U.S. patent application number 13/558258 was filed with the patent office on 2012-11-29 for vacuum grooming tool cleaner.
This patent application is currently assigned to HAIR PATROL LLC. Invention is credited to James E. Freidell.
Application Number | 20120297571 13/558258 |
Document ID | / |
Family ID | 23121720 |
Filed Date | 2012-11-29 |
United States Patent
Application |
20120297571 |
Kind Code |
A1 |
Freidell; James E. |
November 29, 2012 |
VACUUM GROOMING TOOL CLEANER
Abstract
A vacuum cleaning tool for removing animal hair from nearly any
hand-held grooming tool is disclosed. A vacuum grooming tool is
also disclosed. A vacuum plenum of the cleaning tool is attachable
to a vacuum source and has an opening for cleaning a grooming tool
in one pass. The cleaning tool can be mounted on a stationary
support and may also include a pivot-action mechanism that connects
the cleaning tool to the vacuum source during its engagement by a
hand-held grooming tool being cleaned. This pivot-action mechanism
can switch the vacuum off to a connected vacuum grooming tool and
on to the cleaning tool, such that the airflow through the cleaning
tool does not have to compete with any vacuum or airflow through
the vacuum grooming tool during its cleaning.
Inventors: |
Freidell; James E.;
(Littleton, CO) |
Assignee: |
HAIR PATROL LLC
Littleton
CO
|
Family ID: |
23121720 |
Appl. No.: |
13/558258 |
Filed: |
July 25, 2012 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
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11338221 |
Jan 23, 2006 |
8230819 |
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13558258 |
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|
10147802 |
May 17, 2002 |
7159274 |
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11338221 |
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60291762 |
May 17, 2001 |
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Current U.S.
Class: |
15/398 ;
15/414 |
Current CPC
Class: |
A47L 9/06 20130101; A01K
13/002 20130101; A47L 9/0606 20130101; A01K 13/00 20130101; A01K
13/001 20130101 |
Class at
Publication: |
15/398 ;
15/414 |
International
Class: |
A47L 9/06 20060101
A47L009/06; A47L 9/02 20060101 A47L009/02 |
Claims
1. A vacuum cleaning tool, comprising a grooming tool cleaning head
having a nozzle attachable to a vacuum source, the nozzle having an
opening positionable in proximity to a surface of a grooming device
such that animal hair attached to the surface of the grooming
device can be removed from the surface of the grooming device by
negative airflow generated by the vacuum source, the grooming tool
cleaning head being mounted on a stationary support, whereby animal
hair attached to the surface of the grooming device can be removed
from the surface of the grooming device without requiring an
operator of the vacuum cleaning tool and the grooming device to
hold the vacuum cleaning tool by hand, wherein the opening is at
least as large as one dimension of the surface of the grooming
device, whereby the surface of the grooming device can be cleaned
in a single pass of the surface of the grooming device across the
opening of the nozzle of the grooming tool cleaning head.
2. The cleaning tool of claim 1, wherein the cleaning head is
pivotally mounted on the stationary support.
3. A grooming tool cleaner, comprising a grooming tool cleaning
head having a nozzle attachable to a vacuum source, the nozzle
having an opening, which when proximate to a surface of a grooming
device, removes animal hair attached to the surface of the grooming
device by negative airflow generated by the vacuum source as the
grooming device is wiped across, the grooming tool cleaning head
being mounted on a stationary support, whereby an operator of the
grooming device has the ability to engage the vacuum cleaning tool
to clean the grooming device without releasing an animal being
groomed.
4. The grooming tool cleaner of claim 3, wherein the cleaning head
is pivotally mounted on the stationary support.
5. A grooming tool cleaner, comprising a grooming tool cleaning
head having a nozzle attachable to a vacuum source, the nozzle
having an opening configured to interface with a slicker brush, the
opening when engaged with the slicker brush removes animal hair
attached to the slicker brush with negative airflow generated by
the vacuum source as the slicker brush is wiped across the opening,
the grooming tool cleaning head being mounted on a stationary
support, thereby allowing a groomer to engage the slicker brush
with the opening to clean the slicker brush without releasing an
animal being groomed.
6. The grooming tool cleaner of claim 5, wherein the cleaning head
is pivotally mounted on the stationary support.
7. A grooming tool cleaner comprising a grooming tool cleaning head
having a first nozzle attachable to a vacuum source, the first
nozzle having an opening with respect to which a pressure
differential is induced between the vacuum source and the opening,
the opening being compatible with a shape of an operative portion
of a grooming tool so as to increase the pressure differential's
affect upon the operative portion of the grooming tool and when the
operative portion of the grooming tool is engaged with the opening
the pressure differential removes animal hair attached to the
operative portion of the grooming tool.
8. The grooming tool cleaner of claim 7, wherein the cleaning head
is pivotally mounted on the stationary support.
Description
CROSS-REFERENCE TO RELATED APPLICATION
[0001] The present application is a divisional of pending U.S.
Utility patent application Ser. No. 11/338,221, filed Jan. 23,
2006, for which issuance of U.S. Utility Pat. No. 8,230,819 has
been scheduled for Jul. 31, 2012 by way of an Issue Notification
mailed Jul. 11, 2012, which is a continuation of and claims the
benefit of U.S. Utility patent application Ser. No. 10/147,802,
filed May 17, 2002 and issued Jan. 9, 2007 under U.S. Utility Pat.
No. 7,159,274, which claims the benefit of U.S. Provisional
Application No. 60/291,762 filed May 17, 2001, all of which are
hereby incorporated by reference in their entirety.
FIELD
[0002] The present invention relates generally to animal grooming
tools and more particularly to animal grooming vacuum tools.
BACKGROUND OF THE INVENTION
[0003] Professional animal groomers deal with a large amount of
hair during the grooming process. Hair accumulates on the grooming
table, floor, and in the bathing tub. Much of this hair is
introduced into the air environment as a result of blow drying,
hair stripping, brushing, combing, raking, clipping, shearing,
de-shedding, carding, and de-matting operations. Much of this hair
is physically handled by the groomer as he/she manually removes
accumulated hair from various hand tools such as slicker brushes,
combs, and rakes. In this latter case, the groomer must use both
hands and either drops extracted hair on the floor or deposits such
into a waste receptacle. During the bathing process, an abundance
of animal hair often finds its way into the drain causing frequent
blockage. Most professional grooming shops have plumbing
professionals clean shop bathing drains as frequently as every two
weeks as a precautionary measure.
[0004] Many states employ licensing and/or regulations requiring
that animal hair be cleaned up after grooming each animal before
another can be groomed at the same workstation. In practice, either
hair accumulates on the floor until which time as the groomer
decides it must be cleaned up, or it is cleaned up after each
animal. Most professional groomers use a standard wet/dry vacuum to
accomplish this clean-up operation. Fewer perform such clean-up
with brush, broom and dustpan. The environment containing
accumulated hair, dander and pests is recognized as unhealthy for
both humans and animals. Airborne hair and dander is one way of
transmitting skin ailments and disease between animals, and
allergens to humans, confined in closed spaces.
[0005] Clean-up time can be a substantial portion of the total time
allocated to groom an animal. Most grooming business advisors
espouse the need to continuously maintain as clean as possible a
grooming environment to appease discerning customers.
[0006] Professional groomers often suffer from carpal tunnel
syndrome, tendonitis, and other maladies resulting from repetitive
motion, particularly repetitive motion that involves strain due to
weight or resistance to such motion. Anything that can reduce the
number of repetitions and/or relieve strain, particularly in using
common hand tools, can reduce the incidence and severity of such
maladies.
[0007] Pet owners often must deal with volumes of hair naturally
shed by many animals. This shed hair accumulates around the home
during shedding season, creating a general nuisance and requiring
more frequent home vacuuming and cleaning
[0008] One of the problems faced by all groomers is the
accumulation of hair on their hand tools (combs, rakes, brushes,
etc.) during use. FIG. 9(A) shows a slicker brush before use, and
FIG. 9(B) after use. Groomers normally use their free hand to
remove the hair (and with slicker brushes in particular, presents a
relatively arduous, repetitive task). FIG. 9C illustrates that even
rakes and combs are affected.
BRIEF SUMMARY OF THE INVENTION
[0009] The present invention discloses a system of tools which,
when attached to a vacuum source, reduces the need for the tool
user (groomer) to manually deal with animal hair accumulating on or
in such tools during use, or manually clean up hair displaced from
the animal during the grooming process. Certain of these tools are
used with standard professional grooming hand tools. Others
integrate vacuum plenums into and with standard professional
grooming tool functionality. Others yet facilitate the drying of
animals. These tools also reduce exposure to animal dander and
pests often found in animal coats.
[0010] Features of this system of tools and/or individual tools (as
applicable) include: [0011] 1. aerodynamic design to allow
operation under vacuum application without significantly
contributing to environmental noise; [0012] 2. ergonomic design to
be lightweight and comfortable to use; [0013] 3. increased
efficiency, compared to common grooming tools that the invention
replaces, as measured in the amount of hair extracted per
operational stroke and/or the elimination of operational strokes,
both of which can directly translate to reduction of repetitive
motion actions and the amount of time required to groom an animal;
[0014] 4. the ability to automatically capture most animal hair,
dander, and pests that otherwise would be released in the
environment as a result of the grooming process; [0015] 5. designs
comparable to the professional hand tools the invention replaces in
their ability to properly accommodate animal body contour(s) and
varying types of animal hair; [0016] 6. the ability to use such
tools with a single hand, allowing the groomer the ability to
always keep one hand on the animal being groomed; [0017] 7.
reduction of time devoted to animal drying after bathing; [0018] 8.
reduction of the amount of hair introduced into bath drains and
thereby reducing the incidence of drain clogging resulting from
animal bathing; [0019] 9. reduction of the acoustic noise
environment, particularly during blow drying and clean-up, either
in sound pressure level (intensity) reduction or time of exposure
to such, or both; and [0020] 10. design of certain tools to be
usable by animal owners employing a standard home vacuum cleaner
(upright or canister) as the vacuum source.
BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS
[0021] Other objects and advantages of the invention will become
apparent upon reading the following detailed description and upon
reference to the drawings in which:
[0022] FIG. 1 shows a set of embodiments of the invention in which
the vacuum grooming tool includes shedding blade(s);
[0023] FIG. 2 shows the grooming tools shown in FIGS. 1(A), 1(B)
and 1(C), respectively, in a different perspective;
[0024] FIG. 3 shows a side view of the grooming tools shown in FIG.
2;
[0025] FIG. 4 shows another embodiment of the invention, in which
the grooming tool includes a brush;
[0026] FIG. 5 shows another set of embodiments of the invention, in
which the grooming tool includes a comb;
[0027] FIG. 6(A) shows another embodiment of the invention, in
which the grooming tool includes a rake;
[0028] FIG. 6(B) shows a conventional grooming rake;
[0029] FIG. 7 shows another embodiment of the invention, in which
the grooming tool includes a rake;
[0030] FIG. 8 shows another embodiment of the invention, in which
the grooming tool includes a de-matting tool;
[0031] FIGS. 9(A), 9(B) and 9(C) show examples of conventional
grooming tools;
[0032] FIGS. 9(D) and 9(E) show examples of the vacuuming grooming
tools according to the invention in their condition after use;
[0033] FIGS. 10 and 11 show a grooming tool cleaner according to
the invention and examples of various uses of the cleaner; and
[0034] FIGS. 12 and 13 show an articulated cleaner according to an
aspect of the invention.
DETAILED DESCRIPTION OF SPECIFIC EMBODIMENTS
[0035] FIG. 1D depicts an animal grooming vacuum tool 100 having an
integrated shedding tool blade 110. The device has a suction nozzle
120 having an integrally formed suction pipe 122 to connect to a
source of negative pressure (such as a vacuum). The suction pipe
122 is in physical communication with a hollow body 124 terminating
in an integrally formed mouth opening 126. In the preferred
embodiment, the mouth 126 is substantially rectangular and is
defined by a first pair of integrally formed spaced rectangular
walls 128 which are substantially parallel to each other and a
second pair of integrally formed spaced rectangular walls 130 which
are substantially parallel to each other.
[0036] The apparatus has one or more substantially straight
stainless steel grooming blades 110, illustrated in more detail in
FIG. 1(F), disposed within the rectangular mouth opening. Each
blade 110 has two shaped and smoothed ends 112, each end is
attached to one of the second pair of integrally formed spaced
rectangular walls 130. Each blade also has a serrated edge 114
extending outside the plane of the rectangular mouth opening 126.
In multiple blade implementations, such as those schematically
shown in FIGS. 1(A), 1(B), 1(C) and 1(E) each blade 110 is
substantially parallel to the other blades 110 and to the first
pair of integrally formed spaced rectangular walls. In addition,
the blades 110 are positioned to provide an air passage extending
from the mouth opening 126 into the hollow body portion 124 of the
nozzle 120 between each of the blades 110 and between the blades
110 and the first pair of integrally formed spaced rectangular
walls 128. Better results are achieved if the animal hair can be
sucked down from both sides of the blade 110.
[0037] Although the mouth 126 of the preferred embodiment is
rectangular, those skilled in the art will recognize that other
mouth shapes such as ovals may be used, so long as the blades 110,
in multiple blade devices, are substantially parallel to each
other.
[0038] Each blade 110 can be attached to the mouth opening 126 in a
variety of ways. For example the blades 110 can be glued to the
walls using commercially available epoxies. For additional
stability, receiving slots can be cut in the nozzle housing to
receive the ends of each blade 110 or the entire edge of the blade
110 opposite the serrated teeth 114.
[0039] Blades 110 may be constructed out of stainless steel or a
plastic blade may be used provided the mold for the serrated edges
of such (or post molding operations) give rise to sharp edges. The
ends 112 of the blades are shaped (and may be smoothed) in order to
minimize sharp corners which could cut or scrape an animal's skin
when used. These tools are designed to be pushed or pulled on the
animal's coat, not side-to-side, which could injure the coat or
underlying skin.
[0040] The blade can be formed from a substantially straight piece
of the toothed metal, as opposed to trying to maintain a curve in
the metal blade. The blade can be integrated with an upholstery
nozzle that does not have bristles. The blade can also take the
form of any manual shedding blade. For example, in the embodiment
illustrated in FIG. 1(G), the blade 140 has faceted teeth 142 with
sharply angled channels 144 between the teeth 142 and sharp edges
145 for pulling hair. A blade similar to a hair clipper blade, with
teeth that have cutting edges, can also be used.
[0041] As illustrated in FIG. 1(H), the orientation of the blade(s)
can be set at an angle 116 relative to the direction of tool motion
118 during the intended normal use. Typically, the tool is moved in
a direction substantially perpendicular to the rim of the mouth
opening 126 so that the vacuuming action is the most efficient. The
blade can be perpendicular to the tool motion, or deviate from the
perpendicular orientation by an angle 116. Typically, the blade is
perpendicular or angled away from the tool motion 118.
[0042] FIGS. 2(A), 2(B) and 2(C) as well as FIGS. 3(A), 3(B) and
3(C) depict, respectively, blades having different heights 210,
depending upon the type of animal's coat to be groomed. The angle
220 between the hose attachment point (i.e., suction pipe 122,
which serves as the handle) and blade(s) 110 may vary according to
customer preference and/or ergonomic design considerations. In the
preferred embodiment the blade protrudes between 1/8'' to 5/8''
from the mouth of the nozzle.
[0043] The blade could also be mechanically secured to the mouth
using a clip or other fastener. Those skilled in the art will
recognize that using a mechanical mechanism allows blades to be
exchanged.
[0044] The present invention will operate with commercially
available wet/dry and standard vacuum cleaners. The greater suction
of the wet/dry vacuum (compared to the upright or canister vacuum)
tends to be more effective in lifting the animal's coat (its hair),
almost to the point of standing upright within the vacuum tool.
Nevertheless, care should be taken to ensure that too much suction
is not used. In the event a strong vacuum is used, an adjustable
vacuum suction hose can be used to reduce the vacuum pressure.
[0045] Other means can be used to reduce suction. For example, a
vacuum with a variable-speed motor drive can be used to create
variable suction; a vent, with or without a valve, can also be
placed on the grooming tool itself.
[0046] Adequate CFM and vacuum pressure is important. In the
preferred embodiment, the vacuum pressure should be at least 40
inches of water at or above 90 CFM. Tools may be fabricated with
smaller vacuum orifices to accommodate less powerful vacuum
cleaners. Similarly, larger tools designed for horses and similar
large animals may operate best with greater vacuum pressure and
airflow.
[0047] FIGS. 1, 2 and 3 show several tools incorporating shedding
tool functionality into a vacuum nozzle. The number of blades and
overall tool size varies depending upon the type and size of
animal, and the characteristics of the animal's hair. For example,
Tool E in FIG. 1 is sized for horses and other large animals. The
length of the blade 110 is typically a few inches in the preferred
embodiment, but may be built larger or smaller to suit the intended
use. An example of where a smaller tool may be of value would be
one for small dogs and particularly legs of dogs generally. For
such a purpose, a tool approximately 1 to 2 in. wide may prove most
useful.
[0048] FIG. 4 discloses an alternate embodiment using a pin brush
410 instead of one or more blades. The pin brush 410 has a large
number of plastic or metal wire pins 420 held by base 430. Base 430
may be rigid or flexible. The pins allow air flow from a vacuum to
suck hair through the slots 440 formed in the base 430 and the
mouth 126 of the device.
[0049] The slot configuration of this design also aids blow drying.
The slots 440 allow airflow created by the vacuum to help suck hair
(and fleas, ticks, dirt, etc.) up into the brush while brushing and
to evacuate loosened hair and moisture. Note that hair may wrap
around the brush pins (more than the shedding blade) and require
additional procedures to remove the hair. Airflow may be induced in
reverse (connected to the blower output of a vacuum cleaner for
example) to further aid blow drying while brushing the animal.
[0050] Those skilled in the art will recognize that the slot size,
shape, number and length of pins may all vary depending on the
animal's hair length and the required amount of brushing or drying
assistance. Overall size may also vary depending on the size of the
animal. Instead of brush pins, bristles can also be used in the
embodiment shown in FIG. 4.
[0051] FIG. 5 discloses an alternate embodiment using combs 510,
530 and 560 instead of a blade. Three styles of vacuum combs are
shown, respectively. Two (FIGS. 5(A) and 5(B)) of the depicted
embodiments are intended to be used like a rake (moved fore and
aft). Pulling the rake works better than pushing. The third vacuum
comb (FIG. 5(C)) is designed to be used more like a traditional
comb (moved sideways).
[0052] In all cases, airflow (created by vacuum) flows around both
sides of the comb to suck hair up into the comb and evacuate
loosened hair (along with dirt, dander, fleas, ticks, etc.). The
combs may be constructed of metal or plastic. Comb length and pitch
(number of teeth per inch), may be varied according to personal
preference and the type and length of hair on the animal to be
groomed. Hair will accumulate in the teeth during use, requiring
removal. Size may vary also (length of teeth) depending on personal
preference and the size of the animal.
[0053] FIGS. 6(A) and 7 depict rakes 610 and 710, respectively, of
embodiments of the present invention. Conventional rakes, such as
the one 650 shown in FIG. 6(B), are used for some dog breeds. FIG.
7 shows a double row rake 710 integrated into a vacuum hand tool,
creating a vacuum rake in accordance with an embodiment of the
present invention. Shown in FIG. 6(A) is a single row Teflon coated
rake according to an embodiment of the invention. Again, vacuum
causes airflow around the rake so to suck up hair, dirt, fleas,
ticks, etc. into the tool. Preferably, air flow would also flow
between the rows of the double row rake 710. The devices were made
using metal rakes (some Teflon coated), but can be made of any
suitable material, such as metal and plastic. The number of teeth,
pitch, length of rake, and length of rake tangs may vary, according
to the preferences of the user and breed of animal to be groomed.
The rake tangs could be made of plastic. In use, hair will build up
in the tangs, requiring removal.
[0054] FIG. 8 depicts two vacuum de-matting tools. De-matting tools
usually have replaceable blades 820, 860 that are very sharp for
cutting hair. The purpose is to cut through hair mats, somewhat
shredding such in order to allow a comb to effectively run through
the hair. Blades are replaceable in both cases but need not be in
either. According to one embodiment, air (from the vacuum) flows
around both sides of the blades 820, 860 (the cutting and
non-cutting edges), and in one case between the blades 860. A thumb
rest 870 is shown on the embodiment illustrated in FIG. 8(B).
Blades are reversible to accommodate both right and left-handed
users. Blades might be made of plastic. Cut hair may accumulate in
the blades during use, requiring removal.
[0055] As mentioned above, and illustrated as examples in FIGS.
9(D) and 9(E), the animal hair may accumulate in the tool of the
invention during use. FIG. 10 through 13 depict devices that are
used to remove accumulated hair from tools during use, thereby
eliminating the need for using ones fingers to do so.
[0056] One embodiment is a static vacuum cleaner 1000 shown in
FIGS. 10 and 11. A vacuum source (not shown) is adapted to a
cleaner head 1010 having an opening 1020 at least the size (length)
of most tools. The other dimension (width) is such that maximum
airflow is created, yet the opening is adequate to easily
accommodate any of the non-brush tools.
[0057] Brush tools are cleaned across the cleaner opening 1020,
providing mechanical scrubbing action to facilitate the vacuum
action. Non-brush tools are merely held in the vacuum cleaner
opening 1020.
[0058] Disconnecting the source of vacuum from the vacuum tool
before attempting to remove hair from the tool with the vacuum
cleaner typically makes hair removal from said tool easier and more
complete (vacuum sources and resultant airflow don't compete).
[0059] FIGS. 12 and 13 show one of many possible implementations of
an articulated tool cleaner 1200 according to one aspect of the
invention. The tool cleaner 1200 can be activated by placing the
tool to be cleaned onto the cleaner opening 1220 of a movable
vacuum plenum 1210 and pressing down, causing rotation of the
cleaner about a pivot 1230 held in place by channels effectuating a
rotational sliding mechanism similar to the action of a standard
linear motion blast gate. This rotation effectively switches the
vacuum source from a vacuum tool to the cleaner, allowing both the
vacuum tool and cleaner to share the same vacuum source, but not
simultaneously. This switches the vacuum off to the connected
vacuum tool and on to the cleaner, such that the airflow through
the cleaner does not have to compete with any vacuum or airflow
through the tool to be cleaned (wiped). If a brush is used, the
brush is wiped across the cleaner opening, (while pressing down)
providing mechanical assistance to assist the vacuum in removing
hair. Releasing the downward force causes a spring to return the
cleaner to the original position (via counter-rotation about the
pivot point).
[0060] An auxiliary vacuum device 1250 (AVD), shown in FIG. 12(B)
is designed to split the vacuum source to it in order to provide
vacuum outlets 1270 to either side of the movable vacuum plenum
1210. This provides flexibility in mounting the entire unit. The
unused outlet port is plugged in normal operation. One of the many
alternatives readily appreciated by one skilled in the art is a
simple pipe "elbow" (not shown), providing tool attachment on only
one side of the movable vacuum plenum 1210. Such pipe elbow could
also be configured such that it could be rotated to provide tool
attachment on either side of the movable vacuum plenum 1210.
[0061] Mechanical articulation and rotation can be minimized or
eliminated by using a pressure or other switch to activate
pneumatic (even vacuum-driven) or electrical motorized opening and
closing of respective valves to achieve the same function as that
described above.
[0062] In the preferred embodiment, the articulated brush scrubber
is made up of the following: a fixed 21/4'' vacuum plenum 1280, to
which vacuum is continuously supplied; a moveable vacuum plenum
1210, which rotates up and down around a fixed pivot point 1230.
One end of the moveable vacuum plenum 1210 has an opening 1220
having a width just larger than the width of the tool to be
cleaned. The other end of the moveable vacuum plenum has a sliding
vacuum seal 1290 (shown in FIG. 13(B) sealing off the fixed vacuum
plenum).
[0063] The device is activated by pushing the moveable vacuum
plenum 1210 down with the tool to be cleaned. This action, as
illustrated in FIG. 13(C), rotates the sliding vacuum seal 1290 off
the fixed vacuum plenum 1280 and simultaneously rotates the
previously open end of the moveable vacuum plenum 1210 to engage a
seal with the fixed vacuum plenum 1280. This causes air flow
through the moveable vacuum plenum 1210. It also stops or reduces
air flow through the AVD 1250. The device being cleaned is then
pushed across or inserted into the open end 1220 of the moveable
vacuum plenum 1210 to release trapped hair, which is sucked up by
the moveable vacuum plenum 1210, through the seal between moveable
and fixed vacuum plenums and on to a vacuum source.
[0064] At the completion of the cleaning motion, pressure on the
moveable vacuum plenum 1210 by the device being cleaned is released
by lifting the device being cleaned. A return spring 1282 biases
the moveable vacuum plenum 1210 back to the starting position,
sealing off the vacuum from the fixed vacuum plenum 1280 to the
moveable vacuum plenum 1210 and restoring full vacuum to the AVD
1250. This device could be used with any standard grooming tool as
well as any of the vacuum tools (with vacuum still running to
such). In the case of a shedding blade, comb, rake, or de-matting
tool, the tool would be cleared of trapped hair simply by engaging
the open end of the moveable vacuum plenum 1210, pushing both down.
No aft-fore motion of the tool would be required--the trapped hair
would be just sucked off. As for a non-vacuum assisted slicker,
bristle or pin brush, wiping motion of a pin brush style vacuum
tool would facilitate clearing of hair from the pins. Cleaning a
vacuum tool connected to its vacuum source via the AVD 1250 gains
the benefit of having its vacuum supply automatically stopped or
reduced through such engagement of the open end of the movable
vacuum plenum 1210, effectively disconnecting the AVD 1250, and
hence the source of vacuum to the vacuum tool from fixed vacuum
plenum 1280.
[0065] In the preferred embodiment, the device has a sufficient
seal so that leakage is not a significant source of noise. Also,
the seal remains adequate throughout many cycles. In addition the
vacuum plenums are designed with aerodynamically smooth inner
surfaces to avoid generation of noise. Finally, the entire tool
cleaner is designed as a single unit that can easily be attached
(with screws, etc.) to either the top or bottom of a grooming table
1302, or to a wall so to provide easy, natural access to such by
any tool held in a groomer's hand.
[0066] With this implementation, a vacuum source could easily be
shared between the tool cleaner and vacuum tools. Doing so may even
make both tools work better. Full vacuum would be available to the
vacuum tool when grooming. Activation of the tool cleaner would
release some or all of the vacuum from the vacuum tool, making it
that much easier for the tool cleaner to suck trapped hair off the
vacuum tool. Full vacuum would be restored to the vacuum tool upon
release of the tool cleaner. All of this action is accomplished
with just the one hand holding the tool that is to be "scrubbed" of
hair.
* * * * *