KR20100127701A - Washing machine - Google Patents

Abstract

PURPOSE: A washing machine is provided to enable the discharged water to be widely scattered into the tub. CONSTITUTION: A washing machine comprises a tub(8), a mixing blade(9), an inner blade(18), a pump chamber(22), waterway covers(20) and expandable parts(29). The tub is installed in a body. The mixing blade is rotatably installed on the lower part in the tub. The inner blade is formed in the mixing blade. The pump chamber is formed on the lower part in the tub and holds the inner blade. The waterway cover is extended to the upper part from the pump chamber along the tub wall and forms a circulating waterway between inner sides of the tub wall. The expandable part is formed on the upper part of the waterway cover to be expanded toward the inside of the tub. A transverse slit shape of discharge hole is formed on the expandable part.

Description

Washing machine {WASHING MACHINE}

The present invention relates to a washing machine which raises the washing water by using the pump action of the inner blade formed on the inner surface of the stirring vane disposed in the lower part of the washing tank, and allows the raised washing water to be discharged from the upper side into the washing tank.

A washing machine having a tubular washing tank having a bottom which has a conventional upper surface opened, and washing laundry by rotating a stirring blade (pulsator) provided in the lower portion of the washing tank, wherein the inner surface side of the stirring blade is used. The inner blade which pumps a space part is integrally provided with the said stirring blade, and also forms the circulation channel which extends above the washing tank from the said space part (functioning as a pump room), and the washing tank of the washing tank from the upper part of the said circulation channel. It is known to consist of the structure which provided the opening part (outlet port) of slit shape horizontally long toward inside (for example, refer Unexamined-Japanese-Patent No. 2001-347095).

In the washing operation by the rotary drive of the stirring vane, the washing water is raised from the pump chamber by the pumping action of the internal vane which rotates at the same time, and the water is discharged in the washing tank from the opening of the upper portion in the washing tank. To repeat the cycle. Along with the circulating action of the washing water, the discharged water from the upper portion of the circulation water passage is sprayed with washing water that tends to be exposed and exposed on the washing water surface in the tank to improve washing performance.

In the above configuration, it is preferable that the discharged water from the upper portion of the circulating water can be sprinkled onto the water film and sprinkled on most of the laundry in a sprinkled state, and evenly sprayed washing water irrespective of the position of the laundry.

Thus, for example, as described in Japanese Patent Laid-Open No. 2001-347095, a concave portion is provided on the bottom of the balancer at the upper part of the washing tank (with a dehydration tank), and water received from the concave portion is raised. We want to expand the shape to obtain the watering state.

However, in this case, since the balancer has a unique configuration, it is not efficient, such as incompatibility with the balancer of other washing machines with different washing capacity, etc., and the assembly work is complicated.

In addition, although a channel cover is disposed to form a circulation channel between the inner wall surfaces of the washing tank, as the discharge port formed in the middle of the height direction of the water channel cover, the slit-shaped opening is made to extend as horizontally as possible, and the discharge water is made into the washing tank. Facing inward (inside the tank), it is a water film that can be sprayed extensively.

However, there is a limit to the size of the waterway cover, and for example, the entire waterway cover can be protruded inward to the inside of the bath, or the surface area can be increased by rotating the laundry (commonly referred to as "fabric rotation") or resisting the flow of water flow. As a result, the rotational motion of the laundry is inhibited, and the inhibition of the rotational motion greatly affects the cleaning effect.

For this reason, there are limitations in the size and shape of the discharge port during practical use, and it is a phenomenon that it cannot be easily coped with.

The present invention can be sprayed as a fan-shaped water film in which the discharge water is greatly expanded to the laundry in order to solve the above problems, and the improvement of the cleaning performance can be expected by reducing the rotational motion of the laundry, that is, the fabric rotation being inhibited. It is an object to provide a washing machine.

In order to achieve the above object, a washing machine of the present invention includes a tubular laundry tank having a bottom installed in a main body, a stirring blade rotatably disposed at a lower portion of the washing tank, an inner wing formed on an inner surface of the stirring blade, and a bottom in the washing tank. A pump chamber formed to receive the inner wing, and a channel cover extending upwardly from the pump chamber along the washing tank wall and forming a circulation channel between the washing tank wall inner surface,

The swelling part which swells toward the inside of the said washing tank is formed in the upper part of the said channel cover, The slit-shaped discharge port horizontally long is formed in this bulge part, It is characterized by the above-mentioned.

According to the said means, since the discharge port was provided in the bulging part, it can form large in a slit shape horizontally long, and can obtain a fan-shaped water film largely in the horizontal direction. Therefore, the discharged water can be sprayed widely toward the inside of the tank. In addition, since the swelling portion is provided on the upper portion of the channel cover, there is less possibility of inhibiting the rotation of the fabric, and a washing machine capable of improving the cleaning performance can be provided.

BRIEF DESCRIPTION OF THE DRAWINGS The longitudinal side view which expands and shows the principal part of the dehydration and washing tank which shows the 1st Embodiment of this invention applied to the washing | cleaning combined use for dehydration,
Figure 2 is a side view of the main part schematically showing the overall configuration of the washing machine combined with dehydration,
3 is a cross-sectional view taken along the line AA in FIG. 1;
4 is a cross-sectional view taken along the line BB of FIG. 1;
FIG. 5 is an enlarged vertical sectional side view of the main portion of the circulation channel showing the second embodiment of the present invention; FIG.
6 is a diagram illustrating a rotation control pattern of a plurality (a, b, c, d) by stirring vanes corresponding to the strength "strong" and "weak" operation of the washing water flow;
7 is a plan view of a dewatering and washing tank illustrating a falling region of discharged water according to "strong" and "weak" operation, and
8 is a diagram illustrating a discharge state of discharged water according to "strong" and "weak" operations.

(1st embodiment)

EMBODIMENT OF THE INVENTION Hereinafter, the 1st Embodiment which apply | coats the washing machine of this invention to the dehydration combined washing machine is demonstrated with reference to FIGS. First, FIG. 2 is a side view of a main part schematically showing the overall configuration of a washing machine for dehydration combined use. The main body 1 forming the outline of the washing machine includes an outer box 2 having a substantially rectangular box shape and an upper surface thereof. It consists of the attached top cover 3, and the top cover 3 is provided so that the cover 5 of 2 sections which opens and closes the laundry inlet 4 is rotatable.

In the main body 1, a tubular water tank 6 having a water storage bottom having an open upper surface is elastically supported by an elastic support mechanism 7, and a tubular water tank having a bottom is similarly inside the water tank 6. The dewatering and washing tank 8 is rotatably provided.

In the lower part of the dewatering and washing tank 8, that is, the inner lower part, a stirring blade 9 for washing (including rinsing washing) is rotatably installed, and a plurality of dewatering for the peripheral wall of the dewatering and washing tank 8. The permeation hole 10 is formed, and the upper end part is provided with the balancer 11 which sealed the liquid (not shown), for example.

On the outer bottom side of the water tank 6, a driving unit 12 including a washing and dewatering motor, a clutch mechanism for switching power transmission, and the like is provided. Only 9) is rotated and the dehydration and washing tank 8 is rotated together with the stirring blade 9 during the dehydration operation.

In addition, a drain port 13 is formed at the bottom of the water tank 6, and an electric drain valve 14 is connected to the drain port 13, and a drain hose 15 is connected to the drain valve 14 to lead out of the air. It is.

An air trap 16 is connected to the drain port 13, and a pressure level sensor (not shown) is connected to the air trap 16 through an air tube or the like to detect the water level in the tank. In addition, the upper part of the water tank 6 is provided with the water flow path 17 formed so that it may communicate with the outside.

Moreover, in this embodiment, the circulation channel 19 which extends up and down along the side wall of the said dehydration and washing tank 8 is formed. Although mentioned later in detail, the channel cover 20 which forms a channel between the inner wall (tank inner wall) of the washing tank 8 is arrange | positioned, and the lower end part of the channel cover 20 is agitated wing 9 and a dehydration and washing tank. It communicates with the inner lower part formed between the bottom parts in (8). Specifically, the inner lower portion of the inner blade 18 which pumps on the inner surface side of the stirring blade 9 is integrally formed, and the inner blade 18 is accommodated in the pump chamber 22 which is a space portion formed in the bottom of the tank. This pump chamber 22 is configured to communicate with the circulation channel 19.

Moreover, in FIG. 2, the operation panel 23 is provided in the front part (shown to the left) of the said top cover 3, and operation keys for power "on / off", operation "course" selection are provided as various operation keys. Keys, operation keys for "start / pause", operation keys for setting specific operating conditions, and the like are provided together with a display unit (not shown).

Inside the operation panel 23, for example, a control device 24 composed of a so-called PC board unit mainly composed of a microcomputer is provided, and processes such as washing operation and dehydration operation are performed based on a program stored in advance. It functions as a control means for automatically controlling.

Subsequently, the specific structure of the said circulation channel 19 is demonstrated based on FIG. 1, FIG. 3, and FIG. 1 is a longitudinal cross-sectional view showing an enlarged main part of the dehydration and washing tub 8, FIG. 3 is a cross-sectional view cut along the line AA in FIG. 1, and FIG. 4 is similarly cut along the line BB in FIG. It is a cross-sectional view shown.

First, in Fig. 1, the dewatering and washing tank 8 is formed of a particularly rigid structure that withstands the centrifugal dewatering action. For example, detailed descriptions will be omitted, but materials such as metal plates, plastics, metal plates, etc. may be loaded in place. It is configured in consideration of the rigidity, light weight, assembly processability and the like.

Although the circulation channel 19 is formed along the vertical direction of the inner wall surface (bath inner wall surface) of such a dehydration and washing tank 8, in this embodiment, the cross-sectional shape which covers the inner surface side using the shape of a tank inner wall surface is The water channel cover 20 which forms an arc shape (refer FIG. 3, FIG. 4) forms the circulation channel 19 which made the inside into space. The channel cover 20 has a lower end communicating with the pump chamber 22, extending upward along the tank inner wall, and forming a space between the inner wall surface of the dewatering and washing tub 8.

In order to make this space a channel, as shown in FIG. 3, the parking part 25 which consists of elastic members, such as rubber | gum, is formed in the joint part of the channel cover 20 and the tank inner wall surface, and forms the watertight structure. . In addition, the rough wall which comprises the circulation channel 19 becomes a non-porous wall part without the small hole 10, and thereby the water flow performance of the circulation channel 19 is maintained favorable. As shown in FIG. 1, the channel cover 20 is provided with a plurality of discharge ports 26, 27, 28 stepwise in the vertical direction (three steps in the illustrated embodiment).

That is, the specific structure of these discharge openings 26-28 is the 1st discharge opening 26 located in the uppermost stage, the 2nd discharge opening 27 located in the 2nd stage, and the 3rd discharge opening 28 located in the lowest stage in this embodiment. It consists of).

These discharge openings 26 to 28 are all formed in a horizontally slit shape, of which the second discharge opening 27 is relatively flat and approximately the same curvature of the channel cover 20, as apparent from the cross-sectional view shown in FIG. It is formed by the flat part 21 which comprises the circular arc shape of, and is open toward the inside (horizontal direction) orthogonal to a tank.

Therefore, it is opened in a gentle circular arc shape, and the cross-sectional shape of the circulation channel 19 corresponds to the passage with a narrow inner length, and this form becomes substantially the same also in the 3rd discharge port 28 of the lowest stage.

On the other hand, although the uppermost 1st discharge port 26 is formed in the same horizontally long slit shape as the said discharge ports 27 and 28, and is open toward the horizontal direction (horizontal direction) inside a tank, the 1st discharge port 26 Is formed of a bulge portion 29 which is bulged toward the inside of the tank, which is the spin center side of the dewatering and washing tank 8, and is located at the most protruding end and is formed of the first discharge port 26. As shown in FIG. ). That is, the bulging part 29 of this embodiment forms the circular arc shape in which the cross-sectional shape is as shown in FIG. 3, and the longitudinal cross-sectional shape is slightly deformed all as shown in FIG. The bulging part 29 protrudes largely inward of the tank, and as a result, a space part with a large internal length between the dehydration and the inner wall surface of the washing tank 8 is formed.

For example, in Fig. 3, the circular arc shape in the left and right direction, which is the outer circumferential portion of the bulging part 29, is divided roughly into three parts, the center part and the left and right side parts, and the arc shapes are all smooth, and each arc shape of the left and right side parts has the same ratio. Bent.

Among them, the central part is wider in the lateral direction than the two parts and faces toward the inside of the jaw, and a straight line, or so-called normal (indicated by a solid arrow in the drawing), orthogonal to the arc-shaped tangent of the above part faces the inside of the jaw. have.

Therefore, the opening portion located in the center portion of the first discharge port 26 is opened in the horizontal direction, and will be described in detail later in the description of the operation, but as a discharge direction of the circulating water, the white arrow shown in FIG. It is injected toward the center side of a tank inside direction C).

On the other hand, the normal direction (solid line arrow) of each opening part located on the left and right sides of the first discharge port 26 is directed in the circumferential direction (the inner circumferential direction of the tank) in the dehydration and washing tank 8, and thus as the discharge direction of the circulating water. The circumferential directions in the directions of the white arrows D1 and D2 respectively shown in FIG. 3 are mainly injected.

Of course, the discharged water injected in the direction of these arrows C, D1, and D2 forms a continuous water film shape from one first discharge port 26 in a horizontal direction. Greatly expands into the tank.

On the other hand, as shown in FIG. 4, since the 2nd discharge port 27 formed in the flat part 21 of the channel cover 20 is formed in the area | region where a circular arc shape is gentle, it has the circular arc shape shown by the solid arrow in the figure. The direction (white arrows E1 to E5 directions) discharged from the discharge port 27 with respect to the straight line or the so-called normal direction perpendicular to the tangent line is discharged in the direction substantially the same as the normal direction.

In addition, various means for attaching the channel cover 20 to the dewatering and washing tank 8 can be considered. For example, the hook-shaped hook portion (not shown) can be integrally formed in a plurality of parts by using the channel cover 20 made of plastic. After installation, it is fastened to the hole installed in the wall, and then the wall is inserted into the screw boss part integrally installed in the water channel cover 20, and it can be fixed by screwing. According to this fixing means, the screw fixing part Can be less.

Subsequently, the operation of the dehydrating combined use washing machine of the above configuration will be described.

When washing laundry (not shown), such as clothes, the water supply means and the drive part 12 which are not shown by the control apparatus 24 which input operation conditions, such as a driving course and conditions, from the operation panel 23 like the well-known figure. Drive control and the like, and automatically perform the washing process, the rinsing process and the dehydration process.

Hereinafter, a description will be given of a case of carrying out a standard course operation in which the largest amount of laundry that is the rated capacity of the washing machine can be washed. In addition, rinsing and dehydration processes other than a washing process are as having already demonstrated.

In this case, as shown in FIG. 1, the water level of the dehydration and washing tub 8 is also set to the highest water level S, and is supplied to a higher level than the second discharge port 27, and only the first discharge port 26 is space in the tank. Located in

The drive part 12, such as a motor, is energized and driven, the power is transmitted to the stirring blade 9, and a washing operation is started. In the standard course operation, the water flow by the stirring blade 9 is set to a predetermined strong water flow. The laundry and the washing water are agitated by the rotation of the stirring blade 9, and the laundry rotates in the vertical direction while rotating the laundry in a horizontal direction (referred to as a semi-rotating operation). It aims to obtain the desired cleaning effect without an imbalance.

At the same time, a pumping action is generated on the basis of the rotation of the inner blade 18, and the washing water is sucked into the inner pump chamber 22 from the circumference of the stirring vane 9 to communicate with the pump chamber 22. Send to)

The washing water raising the circulation channel 19 reaches the bulge 29 formed at the upper end of the channel cover 20, and is strongly discharged from the first discharge port 26 facing the inner space of the tank. The discharged water is discharged from the discharge port 26 formed in a horizontally long slit shape in the horizontal direction by using a wide surface over a wide angle of the swelling portion 29, as indicated by the double-dotted line in FIG. Each of them becomes an extensive water film or a so-called fan-shaped water film that extends in the circumferential direction close to the circumferential wall in the tank, and is widely discharged by sprinkling.

Specifically, when the washing water is discharged from the first discharge port 26, it is discharged in the direction indicated by the white arrows D1 and D2 in the circumferential direction on the left and right on the basis of the normal direction indicated by the solid line arrow, and in the center portion therebetween. It is discharged in the direction indicated by the white arrow C toward the inside of the tank.

Of course, the flow of water in the normal direction indicated by a plurality of solid line arrows immediately before the discharge becomes a continuous water film state in the left and right directions, and the water film is formed in a wide fan shape as indicated by the double-dotted line in the figure. .

In this way, the washing water in the dehydration and washing tank 8 is sucked into the pump chamber 22 from the surroundings of the stirring blade 9, and lifts the circulation channel 19 to wash the circulation discharged from the first discharge port 26 into the tank. It is executed repeatedly during operation.

By the way, laundry is liable to float on the water surface, especially in the initial stage of operation. In this phenomenon, since the washing operation is not yet sufficiently infiltrated into the laundry and the washing operation is started as air enters the overlapping part of the laundry such as clothing, the laundry is swelled with air, and part of the laundry floats and is exposed to the water surface. It becomes a state.

Therefore, when the washing operation is performed as it is, the laundry which does not sink in the water naturally lacks the rotation (fabric rotation) in the above water, and since the washing water flow does not directly contact with each other, a good washing effect cannot be expected.

By the way, in this embodiment, the inner blade 18 rotates with the rotation of the stirring blade 9, and the water in the pump chamber 22 is pumped by the pump action, and the circulation channel 19 is raised. Then, the water which has risen is discharged in the horizontal direction toward the inside of the tank from the first discharge port 26 formed in the bulge 29 located above the highest water level, which is the cleaning level, and the discharged water is shown in FIG. As it is sprayed on a wide range of water surface in the tank, onto the water film largely expanded into a fan shape, it is sprayed in a sprayed state.

In this case, since the storage capacity of the bulging part 29 is large, discharge water can be discharged smoothly even if the 1st discharge port 26 is made into a large horizontally long shape. Therefore, even if a part of the laundry floats and is exposed on the water surface, the discharged water can be sufficiently added from the upper part of the exposed part (laundry).

As a result, the wet action of the washing water to the laundry in the floating state is promoted, the laundry to be floated is suppressed, and the washing action is also accelerated by receiving the discharged water directly from the upper side. In addition, the air remaining in the laundry by receiving the discharged water is easily released, and the floating part of the laundry is also easily sinked in water.

Therefore, the stirring operation | movement which is good in so-called fabric rotation, such as the rotational motion of the laundry in the water direction, the semi-rotation motion of the up-down direction, is actively performed. In this case, the bulging part 29 is higher than the washing | cleaning water level, and does not prevent the stirring water flow or the rotation of laundry.

Of course, the laundry subjected to the stirring operation is not limited to the initial washing operation, but is often lifted on the water surface to reach an exposed state, but even in this case, the laundry is pressed by the discharge water from the first discharge port 26. The laundry which tries to float can be suppressed, and an efficient washing | cleaning action is always exhibited.

In addition, the laundry which tends to float may flow in which the water is drawn from the circumference of the stirring blade 9 in the tank by the circulation water flow, or the force (impact) of the water discharged from the first discharge port 26 in the upper portion of the tank. Receive.

This flow or impact makes it easier to pull the laundry downward, and promotes the so-called up-and-down rotation of the laundry, thereby improving the cleaning performance.

When such a washing process is performed for a predetermined time, the process shifts to the rinsing process, and the detergent powder is washed in the same operation mode as the washing operation. Of course, the discharged water is sprinkled from the upper part on the laundry tending to float using the pump action of the inner blade 18 to promote a rinsing action.

Subsequently, when the process proceeds to the dehydration step, the power transmission by the drive unit 12 is switched, and the dewatering and washing tank 8 is rotated at high speed in one direction. The water containing the laundry is dehydrated by centrifugal action, discharged from the plurality of permeation holes 10 to the water tank 6 side, and drained to the outside via the drain hose 15 and the like. After this dehydration step is performed for a predetermined time, the control device 24 terminates the entire operation of the standard course such as stopping the drive unit 12.

4, the discharge direction of the water from the 2nd discharge port 27 formed in the flat part 21 of the channel cover 20 is shown by the white arrows E1 to E5. In the case where water is discharged from the second discharge port 27 (the same as the third discharge port 28), the laundry is used in a small amount, and the washing water is used in a small amount, for example.

The second discharge port 27 is formed in the flat portion 21 having a small arc-inward protrusion amount inward to form the flat circulation channel 19 as described above. Except for the outlet part 29, it reaches in the substantially same form to the pump chamber 22 of the lower part.

Since it is located at the position intersecting with the movement of the laundry during the washing operation or the water flow, it is set as a flat circulation channel 19 so that the resistance by impact does not increase so as not to disturb the so-called fabric rotation.

Therefore, the discharge state of the water from the second discharge port 27 shown in Fig. 4 is discharged in the direction indicated by the solid arrows and the white arrows E1 to E5 in the normal direction along the curvature of the arc shape. However, since the discharge port 27 is formed in the flat circular arc-shaped site | part, the direction shown by each white arrow E1-E5 has a slight displacement from each other, and the opening range of a horizontal direction becomes narrow.

For this reason, the main body is mainly discharged linearly toward the center side of the inside of the tank, and the discharge range (angle) in the left and right directions is indicated by the double-dotted line in the drawing, as shown in the first discharge port 26 (see FIG. 3). It is discharged as a narrow water film rather than a fan shape such as).

In addition, although the 1st discharge port 26 functions effectively, the discharge water at the time of washing | cleaning water at the highest water level S in FIG. 1 is also set from the 2nd, 3rd discharge ports 27 and 28 located in the water at this time. The discharge water flow toward the inside is generated, the circulation action of the washing water is promoted, and it is also effective for the washing action.

In addition, when the first and second discharge ports 26 and 27 function effectively as discharge water toward the space in the tank (the water level at this time is above the third discharge port 28), the bulging portion 29 (the The discharged water from the first discharge port 26 extends in a fan shape and reaches a distance, while the discharged water from the flat portion 21 (the second discharge port 27) is narrower than the first discharge port 26. It can be expected to be a water film, and fall near the tank wall, and to spray discharged water with little unbalance to the inside of the tank.

According to the said 1st Embodiment, it has the following effects.

The pumping action of the inner blades 18 of the stirring vanes 9 is used to form a circulation channel 19 through which the washing water is circulated, and discharged from the upper portion of the circulation channel 19 into the dehydration and washing tank 8. did. Since the first discharge port 26 is provided in the bulge portion 29 formed on the upper portion of the channel cover 20 forming the circulation channel 19, as shown in FIG. 3, the wide area of the bulge portion 29 is shown. A wide slit-shaped first discharge port 26 can be largely formed by using a wide surface over an angle, and as a result, a greatly expanded fan-shaped water film can be discharged over a wide range inside the tank.

This makes it possible to effectively apply water to the laundry floated during the washing operation irrespective of its position, and in particular, in the initial stage of the washing operation, laundry entering the air is likely to float on the water and be exposed, but this exposed portion ( By spraying washing water with laundry), it can be expected not only to promote wetting but also to return water in water.

In addition, the laundry is being agitated efficiently and agitated, and the up and down rotation of the laundry by the circulating water is also promoted, the so-called fabric rotation is improved, and the impact action by the sprinkled water is added, so that the efficient cleaning performance can be expected to be improved. have.

Moreover, since the bulging part 29 of the upper part of the circulation channel 19 is normally located higher than the washing | cleaning water level, it can prevent the laundry from moving and resistance of water flow, and fabric rotation is favorable. On the other hand, the flat part 21 which occupies most of the circulation channel 19 mainly located in washing water except the bulging part 29 has the inside of the channel cover 20 as shown in sectional drawing of FIG. The protrusion amount (circular portion) is small and has a flat configuration, and in particular, it is possible to reduce the obstruction of the movement of the laundry in the circumferential direction of the dewatering and washing tank 8 and the flow of water. Works. In addition, since the circulation channel 19 can be configured as the channel cover 20 without being shared with other components such as the balancer 11, it does not cause a problem such as compatibility with other models.

(2nd embodiment)

5 to 8 show a second embodiment of the present invention, where the same reference numerals are given to substantially the same parts as the first embodiment, and descriptions thereof will be omitted, and other parts will be described in detail.

5 is an enlarged longitudinal sectional side view of the main part of the circulation channel 30 of the present embodiment, and FIGS. 6A to 6D correspond to the strength of the cleaning action "strong" and "weak" operation. Fig. 7 illustrates a plurality of rotation control patterns by one stirring vane 9, FIG. 7 is a plan view of a dewatering and washing tank illustrating a drop zone of discharge water according to the operation of “steel” and “weak” operation, and FIG. And the discharge state of the discharged water according to the "weak" operation.

Since the structure of the circulation channel 30 is substantially common except the structure of the circulation channel 30 with respect to 1st Embodiment, the characteristic of the circulation channel 30 is demonstrated with reference to FIG.

This circulating waterway 30 is also provided with a waterway cover 31 having an bulging portion 32 protruding in an arc shape inside the tank so as to be located above the highest water level S of the washing water, and having a space between the walls of the water tank. The shape of the circulation channel 30 including the portion is substantially the same as that of the first embodiment. However, it differs specifically from the following points.

First, the channel cover 31 is provided with a first discharge port 33 positioned at the uppermost end thereof, and below the first discharge port 33, the second and third discharge ports 27 and 28 are the same as those of the first embodiment. Equipped with.

Here, as shown in FIG. 5, the bulge portion 32 provided with the first discharge port 33 has the most prominent center portion of an arc shape projecting inward of the jaw, and the upper and lower portions thereof retreat to the right side shown gently. An arc-shaped portion is formed.

Accordingly, the upper side of the bulge 32 faces upwardly inclined with respect to the inside of the jaw, and forms an inclined surface shape having an inclination angle β that inclines backward with respect to a so-called vertical line, and the inclined surface portion 32a The first discharge port 33 is formed.

The discharge port 33 opened and installed to be orthogonal to the inclined surface portion 32a is inclined upward and is formed at an upper direction position forming an elevation angle θ with respect to the horizontal line shown in FIG. This elevation angle [theta] is equal to the inclination angle [beta] ([theta] = [beta]) and is determined by the inclination angle [beta].

In addition, only the rib 34 protruding in the shape of the sunshade continuous with the discharge port 33 is provided only on the upper edge side of the discharge port 33 opened in the inclined upper direction of the discharge port 33. The rib 34 is integrally formed by protruding into the jaw in the inclined upper direction, which is the opening direction of the discharge port 33. In addition, the white arrow F in a figure shows the discharge direction of discharge water, and is discharged to the upper direction slightly.

6, the plurality of stirring blades 9 are used to express the strengths of the washing waters that give the laundry “strong” and “weak” operations to the laundry. The rotation control pattern is shown.

Through-out (on, off) control and rotation speed control of the drive part 12 (especially a motor) by the control apparatus 24 are performed (it demonstrates as rotation control of the stirring blade 9 hereafter). This directly affects the strength of the pumping action of the inner blade 18 of the stirring blade 9, and as a result, as described later, to the flying distance of the discharge water from each of the discharge ports 33, 27, 28. It causes a big change.

In other words, the stirring blades 9 are both driven to rotate in the forward and reverse directions. First, FIG. 6 (a) shows the "weak" washing water flow in which the stirring blades 9 are controlled by a common on / off time in a relatively short time. The pattern at the time of creation is shown and the so-called "weak" operation at the time of washing operation is shown.

On the other hand, FIG. 6 (b) shows a pattern in which the maximum rotational speed of the stirring blade 9 is the same as that of FIG. 6 (a), but the on time is long and the off time is short. In particular, the longer on-time rotating in one direction indicates that the washing water flow is accelerated and the mechanical action that the stirring blade 9 imparts to the laundry is also increased. In this case, "strong" operation is possible.

Although FIG. 6C has the on-off time in common with FIG. 6A, the maximum rotational speed RPM is controlled at low speed. Therefore, "weak" operation by "weak" washing water flow that is weaker than in Fig. 6A is shown.

FIG. 6 (d) shows a pattern when obtaining the strongest "strong" washing water flow. For example, the on and off times are common to both (a) and (c) of FIG. 6, but have the highest maximum rotational speed (RPM).

In this case, depending on whether the on or off time is set, it can be considered that the cleaning strength equivalent to that of Fig. 6B is shown. However, the strongest "strong" operation can be executed here based on the highest rotational speed.

7 and 8 illustrate the discharge state of the discharge water corresponding to the "strong" and "weak" water flows, and the detailed description will be described with reference to the following operation description.

Subsequently, the discharge action of the washing water based on the circulation channel 30 having the above configuration will be described.

First, a case where a standard driving course is set similarly to the first embodiment will be described with reference to FIG. 5. Therefore, the washing water level is at the highest water level S higher than the second discharge port 27, only the first discharge port 33 faces the space inside the tank, and the washing water flow by the stirring vane 9 is a predetermined " strong " Is set to "current". Here, in this embodiment, the bulging part 32 which provided the 1st discharge port 33 has the inclined surface part 32a which forms the inclination angle (beta) inclined slightly back, and this inclined surface part 32a has a 1st Since the discharge port 33 is provided in the upper direction, the discharge water is discharged in the direction of the white arrow F which is approximately equal to the normal direction.

In addition, in this embodiment, the rib 34 protrudes and is provided in the upper side of the opening edge of the 1st discharge port 33. As shown in FIG. In the absence of this rib 34, the water leaving the discharge port 33 tends to fall immediately due to gravity.

On the other hand, in the case where the rib 34 is provided, when water is discharged, the action of reaching the rib 34 from the upper edge of the opening and continuing to contact the lower surface side of the rib 34 by surface tension occurs, and as a result, It is possible to scatter water until.

In addition, since the rib 34 protrudes from the upper side to the sunshade shape so as to cover the opening with respect to the horizontally long slit-shaped first discharge port 33, foreign matters (for example, coins, etc.) from the upper side are formed. Intrusion of foreign matter into the discharge port 33 can be prevented by falling.

In addition, as for the discharge angle of water, the elevation angle (theta) which is a discharge direction is determined according to the inclination angle (beta) of the inclined surface part 32a, and water is discharged in the inclined upper direction. Accordingly, the discharged water is discharged to draw a parabolic line (see FIG. 8), and can reach a far distance as compared to the discharge in the horizontal direction.

For example, the pump action by the inner blade 18 can be encouraged, or when the diameter of the dewatering and washing tank 8 is large due to the large capacity, it can be easily coped with. Of course, the discharged water becomes a fan-shaped water film as in the first embodiment, is sprinkled into the tank, and contributes to the improvement of the cleaning performance by being sprinkled from the upper part of the laundry which tends to float.

In addition, although the angle of incidence θ, which is the discharge angle, can theoretically be discharged to the farthest 45 degrees, the number of discharges is too scattered at the rotational speed of the stirring blade 9 in the standard driving course, which may reach the exterior. Therefore, it is preferable to set the elevation angle [theta] to 30 degrees or less, for example.

On the other hand, the second and third discharge ports 27 and 28 provided in the flat portion 21 are suppressed by the narrow slit-shaped openings, and are formed to be discharged linearly into the tank so as to be orthogonal to the flat portion 21. The roots are therefore smaller.

In this standard course operation, the washing operation is generally performed under a constant flow of washing water, and of course, the stirring blade 9 (inner blade 18) is also suppressed at a constant rotational speed or the like, and the first discharge port 33 The flying distance of the discharged water from this also becomes substantially constant.

For this reason, by spraying the discharged water in a fan shape, spraying to laundry is effectively performed.

In this case, however, the discharge water is effectively injected into the region far from the first discharge port 33, but the discharge water is hardly injected in the immediately preceding area. Of course, if the discharged water can be evenly injected into the tank, further improvement of the cleaning performance can be expected.

Therefore, in this embodiment, the flying distance of discharged water can be changed based on the rotation control of the stirring blade 9. Hereinafter, with reference to FIG. 6, the rotation control pattern of the stirring blade 9 for obtaining the strength "strong" and "weak" of washing water flow is demonstrated.

In the control pattern shown in FIG. 6 (d), for example, in which the washing water flow is strongest in FIG. 6, since the rotational speed RPM is the highest and the pump action by the inner blade 18 is the strongest, the water is a circulation channel. 30 is raised strongly and discharged to the furthest part from the 1st discharge port 33 formed in the bulging part 32. FIG. In FIG. 7, the area | region G drawn in the fan shape by the inclination line which crossed the range of the arrival fall (improvement) of discharge water in this case is discharged to the opposite side farthest from the circulation channel 30. In FIG.

On the other hand, in the rotation control pattern shown in FIG. 6C showing the weakest washing water flow, the pump action by the inner blades 18 is also weakened, and the discharge water from the first discharge port 33 is moved forward. It falls and corresponds to the range corresponding to the area | region H which shows the slightly small fan shape shown by the oblique line in FIG.

When the drop regions G and H of the discharged waters are combined, they occupy most of the inner area of the dewatering and washing tank 8, and the spraying of the washing water into the laundry is more effectively performed.

Therefore, if the rotation control pattern which becomes the "strong" water flow of FIG. 6 (d) and the rotation control pattern which becomes the "weak" water flow of FIG. It can be added, and the cleaning effect without an unbalance can be expected by that much.

In addition, the pattern which alternates what is called "strong" and "weak" operation | movement by this stirring blade 9 is not limited to being performed during a washing process, For example, even if it is the setting performed by focusing in the initial stage of operation which a laundry tends to float, It is possible to carry out various modifications including rinsing process.

In addition, since this type of washing machine usually has the above-described "strong" and "weak" operation functions, it is programmed in advance to the control device 24 without adding a new configuration, and thus "strong" based on the rotation control of the stirring blade 9. And control pattern of "weak" operation can be easily performed.

In addition, as shown in FIG. 6, the rotation control of the stirring blade 9 can be considered in various ways, such as a method of changing the maximum rotational speed (RPM), or a method of changing the ratio of on and off periods. And "weak" operation patterns can also be modified in various ways.

Subsequently, FIG. 8 will be described. This shows an overview of the discharged state of the washing water according to the "strong" and "weak" patterns of the washing water flow, and images the discharge water from each discharge port 33, 27, 28 that becomes effective according to the amount of laundry and the water level. The solid line shows the case by the "strong" water flow operation, and the dashed-dotted line shows the case by the "weak" water flow operation.

In this example, the state (flying distance) of discharge water which added and subtracted the intensity | strength at the time of "weak" water flow operation is shown so that the whole may discharge toward the center side inside tank.

In addition, since the second and third discharge ports 27 and 28 are formed to be opened in the horizontal direction (lateral direction) inside the tank, as shown in the drawing, the flying distance is significantly different from the first discharge holes 33 opened in the upper direction. Further, even if the second and third discharge ports 27 and 28 are narrow, they are formed in any flat portion 21, so that the discharge water width, which is the water film, does not become a fan shape linearly as shown in FIG. .

In addition, referring to FIG. 8, another use example will be described. For example, when the water level according to the amount of laundry is set above the third discharge port 28 and the washing operation is performed, the first and second discharge ports ( The discharge water from both sides 33 and 27 can be utilized effectively. That is, in this case, as shown in the figure, two discharged waters having different flying distances, water films, and the like can be utilized, and the effect applied to the laundry becomes more effective.

In addition, it is not limited to this, It is possible to adjust and operate suitably so that a desired distance can be obtained according to the capacity | capacitance (diameter) of the dehydration and washing tank 8, etc.

According to the said 2nd Embodiment, it has the following effects.

Especially, as shown in FIG. 5, since the 1st discharge port 33 of the bulging part 32 was formed in the site | part of the inclined surface shape which faces the upper direction inclined with respect to the inside of the tank of the bulging part 32, a discharge port also shows The shape is opened in the upper direction to be the same.

Therefore, the discharged water discharged from the discharge port 33 in the upper direction can be scattered to draw a parabola and reach far, and the same effect as that of increasing the pump performance by the inner blade 18 is easily obtained.

This is effective for increasing the fan-shaped water film to the laundry, and also has the advantage that the design and fabrication of the inner blade 18 can be made easier.

In addition, since the sun-shaped rib 34 protrudes from the upper edge side of the opening of the first discharge port 33, the action of discharging to a far distance can be promoted by using the surface tension generated on the lower surface side of the rib 34. In addition, the rib 34 is formed to cover the opening of the discharge port 33, and also effective in preventing foreign matters such as coins falling from the upper side from entering the discharge port 33.

In addition, although FIG. 6 demonstrated that the "strong" and "weak" operation | movement based on the various intensity | strengths of washing | cleaning water flow can be selectively switched based on the rotation control of the stirring blade 9, this simultaneously carries out internal blade 18 It is possible to switch the strength and weakness operation of the pump action by).

Therefore, the distance of the discharged water from the 1st discharge port 33 can be changed by the rotation control of the stirring blade 9, so that the fall area | region G or H of discharged water may be obtained alternately as shown in FIG. As a result, improvement of the cleaning performance without an imbalance can be expected.

In addition, the rotation control of the stirring blade 9 can be easily programmed and performed, for example, it concentrates at the initial stage of a washing process, and accelerates the action of quickly wetting a laundry including air and returning it to water. In addition, the control which acquires the desired washing | cleaning effect by an original washing | cleaning action can also be performed easily.

The swelling part 32 formed in the upper part of the channel cover 31 which forms the circulation channel 30 is arrange | positioned in the position higher than the highest water level of the washing process of a standard driving course, and is located in the pump room lower than the swelling part 32. The site | part up to (22) was set as the flat part 21 which has a slightly circular arc shape, and the 2nd and 3rd discharge ports 27 and 28 are also provided also in the flat part 21. As shown in FIG.

Thereby, the bulging part 32 can ensure the desired washing | cleaning performance, without impeding washing water flow and textile rotation. Moreover, since the some discharge port was provided over the bulging part 32 and the flat part 21, the improvement of the washing | cleaning effect by discharged water can be expected with respect to the washing | cleaning level of several stages corresponding to the laundry amount.

In addition, in this embodiment, the 2nd, 3rd discharge openings 27 and 28 provided in the flat part 21 are horizontal in the horizontal direction, while the 1st discharge opening 33 provided in the bulging part 32 is opened upward. Since it is open | released, when it discharges in combination with each discharge opening 33, 27, and 28 opened in these other directions, it can discharge evenly in a tank, and can contribute to the cleaning effect without an imbalance.

In this case, the second and third discharge ports 27 and 28 may be openings in upper directions having different angles, or may be discharge ports opening in all different directions.

In addition, this invention is not limited to embodiment mentioned above and also shown in the figure, For example, although the bulging part formed in the upper part of the circulation channel made the cross section substantially circular arc shape, the part which forms a discharge port obtains a fan-shaped water film | membrane. Although it is preferable that it is circular arc shape, it can change into various shapes.

In addition, the washing machine may be provided with at least a stirring blade to act as a pump by the inner blade, and can be applied to, for example, a washing tank unit having a washing function and without a hole. Various modifications can be made without departing from the scope of the invention.

1: body 6: tank
8: dehydration and washing tank (washing tank) 9: stirring blade
18: inner wing 19, 30: circulation channel
20, 31: channel cover 21: flat part
22: pump chamber 26, 33: first discharge port (discharge port)
27, 28: 2nd, 3rd discharge port (discharge port) 29, 32: bulge part
32a: inclined surface portion 34: rib

Claims (7)

Tub-type washing tub with bottom installed in the body,
A stirring blade rotatably installed in the lower part of the washing tank,
An inner blade formed on an inner surface of the stirring blade,
A pump chamber formed at the bottom of the washing tank to accommodate the inner wings;
A channel cover extending upwardly from the pump chamber along the tub wall and forming a circulation channel between inner walls of the tub,
And a swelling portion that swells toward the inside of the washing tub in the upper portion of the water channel cover, and a slit-shaped discharge port that is horizontally elongated in the swelling portion. The method of claim 1,
The part in which the discharge port of the bulge is provided is an inclined surface inclined toward the upper direction inclined with respect to the inside of the washing tank, and the discharge port of the bulge is also opened upward. The method according to claim 1 or 2,
A washing machine characterized in that a sunshade rib is protruded and installed on an upper edge side of the opening of the discharge port. The method according to claim 1 or 2,
The washing machine characterized by switching the intensity | strength operation of the pump action by the said inner blade based on the rotation control of the said stirring blade, and changing the flying distance of the discharge water from the said discharge port. The method according to claim 1 or 2,
The said bulging part was formed in the position higher than the highest water level of a washing process operation. The washing machine characterized by the above-mentioned. The method according to claim 1 or 2,
The waterway cover is provided with a discharge port in the flat portion of the lower portion than the bulge portion in addition to the bulge portion provided on the upper portion. The method according to claim 6,
And a discharge port provided in the flat portion with respect to the opening of the discharge port provided in the bulge portion, which is opened in a different direction.

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