U.S. patent application number 15/620878 was filed with the patent office on 2017-09-28 for wet abrasive blasting system with self-venting assembly.
This patent application is currently assigned to Graco Minnesota Inc.. The applicant listed for this patent is Graco Minnesota Inc.. Invention is credited to Keith Eliason.
Application Number | 20170274501 15/620878 |
Document ID | / |
Family ID | 47881090 |
Filed Date | 2017-09-28 |
United States Patent
Application |
20170274501 |
Kind Code |
A1 |
Eliason; Keith |
September 28, 2017 |
Wet Abrasive Blasting System with Self-Venting Assembly
Abstract
The invention is directed toward wet-abrasive blasting systems
used for cleaning, preparing surfaces, removing coatings, and other
abrasive blasting applications. The wet abrasive basting system has
a blast pot that includes a venting system. The venting system may
be a self-venting system that allows gases to be vented during
charging and prevents gases from accumulating in the blast pot
during operation. In wet abrasive blasting systems a slurry is
conveyed via a piping system, hoses, etc. to a mixer connected to a
source of pressurized gas where slurry and compressed air/gas are
combined and directed through the blast hose and blast nozzle.
Inventors: |
Eliason; Keith; (Virginia
Beach, VA) |
|
Applicant: |
Name |
City |
State |
Country |
Type |
Graco Minnesota Inc. |
Minneapolis |
MN |
US |
|
|
Assignee: |
Graco Minnesota Inc.
Minneapolis
MN
|
Family ID: |
47881090 |
Appl. No.: |
15/620878 |
Filed: |
June 13, 2017 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
|
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13234478 |
Sep 16, 2011 |
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15620878 |
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Current U.S.
Class: |
1/1 |
Current CPC
Class: |
B24C 7/0007
20130101 |
International
Class: |
B24C 7/00 20060101
B24C007/00 |
Claims
1.-10. (canceled)
11. A method of operating wet abrasive blasting system, comprising:
charging a blast pot of the wet abrasive blasting system with a
liquid and solid abrasive to form a slurry, wherein the blast pot
comprises: a cylindrical side wall, an inwardly sloping top in the
general shape of a basin an upper most portion of an inner volume
of the blast pot defined between the underside of the inwardly
sloping top and an inside top of the cylindrical side wall of the
blast pot, an outlet connected to the cylindrical side wall at the
upper most portion of an inner volume of the blast pot, and a
self-venting assembly, wherein the self-venting assembly is
connected to the outlet in the cylindrical side wall; sealing the
blast pot during the final stage of charging the blast pot with
liquid; after sealing the blast pot, filling the blast pot with
additional liquid and removing substantially all of the trapped air
from within the blast pot through the self-venting assembly until
the fluid level fills the tank and the self-venting, assembly is
sealed; and pressurizing the blast pot with a fluid pump.
12. The method of claim 11, wherein the wet abrasive blasting
system comprises: a mixer; a blast hose in fluid communication with
the mixer; a slurry piping system connecting the bottom outlet of
the blast pot to the mixer; and a pressurized air piping system
capable of connecting a source of pressurized air to the mixer.
13. The method of claim 11, wherein the self-venting assembly,
comprises: an automatic vent valve that operates based upon a
sensor measuring air within the blast pot.
14. The method of claim 13, wherein the automatic vent valve opens
to release air from the blast pot that may become trapped in the
upper most portion of the blast pot, without releasing a
significant amount of fluid, through the automatic vent valve until
the fluid level fills the blast pot and the automatic vent valve is
automatically sealed to prevent escape of liquid.
15. The method of claim 13, wherein a pipe connects the outlet in
the cylindrical side wall and the automatic vent valve.
16. The method of claim 11, wherein the self-venting assembly
comprises one of a float type vent valve, a diaphragm-type vent
valve or an electronic vent valve.
17. The method of claim 11, wherein air accumulating in the blast
pot after purging due to worn pump seals, a suction leak in the
fluid pump's inlet hose or from a fluid source that includes
trapped air bubbles is vented through the self-venting
assembly.
18. The method of claim 11, wherein the self-venting assembly,
comprises: an automatic vent valve that operates based upon a
sensor measuring air within the blast pot, wherein the automatic
vent valve opens to release air from the blast pot that may become
trapped in the upper most portion of the inner volume, without
releasing a significant amount of fluid, through the automatic vent
valve until the fluid level fills the tank and the automatic vent
valve is automatically sealed to prevent escape of liquid, wherein
the automatic vent valve is a float type vent valve comprising a
chamber, a vent seal, a float and a seat, wherein if air enters the
automatic vent valve, the float moves to a lower position to allow
the air or other gases to escape the chamber.
19. The method of claim 11, wherein sealing the blast pot comprises
closing a spring-loaded bung.
20. The method of claim 19, wherein charging the blast pot of the
wet abrasive blasting system with the liquid and the solid abrasive
comprises charging the blast pot through a sealable inlet hole in
the inwardly sloping top.
21. The method of claim 20, wherein during charging air may escape
through the sealable inlet hole in top.
22. The method of claim 20, wherein during charging air may escape
through the sealable inlet hole in top until a water level reaches
the seal.
23. The method of claim 13, wherein the automatic vent valve
prevents the accumulator effect.
Description
FIELD OF THE INVENTION
[0001] The invention is directed toward wet abrasive blasting
systems used for cleaning, preparing surfaces, removing coatings,
and other abrasive blasting applications. Embodiments of the wet
abrasive basting system comprise a venting system on the blast pot.
The venting system may be a self-venting system that prevents gases
from accumulating in the blast pot, In wet abrasive blasting
systems, a slurry is conveyed via a piping system, hoses, etc. to a
mixer connected to a source of pressurized gas where slurry and
compressed air/gas are combined and directed through the blast hose
and blast nozzle.
BACKGROUND
[0002] To remove corrosion, rust, slag, paint, or coatings from a
substrate such as a surface to be restored, painted, or cleaned, an
abrasive blasting system is both desirable and necessary. In
certain applications, abrasive blasting systems should be able to
clean or remove corrosion, rust, slag, paint, or coatings without
damaging the underlying metal or other substrate. In other
applications, a certain degree of surface roughening (called
profile) may be desired to assure new paint or coating
adhesion.
[0003] The use of dry, hard abrasives, such as those used in
conventional sand blasting, may result in excessive surface
roughness to the point of causing damage to the substrate. Typical
blast particles are hard (2.8.about.9 on Mohs Scale of Mineral
Hardness) and abrasive in order to increase the efficiency of the
blasting operation. Soft blast particles (generally less than 2 on
the Mohs scale), such as agricultural products which can include
crushed walnut shells, rice hulls, corn cob, and pistachio shells,
plastic or glass particles are sometimes used to reduce substrate
surface damage.
[0004] Wet-abrasive systems have been used to control the
generation of dust and minimize surface damage, even while using
hard abrasives. Wet-abrasive systems rely on a method to force a
slurry of the abrasive media into the compressed air-stream in a
controlled manner. A blast pot or pressure vessel is charged with a
liquid, typically water, and the solid abrasive to form the slurry.
The blast pot is then purged of air, sealed, and connected to a
source of pressurized water. The flow of pressurized water forces
the slurry out of the blast pot, through a slurry piping system,
and into a mixer. Also connected to the mixer is a source of
pressurized gas, typically air. In the typical case, the water and
abrasive slurry is mixed with the compressed air to form a three
phase blasting stream of abrasive, water and air and directed
through the blast hose and directed with the blast nozzle to the
surface. Fluctuations in flow or pressure in either the slurry or
pressurized gas at the mixer will provide inconsistent behavior of
the wet abrasive blasting system and an inefficient blasting
process.
[0005] There exists a need for a wet abrasive blasting system with
increased consistency in pressure and flow at the mixer and
ultimately at the blasting nozzle.
SUMMARY
[0006] Embodiments of the wet blasting system comprise a blast pot
and an automatic air vent valve connected to a top portion of the
blast pot. The automatic air vent valve may be connected to an
upper portion of an inner volume of the blast pot to vent any air
that accumulates in the blast pot. In a preferred embodiment, the
automatic air vent valve is connected to the upper most portion of
an inner volume of the blast pot.
[0007] The inventors have discovered that wet-abrasive blasting
systems should be designed based on the principle that fluids,
commonly used for wet-abrasive blasting, will not compress. If the
blast pot is full of incompressible fluids, pumping additional
fluid into the blast pot necessitates that an equal amount of
slurry be forced out of a bottom outlet of the vessel. If a
significant amount of air is present, the air or other gas may be
compressed (producing an accumulator effect where the volume of the
pressure vessel occupied by the air or other gas is reduced and the
volume occupied by the fluid and particulates increases), which
could preclude the expected amount of slurry from being forced out
of the vessel.
[0008] Removal of substantially all of the trapped air or other gas
from within the filled pressure vessel provides an efficient and
predictable control of the volume of slurry that will be forced
into the compressed air-stream and thus propelled through the blast
hose and blast nozzle to perform wet-abrasive blasting. Manual
purging of air/gas, although widely used, provides inconsistent
results and does not adequately deal with new, additional air that
may be introduced into the vessel after it is sealed and
pressurized. In addition, manually opening a valve to purge air
would most likely result in liquid run-off at the location of the
blast pot, as both fluid and air will escape due to the fact that
the air volume is not easily determined and the operator cannot
determine the exact point at which all air/gas is expelled and
liquid starts to exit. Consequently, additional manual venting will
cause fluid to escape until the operator can react to the
situation. Further, the operator may not realize the blast pot
needs to be purged of air to improve system performance.
[0009] The self-venting system can release substantially all of the
air or other gases introduced during the fill process (with minimal
fluid release) and the self-venting system may also automatically
release any air or other gas introduced while the wet-abrasive
blast unit is in operation. During operation, a properly
functioning wet blast system typically comprises a fluid pump for
pressurizing the blast pot and pumping additional fluid into the
blast pot, which in turn forces the same volume of slurry out of
the bottom outlet of the blast pot and into a slurry/gas mixer.
[0010] An automatic vent valve in a self-venting system eliminates
the need to manually determine if air is present in the blast pot
and to manually vent the air. Automatic vent valves may be designed
to purge only air or other gases and the vent's seat is
automatically sealed before fluid escapes. The self-venting system
prevents the possibility of the operator forgetting to manually
purge all of the air from the pressure vessel resulting in pressure
fluctuations in the piping systems and inefficient blasting
operation. Further, the self-venting system eliminates the need to
manually "catch" and properly dispose of fluids that escape along
with the purged air during manual venting.
[0011] As used in this document, "force-mixed into the compressed
air-stream" is defined as a method to force slurry in a pipe into a
connecting point that is incorporated in a compressed air piping
system. Both piping systems (the compressed air and the pressurized
slurry) may have a means of shutting off flow simultaneously, so
that the forced mixing occurs only during the time when the
compressed air is moving through the circuit and into the blast
hose and nozzle.
[0012] The terminology used herein is for the purpose of describing
particular embodiments only and is not intended to be limiting of
the invention. As used herein, the term "and/or" includes any and
all combinations of one or more of the associated listed items. As
used herein, the singular forms "a," "an," and "the" are intended
to include the plural forms as well as the singular forms, unless
the context clearly indicates otherwise. It will be further
understood that the terms "comprises" and/or "comprising," when
used in this specification, specify the presence of stated
features, steps, operations, elements, and/or components, but do
not preclude the presence or addition of one or more other
features, steps, operations, elements, components, and/or groups
thereof.
[0013] Unless otherwise defined, all terms (including technical and
scientific terms) used herein have the same meaning as commonly
understood by one having ordinary skill in the art to which this
invention belongs. It will be further understood that terms, such
as those defined in commonly used dictionaries, should be
interpreted as having a meaning that is consistent with their
meaning in the context of the relevant art and the present
disclosure and will not be interpreted in an idealized or overly
formal sense unless expressly so defined herein.
[0014] In describing the invention, it will be understood that a
number of components, parts, techniques and steps are disclosed.
Each of these has individual benefit and each can also be used in
conjunction with one or more, or in some cases, all of the other
disclosed techniques. Accordingly, for the sake of clarity, this
description will refrain from repeating every possible combination
of the individual steps in an unnecessary fashion. Nevertheless,
the specification and claims should be read with the understanding
that such combinations are entirely within the scope of the
invention and the claims.
BRIEF DESCRIPTION OF THE FIGURE
[0015] The invention will now be described with the reference to
the drawing wherein:
[0016] The FIGURE depicts an embodiment of a blast pot comprising a
self-venting assembly.
DESCRIPTION OF EMBODIMENTS OF THE INVENTION
[0017] The invention relates to wet abrasive blasting systems.
Embodiments of the wet abrasive blasting system may comprise a
blast pot having a self-venting assembly. The self-venting assembly
is capable of purging air from the blast pot without operator
action during pressurizing and operation of the wet abrasive
blasting system. In some embodiments, the wet abrasive blasting
system comprises a blast pot and an automatic air vent valve
connected to a top portion of the blast pot. The automatic air vent
valve is capable of releasing air from the blast pot without
releasing a significant amount of fluid. The automatic air vent
valve may be positioned in a top portion of the blast pot such that
the blast pot remains substantially full of liquid and
abrasive.
[0018] The wet abrasive blasting system may further comprise a
slurry piping system, a pressurized air piping system and a mixer.
Typically, the slurry piping system will connect a bottom outlet of
the blast pot to a mixer. In certain embodiments of the wet
abrasive blasting system, the blast pot contains a mixture of a
solid particulate and a fluid (hereinafter "slurry"), and the
slurry piping is capable of conveying the desired flow rate of
slurry from the blast pot to the mixer to be combined with the
pressurized gas. The pressurized gas piping system connects a
source of pressurized gas to the mixer and is capable of conveying
the desired flow rate of pressurized gas at a desired pressure to
the mixer. Typically, the gas will be air and the fluid will be
water, but other gases and fluids may be used. In addition,
additives may be added to the fluid or the gas, as desired. The
abrasive media may include media in the range of United States
Standard Sieve Screen Size 100.mu..about.10.mu.. The media and
water are mixed into the pressure vessel; the ratio is
inconsequential. A blast pot, typically, comprises a cone-shaped
bottom with an outlet at the lowest point of the vessel. Since the
media is heavier than water, the slurry is funneled into a hose or
pipe that connects the blast pot to the input piping of the control
panel. The slurry piping system and/or the pressurized gas piping
system may be comprised of pipe and other components as desired to
control the flow and pressure.
[0019] The inventor's discovered that wet abrasive blast systems
operate and should be designed on the principle that the fluids in
the slurry cannot be compressed. Therefore, the volume of abrasive
slurry pushed out of the blast pot and mixed into the compressed
air stream is controlled by the amount of fluid forced into the
substantially filled pressure vessel. In such a case, as a volume
of water is pumped into the blast pot, an equal volume of
wet-abrasive media must be forced out of the pressure vessel.
However, air trapped in the pressure vessel during filling or air
that may accumulate in the pressure vessel or blast pot after
purging due to worn pump seals, or a suction leak in the fluid
pump's inlet hose, or from a fluid source that includes trapped air
bubbles, will compress and cause fluctuations in the flow and/or
the pressure of slurry stream. These fluctuations in flow and
pressure may be at least partially due to the accumulator effect
caused by the trapped compressed air/gas. As used herein,
"accumulator" or "accumulator effect" is defined as a storage
reservoir in which fluid is held under pressure with a compressible
gas which can be further compressed or pressurized without forcing
fluids out of the vessel when additional fluid is added to the
reservoir. Since the compressible gas may be further compressed the
reservoir may hold an additional volume of fluid as the volume of
compressible gas is reduced.
[0020] In conventional dry blasting, this pressure vessel would
contain both abrasive and compressed, air or other gas in a top
portion of the blast tank, the trapped compressed air/gas forces
the dry media out of the bottom of the tank to the blast hose.
However, in wet-abrasive blasting systems, the pressure vessel
contains a slurry of abrasives and fluid (usually water) when
"charged." Gas trapped in the pressure vessel above the slurry is
undesirable as the trapped air results in a accumulator affect in
the blast pot and is detrimental to the consistent and efficient
means of forcing the wet-abrasive media into the mixer with the
compressed air.
[0021] The air or other gas may become trapped in the space between
the underside of the basin-shaped enclosure and the inside top of
the cylinder, which makes up the cylindrical body of the pressure
vessel (for example, the air space AS shown in the FIGURE). Some
blast pots are equipped with a manual vent valve to remove air from
the air space. However, this manual method has its shortcomings due
to the fact that the operator may not realize the blast pot has
accumulated air and that manually venting also allows fluid to
escape along with the trapped air/gas. Wet abrasive blasting system
operators typically will rely on the release of fluid from the vent
valve to ensure the air and other gases is released. The operator
has no other visible means of determining the exact moment when all
of the air/gas has been expelled and the operator waits to see the
escaped flow of liquid as an indication of when to manually close
the valve. This is a major concern, especially in states or other
locations where a run-off of liquid could be deemed as a violation
of their ecology protection laws.
[0022] The inventors were the first to realize the advantages of a
wet abrasive blasting system comprising a blast pot having a
self-venting system wherein air and other gas is automatically
vented during the filling and pressurizing of the pressure vessel
without allowing fluid to escape. The self-venting system
additionally has the advantage of venting any air or other gas that
may unknowingly be introduced into the purged, pressurized vessel
during use or idle time via worn pump seals, a suction leak in the
pump's fluid source hose or piping, or even due to natural air
bubbles that are trapped in the fluid being fed to the fluid pump,
for example. Because wet abrasive blasting system operators
generally do not manually re-purge the pressurized vessel of new
air/gas (because there is no direct indicator when there is air in
the system and venting could cause fluid run-off due as the fluid
escapes simultaneously or after the air is purged), the inventors
realized an automatic vent valve would provide a wet blasting
system that prevents the accumulator effect and has improved
efficiency and performance.
[0023] In wet abrasive blasting systems wherein the blast pot is
experiencing an accumulator effect, the pressure fluctuations at
the mixer may result in uneven mixing ratios of slurry and air
moving through the blasting hose and/or slurry backing up into the
air supply piping system. Embodiments of the wet blasting systems
comprising a self-venting assembly prevents this accumulator effect
by allows air to escape from the blast pot before problems are
realized.
[0024] Embodiments of the wet abrasive blasting system may comprise
a vertically mounted, cylindrical pressure vessel with the inwardly
sloping top welded enclosure in the general shape of a basin as
shown in the FIGURE. The basin comprises a sealable inlet hole
allowing access into the inner volume of the blast pot. The
sealable hole may be sealed by a pressure tight lid that is secured
by any means such as, but not limited to, spring loaded, bolts,
threaded, swing bolts, clamps, or other securing means. (Some
models of the EcoQuip.TM. wet abrasive blasting systems comprise a
spring-loaded bung to seal the inlet hole.) The purpose of the
inward sloping top or basin is to provide a convenient means to
fill the blast pot with abrasive media and fluid (the basin serves
as a funnel to guide the particulate blast media and fluid into the
hole in the top of the vessel).
[0025] The blast pot may be of any design capable of storing the
slurry and maintaining the pressure of the system. Typical blast
pots for wet abrasive blasting systems comprise cylindrical side
walls and a conical shaped bottom leading to the bottom slurry
outlet of the blast pot and into the slurry piping system, though
other configurations may be used. The top and/or the bottom of the
blast pot may be any configuration such as, but not limited to,
flat, round, conical, elliptical, inward sloping, basin shaped, or
upward sloping, for example. In one embodiment, the blast pot
comprises a threaded outlet such as outlet 15 in the FIGURE to be
located as high as possible in the inner volume of the tank, for
example, in the area below the welding of the basin shaped top to
the cylindrically shaped outer housing. The outlet may be any
outlet capable of connecting the self-venting assembly or automatic
vent valve to the blast pot and in fluid communication with its
inner volume. The outlet may be a welded connection, threaded
connection, flanged connection, quick connector, and/or tubing
connector. The self-venting assembly may further comprise a piping
system between the blast pot and the automatic vent valve. In an
embodiment of the wet abrasive blasting system, the outlet is in
communication with a top portion of the inner volume of the blast
pot and, in a more specific embodiment, the outlet is in fluid
communication with the highest point of the inner volume within the
blast pot.
[0026] An automatic vent valve may be connected to the outlet. The
automatic vent valve may be any type of valve capable of venting
air from a pressurized vessel. The valve may be a float type valve
or an automatic control valve that operates based upon a sensor
measuring air within the pressurized vessel.
[0027] For example, the automatic vent valve may be a float type
valve as shown in FIG. 1. During the final stage of "charging" or
filling the blast pot, the blast pot is sealed. For example, the
spring-loaded bung as shown in the FIGURE is released from its
open, position and allowed to seal the pot under the biasing force
of the spring. (Pressurization of the fluids cannot take place
unless the pot is sealed). As additional fluid/water is pumped to
fill or charge the blast pot, the air or other gas will escape
through the self-venting system's vent until the fluid level fills
the tank and the vent is sealed. In an embodiment of the wet
abrasive blasting system with a float-type vent valve, the fluid
level raises thereby lifting the float and causing its vent seal to
tightly press against the vent's seat. Should new air/gas be
introduced into the pressurized vessel, after it has been filled,
sealed, and purged, the air/gas physically rises to the top portion
of the vessel (in the air space between the underside of the basin
shape and the cylindrical outer shell, for example) and temporarily
causes the float to release its seal from the vent's seat enough to
vent the gas. The air would continue to vent until the float is
again lifted by the rise of fluid and the seal would again engage
the vent's seat and prevent any significant amount of fluid from
escaping.
[0028] As used herein, "pipe" shall mean any fluid containment
device used to convey liquid or gas, such as a tube, hose, duct,
pipe, or other similar structure. The pipe may have any
cross-sectional shape, including rectangular, square, circular, or
other shape. The flow area of the pipe is defined by its internal
cross-sectional area.
[0029] As used herein, "piping system" shall mean pipe and other
components used to connect one part of a system to another. The
other components may include, but are not limited to: valves, check
valves, elbows, tees, reducers, regulators, connectors, gauges or
sensors such as flow, temperature or pressure gauges, and control
valves.
[0030] As used herein, "fluid" or "fluids" are liquids, preferably
substantially incompressible fluids, such as water.
[0031] An embodiment of a blast pot 10 comprising a self-venting
assembly is shown in the FIGURE. The blast pot 10 comprises
vertical cylindrical side wall 11 and top 12. Top 12 forms a basin
with a filling hole able to be sealed by a spring loaded bung 13.
The spring loaded bung 13 forms a pressure tight seal 14 capable of
sealing the blast pot 10. Embodiments of the wet abrasive system
with a self-venting system may or may not comprise a spring-loaded
bung 13 but may comprise another means of charging and sealing the
blast pot. The abrasive media and water may be added through the
hole in the top 12. As the blast pot 10 is filled with particulate
and liquid, air may escape through the same hole in top 12 until
the water level reaches the seal 14. At that point, the basin B
will begin to fill and an air space AS is trapped in the top
portion of blast pot 10. However, the embodiment of the blast pot
10 in the FIGURE comprises a self-venting assembly connected to
outlet 15. The self-venting assembly comprises a vent seal 16 that
may be sealed closed by seat 17 attached to float 19 on lever 20.
The vent seal 16 and seat 17 are in the open position (as shown) as
long as float 19 on a lever 20 is in the lower position. As the
automatic vent valve chamber 21 fills with liquid, the liquid lifts
float 19 to an upper position which raises lever 20 on its hinge
18. This moves seat 17 against vent seal 16 closing the vent. If
additional air enters automatic vent valve chamber 21, the float 19
will move to a lower position opening vent seal 16 to allow the
pressurized air to escape the chamber 21 and allow chamber 21 to be
substantially with liquid, again raising seat 17 to seal vent seal
16 to prevent release of the liquid. As long as the chamber 21 is
substantially filled with liquid, seat 17 will prevent escape of
liquid from the vent. Other styles of automatic vent valves may
also be used on embodiments of the self-venting, assembly.
[0032] In the embodiment shown in the FIGURE, the spring-loaded
bung 13 comprises a bracket 22 mounted below the spider plate 23.
The spider plate 23 is above the hole in the basin B through which
the bung's guide-rod passes. The bracket 22 serves at least two
purposes: (1) the bottom of the bracket 22 becomes the lower
surface for a locking device to hold the bung 13 in the open
position during the filling, process and (2) a center hole in the
bracket 22 acts to align the bung's guide-rod 24 and eliminates the
need for a bung alignment counterweight. The spring-loaded bung
system simplifies the "charging" of the pressure vessel and makes
the process as free from "operator error" as possible.
[0033] The self-venting system does not require the spring-loaded
bung system in order for it to work. The spring-loaded bung keeps
the pressure vessel closed during idle time. This spring loaded
sealing prevents debris from contaminating the inside of the
vessel. This also prevents precipitation from entering the vessel
during idle time, which could freeze and be detrimental to ball
valves and other components associated with the pressure vessel.
The spring-loaded bung and self-venting system enables "charging"
the pressure vessel without any fluid remaining in the top of the
basin--above the seal. Therefore, the operator can travel with a
sealed pressure vessel (whether "charged" or "uncharged") and avoid
spillage, thus not violating ecology laws about run-off in some
states.
[0034] The self-venting system and the spring-loaded bung are two
separate devices installed on the same pressure vessel to comprise
a system that works together to simplify the venting of air/gas
from a pressure vessel, and more importantly, it does so without,
any excess significant fluid run-off or unnecessary spillage.
[0035] The embodiments of the described wet abrasive blasting
systems, self-venting assemblies and methods are not limited to the
particular embodiments, components, method steps, and materials
disclosed herein as such components, process steps, and materials
may vary. Moreover, the terminology employed herein is used for the
purpose of describing exemplary embodiments only and the
terminology is not intended to be limiting since the scope of the
various embodiments of the present invention will be limited only
by the appended claims and equivalents thereof.
[0036] Therefore, while embodiments of the invention are described
with reference to exemplary embodiments, those skilled in the art
will understand that variations and modifications can be effected
within the scope of the invention as defined in the appended
claims. Accordingly, the scope of the various embodiments of the
present invention should not be limited to the above discussed
embodiments, and should only be defined by the following claims and
all equivalents.
* * * * *