemical species in the admixture;
(c) determining if the measured concentration is within a defined
qualification range; and
(d) batchwise adjusting the concentration of the chemical species in the
admixture in response to the measured concentration of the chemical
species in the admixture, said batchwise adjusting step comprising the
steps of:
(i) providing a concentrated solution having a high concentration of the
chemical species relative to the qualification range;
(ii) providing a diluent;
(iii) providing a control system responsive to information comprising the
measured concentration of the chemical species in the admixture, wherein
said control system is capable of generating control signals for
controlling respective amounts of the concentrated solution and the
diluent in order to provide a batch having a corrective concentration of
the chemical species relative to the measured concentration of the
chemical species in the admixture; and
(iv) using information comprising the control signals to controllably
dilute the concentrated solution with an amount of the diluent effective
to provide said batch having a corrective concentration of the chemical
species relative to the measured concentration of the chemical species in
the admixture; and
(v) combining the batch with the supply of the admixture.
26. The process of claim 25, wherein at least a portion of the admixture
supply is provided in a mix drum having an internal volume for holding
said portion of the admixture, and wherein a mix drum conduit assembly is
coupled to the mix drum, said mix drum conduit assembly including (i) a
line for transporting the admixture from the mix drum to a point of use
and (ii) a recirculation line.
27. The process of claim 26, wherein the step of measuring the
concentration of the chemical species in the admixture comprises measuring
said concentration from a portion of the admixture which is being
transported through said mix drum conduit assembly.
28. The process of claim 26, wherein the batch is prepared in a mix vessel
having an internal volume, wherein the internal volume of mix vessel is
less than the internal volume of the mix drum, and wherein the mix vessel
is coupled to the mix drum by a conduit for transmitting batches from the
mix vessel to the mix drum.
29. The process of claim 26, wherein the ratio of the internal volume of
the mix vessel to the internal volume of the mix drum is about 1:10.
30. The process of claim 28, further comprising the step of providing a
plurality of sensors disposed on the mix vessel at positions effective to
generate sensor signals representative of the respective amounts of the
concentrated solution and diluent which are added to the internal volume
of the mix vessel, and wherein the control system is responsive to
information comprising both the measured concentration and the sensor
signals for controlling the amounts of the concentrated solution and
diluent which are combined to form the batch.
31. The process of claim 30, wherein the plurality of sensors comprises:
(a) a first sensor disposed on the mix vessel at a position effective for
detecting when a defined amount of one of the concentrated solution and
the diluent is added to the mix vessel;
(b) a second sensor disposed on the mix vessel at a position effective for
detecting when a combined amount of the concentrated solution and the
diluent in the mix vessel is effective to provide a batch having a
corrective concentration of the chemical species which is within the
qualification range;
(c) a third sensor disposed on the mix vessel at a position effective for
detecting when a combined amount of the concentrated solution and the
diluent in the mix vessel is effective to provide a batch having a
corrective concentration of the chemical species which is less than the
qualification range; and
(d) a fourth sensor disposed on the mix vessel at a position effective for
detecting when a combined amount of the concentrated solution and the
diluent in the mix vessel is effective to provide a batch having a
corrective concentration of the chemical species which is greater than the
qualification range.
32. The chemical mixing system of claim 3, wherein said plurality of
sensors comprises:
(a) a first sensor disposed on the mix vessel at a level corresponding to a
predefined amount of diluent;
(b) a second sensor disposed on the mix vessel at a level higher than the
first sensor by an amount which corresponds approximately to a
concentrated solution volume that will yield a batch having a chemical
species concentration within the qualification range;
(c) a third sensor disposed on the mix vessel at a level higher than the
first sensor, but lower than the second sensor, to approximately
correspond to a concentrated solution volume that will provide a batch
having a chemical species concentration which is less than the
qualification range; and
(d) a fourth sensor disposed on the mix vessel at a level higher than the
second sensor at a position which corresponds approximately to a
concentrated solution volume that will yield a batch having a chemical
species concentration which is greater than the qualification range.
33. The process of claim 28, wherein the mix vessel and the mix drum each
comprise a corrosion resistant material selected from the group consisting
of an ultra high molecular weight polyethylene and a perfluoroalkoxy
material.
34. The process of claim 25, wherein the concentrated solution is a
concentrated aqueous HF solution and the diluent is ultra pure water.
35. The process of claim 26, wherein the mix drum further comprises:
(a) a low level sensor disposed at a low volume level, said low level
sensor capable of generating a low level sensor signal indicative of when
the supply of admixture in the drum corresponds to the low volume level;
and
(b) a high level sensor disposed at a high volume level, said high level
sensor capable of generating high level sensor signals indicative of when
the supply of the admixture in the drum corresponds to the high volume
level; and
wherein the control system is responsive to such low and high level sensor
signals such that the control system causes batchwise replenishment and
chemical species concentration control of the admixture supply when the
low level sensor generates a signal indicating that the volume level of
the supply admixture in the mix drum corresponds to the low volume level
and stops such batchwise replenishment and chemical species concentration
control when the high level sensor generates a signal indicating that the
volume of the admixture in the mix drum corresponds to the high volume
level. |
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Claims |
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Description |
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FIELD OF THE INVENTION
The present invention is a chemical blending or mixing system. In
particular, the invention is a system for mixing concentrated chemicals
from two or more chemical components for subsequent use in semiconductor
fabrication facilities.
BACKGROUND OF THE INVENTION
Chemical generation or mixing systems are used in a variety of industrial
applications to blend two or more components or constituents to a desired
concentration. In semiconductor fabrication facilities, for example,
concentrated chemicals (which are usually provided by commercial chemical
suppliers in solution with water) are commonly mixed or diluted with DI
(deionized or ultra pure) water before being sprayed on or otherwise
applied to semiconductor wafers. Table 1 below lists a number of chemicals
used in semiconductor fabrication facilities, and the concentration (in
weight %) in which these chemicals are typically provided by suppliers.
TABLE 1
______________________________________
Percentage
Concentrate
Chemical Symbol in Water
______________________________________
Hydrofluoric Acid HF 49%
Acetic Acid HAC 99.7%
Nitric Acid HNO.sub.3 71%
Phosphoric Acid H.sub.3 PO.sub.4
80%
Potassium Hydroxide
KOH 30%
Tetramethyl Ammonium
TMAH 25%
Hydroxide
Hydrochloric Acid HCl 37%
HF and Ammonium BOEs --
Fluoride Mixtures
Ammonium Hydroxide
NH.sub.4 OH
28-30%
Sulfuric Acid H.sub.2 SO.sub.4
93-98%
______________________________________
When used in semiconductor fabrication facilities, the concentrated
chemicals described above are commonly diluted with DI water (i.e., a
diluent) to desired concentrations or assays. Concentrations in these
applications are typically described in terms of weight % (weight percent)
of concentrated or pure chemical in water. Hydrofluoric Acid (HF), for
example, is often diluted with ultra pure water to concentrations ranging
from about 0.5%-5% HF by weight when used for etching and cleaning
processes. Tetramethyl Ammonium Hydroxide (TMAH) is often diluted to about
2.38 weight % for use as a positive photoresist developer. Non-aqueous
blended chemicals, and blended chemicals with three or more components,
can also be generated.
Chemical mixing systems blend the chemicals to a desired concentration
which is sometimes known as the nominal or qualification concentration. A
high degree of accuracy is also required. The range or window of
acceptable concentrations surrounding the qualification concentration is
known as the qualification range, and can be defined as a weight % error
with respect to the qualification concentration, or by upper and lower
qualification range concentrations. Chemical blending systems of the type
described above are commercially available from a number of sources
including FSI International of Chaska, Minn. and Applied Chemical
Solutions of Hollister, Calif.. They are also disclosed generally in the
Geatz U.S. Pat. No. 5,148,945 and the Ferri, Jr. et al. U.S. Pat. No.
5,330,072.
There remains, however, a continuing need for improved chemical blending
systems. In particular, there is a need for chemical blending systems
capable of quickly blending batches of chemical to a very high degree of
accuracy. To be commercially viable, the chemical blending systems must
also be highly reliable.
SUMMARY OF THE INVENTION
The present invention is a chemical mixing system capable of quickly and
accurately blending chemicals. One embodiment of the system is configured
for controlling a concentration of a chemical species in an admixture such
that the concentration of the chemical species is maintained within a
defined qualification range. The system includes a mix vessel having an
internal volume suitable for preparing a batch from ingredients comprising
a diluent and a concentrated solution containing a relatively high
concentration of the chemical species relative to the qualification range.
The mix vessel is adapted to receive the concentrated solution and the
diluent from first and second supply sources, respectively. The system
further includes a mix drum having an internal volume for holding a supply
of the admixture. The internal volume of the mix drum is of a size
sufficient for holding a plurality of batches prepared in the mix vessel.
The mix drum is coupled to the mix vessel so that one or more batches
prepared in the mix vessel can be transported to the internal volume of
the mix drum in order to replenish the supply of, and controllably adjust
the concentration of the first chemical species in, the chemical
admixture. The system further includes a control system responsive to
information comprising a measured concentration of the chemical species in
the admixture. The control system is capable of generating control signals
for controlling the amounts of the concentrated solution and | | |
