BACKGROUND OF THE INVENTION
1 . Field of the Invention
[0001] The present invention relates to drum-type washing machines that wash clothes and
others.
2 . Background Art
[0002] A conventional drum-type washing machine is disclosed in, e.g. Unexamined Japanese
Patent Application Publication No.
H10-127978 (Patent Literature 1). This washing machine includes a pump for supplying wash water
stored in a water tub into a water circulating path and a nozzle having multiple holes
through which the wash water jets from this side of a rotating drum toward an inner
part of the drum. The nozzle is placed in front of the drum and the multiple holes
are formed at slightly different angles from each other, so that clothes loaded in
the drum can get wet fast. The rpm of the drum is controlled to prevent the wet clothes
from tangling with non-wet clothes or clustering between the wet clothes. The foregoing
structure allows improving the tumbling effect produced by the spin of the drum, and
as a result, a washing time can be shortened and the performance of wash and rinse
can be improved.
[0003] Another conventional drum-type washing machine is disclosed in, e.g., Unexamined
Japanese Patent Application Publication No.
2005-334412 (Patent Literature 2). This washing machine is an upright washing machine wherein
a rotary axis of a water tub extends in a vertical direction, and a plurality of feed
ports is provided in an opening of the water tub.
[0004] Still another conventional drum-type washing machine is disclosed in, e.g., Japanese
Patent No.
4331243 (Patent Literature 3). This washing machine includes a rotary drum having an opening
at a front end thereof, a water tub having an opening at a front end thereof correspondingly
to the opening of the rotary drum, and a stream nozzle through which wash water fed
into the water tub by a pump streams out, wherein a front end wall of the water tub
has a curved rear surface which is curved inward of the rotary drum on an inner peripheral
end side thereof, and the wash water streamed out through the stream nozzle is guided
along the rear surface of the front end wall and discharged into the rotary drum through
an annular port formed by the curved surface between an inner peripheral end of the
front end wall of the water tub and an inner peripheral end of the rotary drum.
[0005] The foregoing conventional drum-type washing machine disclosed in Patent Literature
1 and Patent Literature 2 jets the wash water from the door side toward the inner
part of drum 4 through nozzle 26 placed above drum 4 at the door side, thereby wetting
the laundry for washing. This method, however, fails to practically wet the laundry
when a small volume of laundry is loaded in drum 4 because the water jetted in parts
fail to hit the laundry but hit the drum directly. To the contrary, when a large volume
of laundry is loaded, the wash water jetted in parts only hit the laundry near to
the nozzles or nozzle holes, so that nozzle 26 also fails to wet the laundry uniformly
or in a wider area. In these cases, wash performance for the entire laundry cannot
be improved.
[0006] In the drum-type washing machine disclosed in Patent Literature 1, since the nozzle
has multiple nozzle-holes, greater pressure loss is incurred during the water supply
from the circulating path to the individual holes. As a result, a smaller amount of
wash water is jetted from each one of the nozzle holes, so that it is difficult to
wet the clothes quickly and uniformly.
[0007] To overcome the foregoing problems, a nozzle greater in size is used, and multiple
nozzles are provided in the water tub for jetting the wash water over the greater
area. However, these measures cause the laundry rotating in the rotary drum to tangle
with the nozzles.
[0008] In the drum-type washing machine disclosed in Patent Literature 3, the wash water
streamed out through the stream nozzle always runs along the rear surface of the front
end wall before being discharged into the rotary drum through the annular port. In
the case where the stream nozzle is provided at a position distant from the annular
port, adverse resistance from the wall surface more considerably slows down a flow
velocity, failing to spray the wash water strongly over the laundry in the rotary
drum. In this case, wash performance for the entire laundry cannot be improved.
[0009] Further, it fails to run the water flow along the rear surface of the front end wall
unless the flow of the water streamed out through the stream nozzle is substantially
flattened. To flatten the water flow, it is necessary to narrow the stream nozzle
in a flat shape. This, however, increases a pressure loss, and the increased pressure
loss reduces a flow rate, making it difficult to swiftly and evenly wet the laundry.
[0010] US 2010/0000266 A1 discloses: A washing machine has a water spray device to efficiently wet the laundry
by spraying wasting water to the laundry with uniform pressure. The washing machine
includes an outer tub, and a water spray device installed at an upper portion of the
outer tub to spray washing water. The water spray device includes a diffusion duct
for diffusing the washing water around the outer tub and a spray member provided in
the diffusion duct to spray the washing water into the outer tub.
[0011] US 2007/0107471 A1 discloses: A spraying device for a washing machine includes a body including a wall
having an outer surface, a water inlet and a channel defined therein. The channel
is in flow communication with the water inlet, and a plurality of nozzles extend through
the wall and in flow communication with the channel. The washing machine includes
a wash tub and a basket mounted within the wash tub. The basket is configured to rotate.
The nozzles include an inlet, an outlet, an inner diameter, and an outer diameter.
At least a portion of the outlet includes a surface substantially perpendicular to
a flow of water through the nozzle, and the nozzles have a length longer than a thickness
of the wall. At least a portion of the outlet is unitary with the wall outer surface.
SUMMARY OF THE INVENTION
[0012] The claim 1 describes the subject-matter of the present invention. The dependent
claims are directed to embodiments of advantage.
[0013] Advantageously, a drum-type washing machine according to the present invention comprises
a water tub for storing wash water; a rotary drum disposed rotatably in the water
tub and having an opening in a front face of the rotary drum; a motor for driving
the rotary drum; a water circulating path for circulating the wash water in the water
tub to the rotary drum; a pump for conveying the wash water in the water tub to the
water circulating path; a nozzle water path formed into an annular shape on an outer
side of a rim of the opening; a nozzle provided in the nozzle water path; and a reflector
provided in a space formed between the nozzle and the rim of the opening, wherein
the wash water is guided by the reflector from into the rotary drum through the opening.
[0014] The structure discussed above allows the wash water conveyed by the pump into the
water tub to jet over a greater area, thereby exposing the laundry agitated in the
rotary drum to the wash water more frequently. As a result, the wash water can be
supplied all over the laundry in the drum, thereby wetting the laundry uniformly,
and improving the performance of wash and rinse.
BRIEF DESCRIPTION OF DRAWINGS
[0015]
Fig. 1 is a sectional view of a drum-type washing machine in accordance with a first
embodiment of the present invention.
Fig. 2 is a sectional view of an essential part of the drum-type washing machine in
accordance with the first embodiment.
Fig. 3 is a fragmentary view taken along arrows 3 - 3 of Fig. 1 for illustrating the
first embodiment.
Fig. 4 is a sectional view of a nozzle of the drum-type washing machine in accordance
with the first embodiment.
Fig. 5 is a fragmentary view taken along arrows 3 — 3 of Fig. 1 for illustrating the
second embodiment.
Fig. 6 is a fragmentary view taken along arrows 3 — 3 of Fig. 1 for illustrating the
third embodiment.
Fig. 7 is a fragmentary view taken along arrows 3 - 3 of Fig. 1 for illustrating a
fourth embodiment of the present invention.
Fig. 8 is a fragmentary view taken along arrows 3 - 3 of Fig. 1 for illustrating a
fifth embodiment of the present invention.
Fig. 9 is a sectional view of a nozzle of a drum-type washing machine in accordance
with the sixth embodiment of the present invention.
Fig. 10 is a sectional view of a nozzle of a drum-type washing machine in accordance
with a seventh embodiment of the present invention.
Fig. 11 is a sectional view of a nozzle of a drum-type washing machine in accordance
with a eighth embodiment of the present invention.
Fig. 12 is a sectional view taken along line 12 - 12 of Fig. 5 for illustrating a
ninth embodiment of the present invention.
Fig. 13 is a sectional view taken along line 13 - 13 of Fig. 5 for illustrating a
ninth embodiment of the present invention.
Fig. 14 is a sectional view taken along line 14 - 14 of Fig. 5 for illustrating the
ninth embodiment of the present invention.
Fig. 15 is a sectional view illustrating a structure of an essential part of a nozzle
widely used in drum-type washing machines.
DETAILED DESCRIPTION OF THE INVENTION DETAILED
[0016] Exemplary embodiments of the present invention are demonstrated hereinafter with
reference to the accompanying drawings. Structural elements similar to those of an
antecedent embodiment have the same reference signs and the detailed descriptions
thereof are omitted. The present invention is not limited by the following embodiments.
In the embodiments, the opening side of the rotary drum of the drum-type washing machine
is referred to as a front, a front side, a front section, or a front face, and the
opposite side to the opening side is referred to as a rear, a rear side, a rear section
or a rear face.
Exemplary Embodiment 1
[0017] Fig. 1 is a sectional view of a drum-type washing machine in accordance with the
first embodiment of the present invention. This drum-type washing machine, as shown
in Fig. 1, comprises the following elements: housing 1, water tub 2, suspension 3,
rotary drum 4, openings 5 and 6, door 7, motor 9, protrusion 12, feed valve 15, drain
valve 19, water circulating path 20, pump 21, nozzle water path 22, nozzle 26.
[0018] The washing machine further comprises controller 32 mounted on a rear bottom in housing
1 for controlling motor 9, feed valve 15, drain valve 19, and pump 21 as well as controlling
the steps of wash, rinse, and dewatering based on a given program.
[0019] Water tub 2 shaped like a cylinder having a bottom is resiliently supported by suspension
3 in housing 1. Rotary drum 4 shaped like a cylinder having a bottom is placed rotatably
in water tub 2. Rotary axis 4a of drum 4 substantially agrees with the center line
on which rotary drum 4 rotates, and also substantially agrees with the center line
on which water tub 2 rotates. Tub 2 and drum 4 have circular openings 5 and 6 respectively
on the front, i.e. the place where door 7 is mounted. Rotary axis 4a tilts rearward
(front-up and rear-down) by, e.g. 10 - 20 degrees relative to the horizontal 4b, so
that water tub 2 can be situated in housing 1.
[0020] Confronting openings 5 and 6, door 7 is placed on the front of housing 1 for loading
or unloading the laundry into or from drum 4. Bellows 8 made of elastic material such
as rubber is placed around opening 5 of water tub 2, so that shut of door 7 bites
a rim of bellows 8 at inner face of door 7 for sealing door 7 shut.
[0021] Motor 9 is mounted at the opposite end (rear face of water tub 2) to opening 5 of
water tub 2 for driving drum 4. The rotor of motor 9 is connected to drum 4 via rotary
shaft 10 which transmits the spin of motor 9 to drum 4. Cylindrical wall 11 of drum
4 has multiple projections 12 projected toward rotary axis 4a. The laundry is caught
on projections 12 and lifted, and then falls from a height to the bottom. This action
is repeated during the rotation of drum 4. On top of that, numerous vents 13 are formed
all over cylindrical wall 11, so that when wash water is stored in water tub 2 up
to a given level, the wash water enters into drum 4 through vents 13.
[0022] Detergent container 14 is placed above water tub 2, and connected to feed valve 15
which connects with a tap of a water supply. Open or close of feed valve 15 supplies
the tap water or halts the supply to detergent container 14. Water-feed path 16 is
connected to the underside of detergent container 14 so that the detergent is supplied
to water sub 2 together with the water entered container 14.
[0023] Drain port 17 is formed on the underside of water tub 2 for discharging the wash
water stored in tub 2, and drain path 18 is connected to drain port 17 for conveying
the wash water to the outside of housing 1. Drain valve 19 is placed somewhere in
path 18 for closing path 18.
[0024] Circulating path 20 connected to drain port 17 branches off from drain path 18 so
that the wash water discharged from tub 2 can circulate via rotary drum 4 into water
tub 2 again. Circulating path 20 is laid under water tub 2 such that it extends from
the rear to the front and lies almost horizontally. Driving pump 21 placed somewhere
in circulating path 20 draws the wash water stored in water tub 2 from drain port
17 into path 20, and pressurizes the wash water flowing in path 20 for conveying it
into drum 4. This mechanism allows the wash water stored in water tub 2 to run through
path 20 and circulate to tub 2.
[0025] Nozzle water path 22 is formed inside the front face of water tub 2, to be more specific,
on the outer face of opening 5 viewed from opening 6 of drum 4 and formed annularly
(including an arc which lacked in a part of annular shape) outside of rim 23a of circular
opening 6 of drum 4. Here, "an arc which lacked in a part of annular shape" means
the shape that lacked in less than approximately 1 / 3 of annular shape in a circumferential
direction. In other words, in the inventions, the shape of arc more than approximately
2/3 of annular shape is construed as annular shape. Nozzle water path 22 is shaped
like a circle, which is approx. concentric (including concentric) with opening 5 of
tub 2 and opening 6 of drum 4. Inner rim 23a of path 22 is placed outside rim 23a
of opening 6 in the radial direction.
[0026] Next, a structure around nozzle 26 in accordance with the first embodiment is demonstrated
with reference to Fig. 2 which shows a sectional view of an essential part of the
drum-type washing machine in accordance with the first embodiment.
[0027] As shown in Fig. 2, flow-in port 25 is formed at an upper section of circulating
path 20 such that port 25 communicates with path 20. Nozzles 26 are provided at an
upper section of nozzle water path 22 which is formed annularly (including an arc
which lacked in a part of annular shape) outside rim 23a of opening 6. Space 27 is
provided between nozzle 26 and rim 23a. Reflector 28 is provided in space 27 for the
wash water jetted into space 27 to reflect thereon toward opening 6. The jetted wash
water can be thus guided to opening 6 and then into drum 4.
[0028] Reflector 28 is formed annularly around opening 5 and confronts the front of rotary
drum 4. Reflector 28 includes hit-face 28a tilting relative to the jet stream from
nozzle 26. This tilt avoids scattering the wash water in all directions and allows
the jet stream of wash water to land stably on hit-face 28a, thereby diffusing the
wash water along hit-face 28a. As a result, the wash water can be sprayed over the
laundry in drum 4 in a stable manner.
[0029] A smaller tilt angle of hit-face 28a relative to the jet direction from nozzle 26
allows the jet stream to land more stably on hit-face 28a and diffuse over a greater
area. However, if reflector 28 is formed of only hit-face 28a, a small tilt angle
of hit-face 28a fails to guide the jet stream into the inner part of drum 4, and the
wash water is sprayed onto only the clothes located at the front part of drum 4.
[0030] To avoid the foregoing possible problem, guide-face 28b is formed on the inner rim
of reflector 28, and the tilt angle of reflector 28 relative to the jet direction
is set smaller than that of guide-face 28b. This structure allows setting the tilt
angle of hit-face 28a gently relative to the jet direction from nozzle 26, whereby
the jet stream of the wash water can land at hit-face 28a more steadily and diffuse
over a wider area regardless of the direction which guides the jet stream into drum
4. The jet stream is guided by guide-face 28b along the direction toward inside drum
4, so that the wash water can be sprayed over the laundry in drum 4 in a steady diffusing
manner.
[0031] The length of guide-face 28b is set shorter than that of hit-face 28a because it
is necessary for hit-face 28a to have a greater contacting area than a hitting area
of the jet stream so that the jet stream can stably land on hit-face 28a and diffuse.
Since guide-face 28b functions only as changing the jet stream direction, a smaller
contacting area of guide-face 28b than that of hit-face 28a works good. This structure
allows minimizing the reduction in the flow velocity at guide-face 28b, thereby spraying
the wash water more strongly over the laundry. As a result, the performance of wash
and rinse can be improved.
[0032] As discussed above, the jet stream from nozzle 26 should run to reflector 28, so
that a water-guide wall, which is regularly used in a conventional washing machine,
is omitted from Fig. 2. Omission of the water-guide wall allows the jet stream from
nozzle 26 to flow into space 27, and then hit the hit-face 28a, and diffuse into drum
4 through opening 6 with the aid of guide-face 28b. The mechanism allows nozzle 26
to be located away from the rim23a of opening 6 of drum 4 while the jet stream from
nozzle 26 can be guided into rotary drum 4 free from adverse resistance from the wall.
As a result, this structure allows minimizing the reduction in the flow velocity,
thereby spraying the wash water more strongly over the laundry in drum 4.
[0033] Nozzle 26 is not necessarily shaped like a flat tube which is required for running
along the water guide wall, but its cross-sectional area should equal to that of the
flat one, so that the cross section of nozzle 26 is shaped like, e.g. a round hole
because this shape invites the least pressure loss. This shape allows minimizing the
reduction in volumetric flow of the wash water jetted from nozzle 26, so that a sufficient
quantity of the wash water can be supplied to the laundry in drum 4.
[0034] Reflector 28 diffuses the bar-shaped jet stream, so that the wash water can be sprayed
in a wide area over the laundry in rotary drum 4. As a result, the performance of
wash and rinse can be improved.
[0035] Next, a structure of the drum-type washing machine in accordance with the first embodiment
is described hereinafter with reference to Fig. 3, which is a fragmentary view taken
along arrows 3 - 3 of the drum-type washing machine shown in Fig. 1. Fig. 3 shows
the structure viewed from opening 6 of rotary drum 4.
[0036] As shown in Fig. 3, nozzle water path 22 is provided with flow-in port 25 at the
lower a section. Nozzle water path 22 runs along the shape of water tub 2, so that
path 22 shapes annularly (including an arc which lacked in a part of annular shape),
and it branches off at port 25 to both sides and the two branched paths extend to
end parts 22a respectively. The water flowing in path 22 is split into two streams
which run long and annular shape (including an arc which lacked in a part of annular
shape) such that the streams surround opening 5. This split makes each one of the
streams short, which reduces the pressure loss in nozzle water path 22. This structure
allows applying sufficient pressures to each one of nozzles 26a - 26g (detailed later)
so that the velocity of jet stream from nozzle 26 can be appropriately maintained,
and therefore, the wash water can be sprayed all over the laundry in drum 4. Nozzle
water path 22 is not necessarily provided with end parts 22a, so that path 22 can
be formed seamlessly. In this case, since the water flow is also split into two directions
at flow-in port 25, an advantage similar to what is discussed above is obtainable.
[0037] The wash water flows into nozzle water path 22 from flow-in port 25 along the direction
toward rotary axis 4a (direction indicated by arrow C in Fig. 3). This structure allows
the streams to branch off smoothly in two directions, thereby applying sufficient
pressures onto respective nozzles 26a - 26g. As a result, this structure can increase
the velocity of the jet streams.
[0038] If the wash water pumped out to nozzle water path 22 dashes against each other at
port 25, jet force is lowered, so that path 22 is preferably structured to avoid this
possible problem. For instance, a path running clockwise and another path running
counterclockwise are prepared so that the wash water cannot dash against each other
at port 25.
[0039] As shown in Fig. 3, multiple nozzles 26a - 26g provided in nozzle water path 22 are
supposed to jet the wash water toward rotary axis 4a (e.g. nozzle 26c is supposed
to jet the wash water along the alternate long and short dash line); however, the
jet direction is shifted from the alternate long and short dash line to the arrow
line by angle θ1. Respective nozzles 26a - 26g are thus shifted toward the same direction
by the same angle θ1 (shift angle).
[0040] This structure allows enlarging the area over which the wash water can be sprayed,
so that the wash water can be supplied all over the laundry in an efficient manner.
[0041] In this case, if the shift angle is too great, the wash water cannot be sprayed around
rotary axis 4a. To avoid this possible problem, shift angle θ1 is set to be an approx.
half of angle θ2 (e.g. 10 - 30 degrees) which defines the spread of the wash water
diffusing along the rotary direction of drum 4, so that shift angle θ1 should be set
at, e.g. 5 - 15 degrees.
[0042] Multiple nozzles 26 (25a - 26g) are formed at locations distant from rim 23a of opening
6 of rotary drum 4 as shown in Fig. 2. This structure allows nozzles 26 to spray the
diffusing wash water over the laundry in drum 4 without exposing nozzles 26 to opening
6 of drum 4. As a result, the laundry can be loaded or unloaded into/from drum 4 free
from being caught on opening 6 and being torn. On top of that, the laundry can be
loaded or unloaded with ease, so that better usability can be expected.
[0043] It is preferable to form bulge section 29 by swelling out a part of nozzle water
path 22 toward rotary axis 4a.
[0044] An advantage of nozzle 26 formed at bulge section 29 is demonstrated hereinafter
with reference to Figs. 3 and 4. Fig. 4 is a sectional view of the nozzle of the drum-type
washing machine in accordance with the first embodiment.
[0045] As shown in Fig. 4, bulge section 29 swelling out toward a wash water stream direction
is formed to a part of nozzle water path 22, and nozzle hole 31 shaped like, e.g.
a circle, is formed on flat part 30 of bulge section 29. Thickness (depth) "L" of
nozzle hole 31 is set not greater than diameter "d" thereof. An extension of flat
part 30 runs across the direction of the wash water jetted from nozzle hole 31 at
right angles, and as shown in Fig. 3, tilts by the shift angle θ1 of nozzle 26.
[0046] The wash water at bulge section 29 is isolated from the main stream (indicated by
dotted line with arrow in Fig. 4) which flows in nozzle water path 22 to end part
22a, so that the main stream does not so much affect multiple nozzles 26a - 26g shown
in Fig. 3. This mechanism thus prevents the streams jetted from multiple nozzles 26a
- 26g from being disarranged, and makes the jet direction steadily. The jet streams
can be contracted, whereby the velocities of the streams can be increased. Stronger
jet stream thus can be expected.
[0047] The foregoing mechanism is detailed hereinafter with reference to Fig. 15 that is
a sectional view illustrating a structure of an essential part of a nozzle widely
used in drum-type washing machines.
[0048] As shown in Fig. 15, in general, inner wall 103 of nozzle water path 102 slants gently
and smoothly toward nozzle hole 101, thereby narrowing nozzle hole 101, in order to
minimize pressure-loss. This structure keeps preventing the water flowing through
path 102 from separating from inner wall 103 until just before the flow is jetted
from nozzle hole 101, otherwise this separation would incur turbulence. Nozzle 100
inviting smaller pressure loss is thus obtainable. In this case, under the condition
of the same quantity of flow, the velocity of the jet stream from nozzle hole 101
is determined by the cross sectional area of hole 101, so that a greater quantity
of flow or a smaller cross sectional area of hole 101 is needed to increase the velocity
of the jet stream.
[0049] Increment in the circulation flow running through circulating path 20 which supplies
the wash water to nozzle water path 22 lowers the water level in water tub 2, thereby
inviting air with ease to enter pump 21, which then falls into "air-biting" state,
and the circulation flow decreases contrary to the expectation. The increment in the
quantity of flow in circulating path 20 is thus limited when a washing is done with
a small amount of water stored in water tub 2. At this time, waste thread produced
from the laundry will clog path 20, and to avoid such a reliability problem, there
should be a limitation on reducing the cross sectional area of nozzle hole 31.
[0050] As shown in Fig. 4, bulge section 29 swelling out toward rotary axis 4a of drum 4
is thus formed, and flat part 30 formed approx. vertically (including vertical) relative
to the extending direction of nozzle hole 31 is also provided around hole 31. The
flow around inner wall face 22b, formed by bulge section 29, of nozzle water path
22 tries to flow along inner wall face 22b due to its viscosity; however, the stream
jetted from hole 31 is separated from the inside wall of nozzle hole 31 because inner
wall face 22b sharply bends by approx. 90 degrees.
[0051] The cross sectional area "B" of the jet stream thus becomes smaller than the cross
sectional area "A" of nozzle 31, namely, the stream is contracted. Nozzle 26 in accordance
with this first embodiment achieves a greater velocity of flow and a stronger jet
stream than a conventional nozzle under the condition where nozzle 26 has the same
cross sectional area as the conventional one and both of the subject nozzles and the
conventional ones are used in the same quantity of flow.
[0052] The sectional view of nozzle hole 31 cut along line 4 - 4 of Fig. 4 is, e.g. a circle,
and this structure allows contracting the jet stream uniformly, preventing the jet
stream from being disarranged, and jetting the wash water along a given direction
for spraying the wash water over the laundry. Circular nozzle hole 31 has no projections
therein, so that the waste thread produced from the laundry is hardly caught in hole
31, which can be thus prevented from being clogged by the waste thread.
[0053] Thickness "L" of nozzle hole 31 is set not greater than diameter "d" thereof, because
if the length of hole 31 along the jet direction is too long, the contracted flow
separated from the inside wall of hole 31 flares gradually before the flow is jetted,
which cancels the advantage of increasing the velocity of flow. This is the reason
why thickness "L" of nozzle hole 31 is preferably set not greater than diameter "d"
thereof.
[0054] The structure discussed above allows increasing the velocity of the stream jetted
from nozzle hole 31, and increasing the strength of the wash water jet stream.
[0055] Starting operation of the foregoing drum-type washing machine is demonstrated hereinafter,
and other operations, e.g. rinse, dewatering, spin-dry, stay the same as those of
the conventional washing machine.
[0056] First , open door 7 for loading laundry, e.g. clothes, into rotary drum 4 before
driving the machine, which then senses an amount of the laundry.
[0057] Next, open feed valve 15 for wash water to dissolve detergent stored in container
14, and this wash water enters water tub 2 via water-feed path 16.
[0058] Then sense a water level of the wash water stored in water tub 2 with a water level
sensor (not shown). To be more specific, the water level sensor senses the amount
of water determined in response to an amount of the laundry. Then halt the water supply
before starting the washing. Motor 9 rotates drum 4 forward or backward, and the laundry
accommodated in drum 4 is lifted along the rotating direction with projections 12
provided on cylindrical wall 11 of drum 4, and then the laundry falls. The lift &
fall action, referred to as "tumbling", washes the laundry.
[0059] At this time, the water level of the wash water is preferably set appropriately to
obtain effective tumbling (beat wash). However, when the water in tub 2 stays at a
low level, the wash water cannot permeate throughout the laundry, so that the wash
water in tub 2 is drawn by pump 21 into circulating path 20 via drain port 17 provided
at the bottom of tub 2, and the wash water is then jetted over the laundry in drum
4.
[0060] To be more specific, as shown in Fig. 1, pump 21 pumps the wash water into water
tub 2, and the wash water then runs through circulating path 20, passes through flow-in
port 25 provided at nozzle water path 22, and flows into nozzle water path 22. The
wash water is then branched off to both sides and runs through annularly formed long
path 22 to end parts 22a. The wash water is then guided to multiple nozzles 26 (e.g.
seven nozzles 26a - 26g are available in Fig. 3). At least three nozzles 26 are needed.
The wash water is jetted from nozzles 26a - 26g in a bar-like shape into space 27
formed at rotary axis 4a side.
[0061] As shown in Fig. 2, the wash water jetted into space 27 hits against hit-face 28a
of reflector 28, and reflects toward opening 6 of rotary drum 4. The wash water then
diffuses along the rotating direction of drum 4, and the wash water is jetted from
around rim 23a of opening 6 into drum 4 with the aid of guide-face 28b.
[0062] In this embodiment, jet directions "a" (indicated in a solid line with arrow in Fig.
3) of respective nozzles 26a - 26g are shifted by angle θ1 from the directions (indicated
in an alternate long and short dash line in Fig. 3) directed to rotary axis 4a. This
structure allows jetting the wash water uniformly in a wider area, so that the laundry
agitated in drum 4 is more frequently exposed to the wash water. As a result, the
wash water can be sprayed all over the laundry, and the performance of wash and rinse
can be improved.
[0063] The jet directions of wash water from multiple nozzles 26 (26a - 26g) can be shifted
from the direction to rotary axis 4a by different angles although they are shifted
in unison as discussed previously. This structure also allows jetting the wash water
uniformly in a wider area, so that the laundry agitated in drum 4 is more frequently
exposed to the wash water. As a result, the wash water can be sprayed all over the
laundry, and the performance of wash and rinse can be improved.
[0064] At least one nozzle, e.g. nozzle 26g, among multiple nozzles 26 is preferably placed
close to the upper end of rim 23a of opening 6 so that nozzle 26g can jet the wash
water into drum 4. This structure allows spraying the wash water from around the upper
most point to the laundry, and the wash water jetted over the laundry flows downward
due to gravitation, thereby wetting the laundry covered with the other laundry.
[0065] The starting operation is discussed above, and this operation can be used at the
rinse, so that pump 21 works even at the rinse, and rinse water can be sprayed uniformly
all over the laundry. As a result, the laundry can be rinsed efficiently within a
shorter time. When a given number of rinses is completed, open drain port 19 for discharging
the rinse water, and spin rotary drum 4 for dewatering the rinse water contained in
the laundry. The dewatering step is done for a given time before the operation ends.
A drying device can be added for carrying out a drying step following the dewatering
step.
Exemplary Embodiment 2
[0066] Fig. 5 is fragmentary view taken along arrows 3 - 3 of Fig. 1 for illustrating the
second embodiment. The second embodiment differs from the first one in placing nozzle
water path 22 at any place except just under (along the perpendicular direction from)
rotary axis 4a. Other structures remain unchanged from those of the first embodiment,
so that detailed descriptions thereof are borrowed from the first one.
[0067] The wash water usually gathers at a lower section of drum 4, so that the laundry
lying in the lower part is always supplied with the wash water. The wash water jetted
from nozzle 26 may be sprayed over the laundry from under rotary axis 4a upward along
the perpendicular direction. However, since the laundry lying in the lower part of
drum 4 is usually supplied with the wash water, this upward jet stream produces poor
effect. Nozzle water path 22 is thus placed at any place other than the place just
under (along perpendicular direction from) rotary axis 4a. This structure allows supplying
the wash water efficiently and uniformly all over the laundry, so that the performance
of wash and rinse can be improved.
[0068] In this second embodiment, as shown in Fig. 5, three nozzles 26 (26a - 26c) are provided
for instance, and nozzle 26a is apart from nozzle 26c by less than 180 degrees. No
nozzle water path 22 exists between nozzle 26a and nozzle 26c. To be more specific,
nozzle water path 22 is shaped like an arc including approx. 240 degrees and surrounding
rotary axis 4a. Respective nozzles 26a - 26c are equidistantly placed, i.e. at equal
intervals of 120 degrees.
[0069] To be more specific, nozzle 26a is placed at left lower side viewed from the opening
of the rotary drum and relative to rotary axis 4a, and nozzle 26c is placed at right
lower side, and nozzle 26b is placed at upper side. In other words, at least one nozzle
is provided at each place, i.e. the upper, lower, right and left sides relative to
rotary axis 4a.
[0070] This structure allows multiple nozzles 26a - 26c to jet the wash water along upward,
downward, leftward, and rightward directions to the laundry in drum 4 while the jet
streams diffuse along the rotating direction. The laundry rotated following the rotation
of drum 4 can be exposed to the wash water more frequently regardless of the location
of the laundry in drum 4, so that the wash water can be sprayed uniformly all over
the laundry.
[0071] Flow-in port 25, through which the wash water flows into nozzle water path 22, is
formed at a place other than around the upper end of nozzle water path 22.
[0072] The reason of this limited location is this: When pump 21 pumps out the wash water
to nozzle water path 22 through flow-in port 25, the air initially trapped in path
22 is exhausted from nozzles 26a - 26c, and then path 22 is filled with the wash water.
Usually the air tends to gather around the upper end of path 22, so that a supply
of the wash water from the upper end of path 22 will stir the air gathered, and then
the air disperses in path 22 if nozzle water path 22 is long.
[0073] At the beginning, streams of water mixed with air are jetted from nozzles 26, so
that the streams are disarranged and louder noises are produced at the jet. Flow-in
port 25 is thus placed at the place in order to avoid the foregoing problems, namely,
at the place other than around the upper end of path 22, thereby preventing the air
from being stirred and preventing the jet water stream from being mixed with air.
The disarrangement of the jet streams and the loud noise at the jet thus can be prevented.
[0074] In this second embodiment, nozzle water path 22 should not be laid just under rotary
axis 4a (along the perpendicular direction); however, path 22 can be laid just under
axis 4a while nozzles 26 should not be placed there. This structure allows spraying
the wash water efficiently and uniformly all over the laundry, and the performance
of wash and rinse can be improved.
Exemplary Embodiment 3
[0075] Fig. 6 is a fragmentary view taken along arrows 3 - 3 of the drum-type washing machine
shown in Fig. 1 for illustrating the third embodiment of the present invention. The
third embodiment employs nozzles 26a - 26f that jet the wash water along directions
other than the perpendicular direction to rotary axis 4a. The other structures remain
unchanged from those of the first embodiment, so that the detailed descriptions thereof
are borrowed from the first one.
[0076] Since the wash water stays at a lower section of rotary drum 4, the laundry there
is supplied with the wash water. Nozzles 26a - 26f thus jet the wash water along the
directions other than the perpendicular direction which is directed to just under
rotary axis 4a. This structure allows spraying the wash water efficiently and uniformly
all over the laundry, and the performance of wash and rinse can be improved.
Exemplary Embodiment 4
[0077] Fig. 7 is a fragmentary view taken along arrows 3 - 3 of the drum-type washing machine
shown in Fig. 1 for illustrating the fourth embodiment of the present invention. The
fourth embodiment employs nozzles 26a - 26g that are equidistantly apart from each
other with intervals of angle θ3 therebetween. The other structures remain unchanged
from those of the first embodiment, so that the detailed descriptions thereof are
borrowed from the first one.
[0078] As shown in Fig. 7, nozzle water path 22 is laid annularly (including an arc which
lacked in a part of annular shape) to surround almost entire circumference around
rotary axis 4a. The number of multiple nozzles 26 is determined in response to the
length of path 22. For instance, seven nozzles 26a - 26f are equidistantly placed
in path 22 with approx. the same intervals (including the same intervals) of angle
θ3 therebetween, i.e. in this case angle θ3 is 360/7 degrees.
[0079] This structure allows nozzles 26a - 26f to jet the wash water uniformly into drum
4. As a result, the laundry can be exposed more frequently to the wash water, and
the wash water can be supplied more uniformly to the laundry.
[0080] In this fourth embodiment, the wash water is jetted toward rotary axis 4a, i.e. the
wash water to be supplied to the laundry is jetted toward the center of drum 4. This
structure allows the wash water to resist flowing out through vents 13 formed on cylindrical
wall 11 to the outside of drum 4. As a result, the laundry can be wetted efficiently.
Exemplary Embodiment 5
[0081] Fig. 8 is a fragmentary view taken along arrows 3 - 3 of the drum-type washing machine
shown in Fig. 1 for illustrating the fifth embodiment of the present invention. The
fifth embodiment employs nozzles 26a - 26g of which at least one jet direction is
different from the other jet directions. This is the different point from the first
embodiment. To be more specific, a jet direction from, e.g. nozzle 26c and a direction
toward rotary axis 4a from nozzle 26c viewed from the opening of drum 4 includes an
angle. The other nozzles also form angles between their jet direction and the directions
toward axis 4a. In this fifth embodiment, at least one of the foregoing angles is
formed differently from the other angles. The other structures remain unchanged from
those of the first embodiment, so that the detailed descriptions thereof are borrowed
from the first one.
[0082] As shown in Fig. 8, angle θ4 formed by nozzle 26c differs from angle θ5 formed by
nozzle 26d such that angle θ5 is greater than angle θ4.
[0083] In a case where a large amount of laundry is loaded into drum 4, the laundry moves
a little in drum 4 such that it rotates together with drum 4.
[0084] The structure discussed above allows the jet streams from nozzles 26a - 26g over
the laundry to change their directions following the rotation of drum 4. As a result,
the wash water can be supplied efficiently and uniformly all over the laundry.
Exemplary Embodiment 6
[0085] Fig. 9 is a sectional view of a nozzle of a drum-type washing machine in accordance
with the sixth embodiment of the present invention. In this sixth embodiment, nozzle
hole 31 is tapered, i.e. the diameter of hole 31 at the flow-in side of the wash water
is smaller than the diameter at the flow-out side thereof. The other structures remain
unchanged from those of the first embodiment, so that the detailed descriptions thereof
are borrowed from the first one.
[0086] To be more specific, as shown in Fig. 9, nozzle hole 31 of nozzle 26 is tapered and
its diameter at the flow-out side is "d1" and the one at the flow-in side is "d2",
and d1 > d2 is established.
[0087] The flow around inner wall 22b of nozzle water path 22 tries to flow as close as
possible to inner wall 22b due to the viscosity; however, the tapered hole 31 bends
sharply inner wall 22b by well over 90 degrees at the place where the wash water is
jetted from hole 31. The flow of wash water thus separates at a greater distance than
the conventional one from the inside wall of hole 31, so that the flow is contracted.
[0088] The structure discussed above thus contracts the jet stream of wash water for increasing
the velocity thereof. As a result, stronger jet streams can be expected, and the performance
of wash and rinse can be improved.
Exemplary Embodiment 7
[0089] Fig. 10 is a sectional view of a nozzle of a drum-type washing machine in accordance
with the seventh embodiment of the present invention. In this seventh embodiment,
flat part 30 where nozzle hole 31 is formed is swelled toward the flow-in side. The
other structures remain unchanged from those of the first embodiment, so that the
detailed descriptions thereof are borrowed from the first one.
[0090] To be more specific, as shown in Fig. 10, on flat part 30, nozzle hole 31 forms an
uphill slope toward the flow-in side, thereby increasing the height by "H" at hole
31, in other words, the location of hole 31 swells up toward the flow-in side by height
"H". The swell of flat part 30 can form either a slope or an arc.
[0091] In general, the flow around inner wall 22b of nozzle water path 22 tries to flow
close to inner wall 22b due to the viscosity; however, the structure discussed above
bends sharply inner wall 22b by well over 90 degrees at the place where the wash water
is jetted from hole 31. The flow of wash water thus separates at a greater distance
than the conventional one from the inner wall of hole 31, so that the flow is contracted.
[0092] The structure discussed above thus contracts the jet stream of wash water for increasing
the velocity thereof. As a result, stronger jet streams can be expected, and the performance
of wash and rinse can be improved.
Exemplary Embodiment 8
[0093] Fig. 11 is a sectional view of a nozzle of a drum-type washing machine in accordance
with the eighth embodiment of the present invention. In this eighth embodiment, cylindrical
rib is formed in a protruding manner on flat part 30 at the flow-in side of nozzle
hole 31. The other structures remain unchanged from those of the first embodiment,
so that, the detailed descriptions thereof are borrowed from the first one.
[0094] In general, the flow around inner wall 22b of nozzle water path 22 tries to close
to inner wall 22b due to the viscosity; however, cylindrical rib 22c protruding from
hole 31 toward the flow-in side sharply bends inner wall 22b by approx. 180 degrees,
so that the flow is separated distantly from the inside wall of hole 31 and the flow
can be thus more contracted.
[0095] As a result of this greater contraction, the velocity of flow increases, and stronger
jet streams can be expected, and the performance of wash and rinse can be improved.
Exemplary Embodiment 9
[0096] Fig. 12 - Fig. 14 are sectional views of a nozzle of the drum-type washing machine
in accordance with the ninth embodiment. Fig. 12 is a sectional view taken along line
12 - 12 in Fig. 5, Fig. 13 is a sectional view taken along line 13 - 13 in Fig. 5,
and Fig. 14 is a sectional view taken along line 14 - 14 in Fig. 5.
[0097] Guide-face 28b is formed on reflector 28 which leads the wash water jetted from each
one of multiple nozzles 26a - 26c into rotary drum 4. Guide-face 28b includes a slope,
of which angular part opposite to each one of nozzles 26a - 26c, tilts differently
from another angular part thereof. There are at least two different tilt angles. This
is a different point from the first embodiment. The other structures remain unchanged
from those of the first embodiment, so that the detailed descriptions thereof are
borrowed from the first one.
[0098] To be more specific, hit-faces 28a, against which the wash water jetted from nozzles
26a - 26c hit, of nozzles 26a - 26c tilt at the same angle; however, guide-faces 28b,
which guide the wash water hit against hit-faces 28a to opening 6 of drum 4, tilts
differently among nozzles 26a - 26c.
[0099] As shown in Fig. 12, the wash water jetted from nozzle 26a hits against hit-face
28a and flows along the arrow to guide-face 28b, of which function is to guide the
wash water hit against hit-face 28a to opening 6, and guide-face 28b greatly tilts
toward opening 6 relative to the jet stream of wash water. The wash water thus jets
along direction S1.
[0100] As shown in Fig. 13, guide-face 28b of nozzle 26b tilts smaller than that of nozzle
26a, then the wash water jets along direction S2.
[0101] As shown in Fig. 14, guide-face 28b of nozzle 26c tilts smaller than other two guides
26b, then the wash water jets along direction S3.
[0102] The structure discussed above allows nozzle 26a to jet the wash water into drum 4
at the inside-front of drum 4, while nozzles 26b and 26c jet the wash water into drum
4 at inner-deep (bottom of drum 4), because each one of guides 26b tilt at different
angles.
[0103] In other words, the wash water jetted from multiple nozzles 26a - 26c hits against
respective hit-faces 28a, which tilt at the same angle, so that each wash-water diffuses
in the same manner, and each guide-face 28b changes a direction along which the each
diffusing water is supplied to the laundry.
[0104] In the case where a large amount of laundry is loaded in drum 4 and the laundry rotates
together with drum 4, the direction of supplying the wash water can be changed in
response to the rotation of drum 4, so that the wash water can be supplied efficiently
and uniformly to all over the laundry.
[0105] Note that, the structure described in one of the embodiments discussed previously
can be combined with the other embodiments, or combined with a part of the other embodiments.
1. Trommelwaschmaschine, die umfasst:
einen Wasserbottich (2) zum Speichern von Waschwasser;
eine Drehtrommel (5), die drehbar in dem Wasserbottich (2) angeordnet ist und eine
Öffnung aufweist;
einen Motor (9) zum Antreiben der Drehtrommel (4);
einen Wasserzirkulationsweg (20), um das Waschwasser in dem Wasserbottich (2) zu der
Drehtrommel (4) zirkulieren zu lassen;
eine Pumpe (21) zum Befördern des Waschwassers in dem Wasserbottich (2) zu dem Wasserzirkulationsweg
(20);
einen Düsenwasserweg (22), der in eine Ringform auf einer Außenseite eines Rands (23a)
der Öffnung (5) gebildet ist;
eine Düse (26), die in dem Düsenwasserweg (22) vorgesehen ist; und
einen Reflektor (28), der in einem Raum (27), der zwischen der Düse (26) und dem Rand
(23a) der Öffnung (5) gebildet ist, vorgesehen ist, dadurch gekennzeichnet, dass
die Drehtrommel (4) die Öffnung (5) in einer Vorderfläche der Drehtrommel aufweist;
und
das Waschwasser durch den Reflektor (28) durch die Öffnung (5) in die Drehtrommel
(4) geführt wird,
wobei der Reflektor (28) in einer Ringform, die der Vorderfläche der Drehtrommel (4)
gegenüber liegt, vorgesehen ist, wobei der Reflektor (24) eine Auftrefffläche (28a),
auf die das Waschwasser, das von der Düse (26) abgestrahlt wird, auftrifft, und eine
Führungsfläche (28b) zum Führen des Waschwassers, das auf die Auftrefffläche (28a)
auftrifft, in die Öffnung (5) aufweist.
2. Trommelwaschmaschine nach Anspruch 1, wobei die Auftrefffläche (28a) des Reflektors
(28) mit einer Neigung in einem kleinerem Winkel als eine Neigung der Führungsfläche
(28b) gebildet ist.
3. Trommelwaschmaschine nach Anspruch 2, wobei
die Führungsfläche (28b) zum Führen des Waschwassers eine Länge aufweist, die kleiner
als eine Länge der Auftrefffläche (28a) ist.
4. Trommelwaschmaschine nach einem der Ansprüche 2 oder 3, wobei mehrere Düsen (26) vorgesehen
sind und wobei die Führungsfläche (28b) wenigstens zwei unterschiedliche Neigungswinkel
umfasst.
5. Trommelwaschmaschine nach Anspruch 1,
wobei die Düse (26) einen gewölbten Anteil aufweist, der wenigstens einen flachen
Abschnitt und eine Verdickung in eine Richtung, wo das Waschwasser ausströmt, aufweist
und ein Düsenloch in dem gewölbten Anteil gebildet ist.
6. Trommelwaschmaschine nach Anspruch 5, wobei
das Düsenloch der Düse (26) in eine Ringform gebildet ist.
7. Trommelwaschmaschine nach Anspruch 5, wobei die Dicke (L) des Düsenlochs (31) gleich
oder kleiner als ein Durchmesser des Düsenlochs (31) ist.
8. Trommelwaschmaschine nach Anspruch 5, wobei
das Düsenloch der Düse (26) konisch zulaufend ist, damit es an einer Ausflussseite
einen größeren Durchmesser als an einer Einflussseite des Waschwassers aufweist.
9. Trommelwaschmaschine nach Anspruch 5, wobei
der flache Abschnitt der Düse (26), der das Düsenloch aufweist, zur Einflussseite
des Waschwassers gewölbt ist.
10. Trommelwaschmaschine nach Anspruch 5, wobei
die Düse (26) mit einer zylindrisch vorstehenden Rippe an der Einflussseite des Waschwassers
des Düsenlochs, die in dem flachen Abschnitt gebildet ist, versehen ist.
11. Trommelwaschmaschine nach einem der Ansprüche 5 bis 10, wobei
die Düse (26) eine Waschwasserstrahlrichtung aufweist, die bei Betrachtung von einer
Öffnungsflächenseite der Drehtrommel (4) aus einer Richtung, die eine Drehachse der
Drehtrommel (4) kreuzt, in der gleichen Richtung verschoben ist.