KR20100009708A - Nozzle for cleaner - Google Patents

Abstract

PURPOSE: A nozzle for a cleaner is provided to reduce the steam generating time by improving a structure of a steam generator. CONSTITUTION: A nozzle body forms the exterior of a cleaner. A steam generator(100) is formed in the nozzle body. Water is supplied to the steam generator, and the steam generator generates the steam. A water tank(110) stores the water. A heating unit(150) heats the water supplied from water tank. A water storage tank(130) supplies the water flowed from the water tank to the heating unit. Air inflow holes(137) are formed on the water storage tank.

Description

Nozzle for cleaner

This embodiment relates to a nozzle of a cleaner.

The present embodiment relates to a nozzle of a cleaner, and more particularly, to a nozzle of a cleaner which reduces a steam generation time by improving a structure of a steam generator provided in a nozzle of a cleaner.

The vacuum cleaner is a device to reduce human labor by cleaning with the power of a machine.A vacuum cleaner using suction power and a water cleaner that inhales water and air at the same time by spraying water, as well as foreign matters on the floor by spraying steam recently Various kinds are disclosed, such as removing.

In addition, a vacuum steam cleaner capable of simultaneously inhaling foreign substances by a vacuum cleaner and steam cleaning by a water cleaner has also appeared.

On the other hand, the nozzle of the steam cleaner is provided with a steam generating device for generating steam therein, it is configured to remove the foreign material on the bottom surface by using the steam supplied with a mop attached to the lower side. In addition, a heater is provided inside the steam generator to convert water into steam at high temperature.

The steam generator, the heater is provided on one side of the water tank is applied to the tube heating method for generating steam by heating the entire water in the water tank and a small amount of water to the heater side is applied come.

However, in the case of the conventional steam generator according to the conventional heating method, since a large amount of water must be heated, the steam generation time is long, and the weight of the steam nozzle apparatus is heavy. In addition, the water tank is not easy to separate from the steam generating device has a problem that the possibility of contamination of the reservoir tank increases.

On the other hand, in the case of a conventional steam generating apparatus using a tube heating method, there is a problem in that water which is not changed into steam due to a small size and capacity of the heater is injected together. Accordingly, the steam generation efficiency is lowered, there was a problem that the stability of the product is not guaranteed.

And, in the case of the tube heating method, since a pump for sending water to the heater should be provided, there is a problem that it is expensive.

The present embodiment aims to provide a nozzle of a cleaner which improves the structure of the steam generator and reduces the time for generating steam.

In addition, it is an object of the present invention to simplify the structure of the steam generating device and to provide a nozzle of a cleaner which allows the weight of the entire nozzle provided with the steam generating device to be lighter.

It is also an object of the present invention to provide a nozzle of a cleaner which reduces the possibility of contamination of the water tank by allowing the water tank to be separated from the steam generator to perform water supply or cleaning.

In addition, an object of the present invention is to provide a nozzle of a cleaner that allows an outside air inflow hole to be generated in the reservoir, so that the pressure inside the reservoir is maintained at atmospheric pressure.

Further, an object of the present invention is to provide a reservoir including a shielding film so that water does not flow out through the outside air inlet hole in the process of introducing water into the reservoir.

The nozzle of the cleaner according to the present embodiment includes a nozzle body forming an appearance; And a steam generator provided in the nozzle body and supplied with water to generate steam, wherein the steam generator includes: a water tank in which water is stored; A heating unit for heating the water supplied from the water tank; And a reservoir for supplying water introduced from the water tank to the heating unit, wherein the reservoir is formed with an outside air inlet hole through which outside air can be introduced.

The nozzle of the cleaner according to another embodiment includes a nozzle body in which a seating part is formed; And a steam generator mounted on the seating unit and configured to generate steam from water, wherein the steam generator includes: a water tank in which water is stored; A water tank into which water is introduced from the water tank and in communication with the outside; And a shielding portion provided in the reservoir and allowing the reservoir to be shielded from the outside.

According to the embodiment of the above configuration, the present embodiment has a merit that a small amount of water is supplied from the reservoir to the heating unit provided with the heater, thereby reducing the time for generating steam.

In addition, since the structure of the steam generator can be simply implemented, there is an advantage that the weight of the entire nozzle provided with the steam generator can be lightened.

In addition, since the water tank may be separated from the steam generating device, water supply or cleaning may be performed, thereby reducing the possibility of contamination of the water tank.

In addition, in a state in which no water is filled in the reservoir more than a predetermined amount, there is an effect that the atmospheric pressure can be maintained by opening the outside air inlet hole and introducing the outside air into the reservoir. On the other hand, when a predetermined amount or more of water is filled in the reservoir, there is an advantage that the water is not leaked to the outside by shielding the outside air inlet hole.

Hereinafter, with reference to the drawings will be described a specific embodiment of the present invention. However, the spirit of the present invention is not limited to the embodiments presented, and those skilled in the art who understand the spirit of the present invention can easily suggest other embodiments within the scope of the same idea.

1 is a perspective view of a cleaner nozzle according to an embodiment of the present invention, Figure 2 is a perspective view of the inside of the nozzle showing the open state of the cover of the cleaner nozzle according to an embodiment of the present invention.

1 and 2, in the nozzle 1 of the cleaner according to the embodiment of the present invention, a nozzle body 10 having an appearance of a nozzle and having a seating part 11 formed thereon, and the nozzle body 10. ) Is provided on the upper side of the nozzle cover 20 to shield the inside of the nozzle body 10, and the air sucked by the nozzle is provided to one side of the nozzle body 10 to the main body of the cleaner (not shown). Included is a connection 30 to be moved.

Although not shown in the drawing, the nozzle 1 of the cleaner is connected to the main body of the cleaner by an extension tube and a connection hose. The connecting portion 30 allows the nozzle 1 to be connected to the extension pipe.

The nozzle body 10 includes an air suction unit 12 through which air containing dust is sucked from the surface to be cleaned, and an air suction unit through which the air sucked through the air suction unit 12 moves toward the connection unit 30. A flow path 13 is provided.

The suction passage 13 may extend backward from the air suction portion 12.

In addition, the nozzle body 10 is provided with a steam generator 100 to change the supplied water to steam. The steam generator 100 may be disposed above and on one side of the suction passage 13.

The steam generating device 100, a water tank 110, the supplied water is stored, and a reservoir provided on one side of the water tank 110, the predetermined amount of water flows from the water tank 110 ( 130 and a heating unit 150 provided on one side of the reservoir 130 to heat the water flowing from the reservoir 130.

Hereinafter, the structure of the steam generator 100 will be described with reference to the drawings.

3 is a perspective view showing a steam generating device according to an embodiment of the present invention, Figure 4 is an exploded perspective view showing the configuration of the steam generating device of the present invention, Figure 5 is a plan view of a steam generating device according to an embodiment of the present invention to be.

3 to 5, the steam generator 100 according to the embodiment of the present invention includes a water tank 110 in which water is stored and a water tank 110 provided below the water tank 110. Storage tank 130 selectively receives a predetermined amount of water from the 110, and the heating unit 150 is provided on one side of the reservoir 130 to heat the water introduced from the reservoir 130 to generate steam Included.

In detail, the water tank 110 may have a substantially rectangular parallelepiped shape. A storage space for storing water is formed in the water tank 110.

On one side of the water tank 110, a tank opening 112 is formed to open to allow the water stored in the water tank 110 to flow into the reservoir 130.

In addition, the bottom surface of the water tank 110 is formed to be inclined downward toward the tank opening 112. Therefore, the water stored in the water tank 110 can be easily moved to the tank opening 112.

The tank opening 112 is provided with a tank cap 120 that the tank opening 112 selectively shields. The tank cap 120 extends toward the inside of the reservoir 130.

In detail, the tank cap 120 has a valve member 122 to control the water supply from the water tank 110 to the reservoir 130, and a guide part 123 to guide the movement of the valve member 122. ) Is provided.

In addition, the water tank 110 is provided detachably from the reservoir (130). The user may separate the water tank 110 to refill the water after filling.

In addition, the steam generator 100 includes a seating plate 116 to allow the water tank 110 to be seated. The seating plate 116 may be disposed to form the same plane as the upper surface of the reservoir 130. 3 is a view showing a state just before the water tank 110 is seated on the seating plate 116.

In addition, the mounting plate 116 is formed with a detachable portion 117 to be fixed in the state in which the water tank 110 is seated. The detachable part 117 may be formed in the shape of a groove recessed downward.

Correspondingly, the water tank 110 is provided with a detachable protrusion 119 that is provided to be coupled to the detachable portion 117. The detachable protrusion 119 may be bent to have a "" shape.

The detachable protrusion 119 is inserted into the detachable portion 117 while the water tank 110 is seated on the seating plate 116. The detachable protrusion 119 may be composed of an elastic member, and in this case, the water tank 110 may be elastically deformed in the process of being coupled or separated.

In addition, a lower side of the seating plate 116 is provided with a first leg 118 for supporting the water tank 110. A plurality of first legs 118 may be provided at corner portions of the seating plate 116.

In addition, the reservoir 130 has a substantially rectangular parallelepiped shape. The size of the reservoir 130, that is, the capacity for storing water is smaller than that of the water tank 110. Below the reservoir 130, a second leg 138 is provided to support the reservoir 130.

The reservoir 130 has a reservoir opening 132 through which water supplied from the water tank 110 flows. The reservoir opening 132 may be larger than the tank opening 112.

Since the reservoir opening 132 is formed larger than the tank opening 112, the tank cap 120 may be easily extended from the lower side of the tank opening 112 toward the inside of the reservoir 130.

In addition, the reservoir 130 is provided with a restraining portion 135 to interact with the tank cap 120. The restraining part 135 has a shape protruding upward from the lower surface of the reservoir 130.

In addition, the reservoir 130 is formed with an outside air inlet hole 137 through which external air is introduced. When air is introduced through the outside air inlet hole 137, atmospheric pressure may be maintained in the reservoir 130.

Between the water tank 110 and the reservoir 130, a sealing member 114 is provided to prevent water from leaking from the reservoir 130. The sealing member 114 is disposed along the outer circumferential surface of the reservoir opening 132.

One side of the reservoir 130, a heating unit 150 is provided to heat the water introduced from the reservoir 130.

The heating part 150 may have a substantially rectangular parallelepiped shape. Inside the heater 150, a heater 151 is provided to heat water to generate steam. The heater 151 may be disposed at the bottom of the heating unit 150. In this case, a sheath heater, a PTC heater, a ceramic heater, and the like may be applied to the heater 151.

Although not shown in the figure, a felt may be provided below the heater 151 to prevent heat of the heater 151 from being transferred to the surface of the heating part 150. That is, the felt may be referred to as a heat transfer preventing member.

The felt may be arranged to surround the heater 151.

In addition, a heater coupling part 154 to which the heater 151 is coupled is formed on one side of the heating part 150. One side of the heater 151 may be coupled to the heater coupler 154.

In addition, the heating unit 150 is provided with a steam discharge unit 155 to discharge the generated steam. The steam outlet 155 has a pipe shape, a part of which extends into the heating part 150, and the other part of the steam discharge part 155 protrudes out of the heating part 150.

That is, the steam discharge part 155 is disposed to be fitted to one surface of the heating part 150. Of course, the steam outlet 155 will be fixed to one surface of the heating unit 150.

In addition, the steam discharge part 155 is disposed to be located above the heating part 150. In detail, the steam outlet 155 may be disposed at a position higher than the height of the center portion of the heating unit 150. This is because steam generated by the heater 151 is lighter than water and has a property of rising.

As shown in FIG. 5, a plurality of steam outlets 155 may be provided.

On the other hand, between the reservoir 130 and the heating unit 150, an inlet 136 is formed so that the water of the reservoir 130 flows into the heating unit 150. As shown in FIG. 5, at least one inlet 136 may be formed at one side of the reservoir 130.

In order to allow water to easily flow from the reservoir 130 to the heating part 150, the inlet part 136 may be inclined downward toward the heating part 150.

Hereinafter, the steam generation process by the steam generator 100 will be briefly described.

6 is a cross-sectional view showing the configuration of a steam generator according to an embodiment of the present invention.

Referring to FIG. 6, water stored in the water tank 110 according to an embodiment of the present invention may be introduced into the reservoir 130 through the tank opening 112. In this process, the valve member 122 of the tank cap 120 is opened.

In addition, the water of the reservoir 130 is introduced into the heating unit 150 through the inlet 136.

Water in the water tank 110 may be introduced into the heating unit 150 via the reservoir 130 according to Pascal's principle.

Pascal's principle means that the pressure exerted on a fluid contained in a closed container is transmitted to all parts of the fluid and the wall of the container containing the fluid without being reduced in size.

The application of Pascal's principle to the present embodiment is as follows.

(1) P _tank + ρgh _{water_tank} = P _air + ρgh _{water_reservoir}

Equation (1) means that the pressure in the water tank 110 and the pressure in the reservoir 130 is in equilibrium. The pressure in the water tank 110 is the sum of the vacuum pressure of the tank and the pressure by the water stored in the tank, the pressure in the reservoir 130 is the pressure of the air inside the reservoir 130 and the reservoir ( 130 is the sum of the pressures stored by the water. As described above, the pressure of the air inside the reservoir 130 is maintained at atmospheric pressure.

When the tank cap 120 is opened, the water of the water tank 110 falls into the reservoir 130 by gravity, that is, water pressure. In this process, the air inside the reservoir 130 is introduced into the water tank 110 through the tank cap 120.

That is, when water falls into the reservoir 130, the water level of the reservoir 130 forms an arbitrary level h1.

Subsequently, when the water level in the reservoir 130 rises so that the water in the reservoir 130 covers at least a portion of the tank cap 120, the air in the reservoir 130 is transferred through the tank cap 120. It cannot be introduced into the water tank 110.

That is, when the water level of the reservoir 130 is raised to form the water level h2, the water of the tank 130, the lower opening, that is, the water level determining unit 125, so that the air of the reservoir 130 is no longer It cannot be introduced into the water tank 110.

In this state, the water tank 110 is formed by the sum of the vacuum pressure and the water pressure by the water level, and the inside of the reservoir 130 is formed by the sum of the atmospheric pressure and the water pressure by the water level. That is, the pressure of the water tank 110 and the reservoir 130 is in equilibrium.

(2) P _air + ρgh _{water _ reservoir} = ρgh _{water _ boiling} + P _{steam & air}

Equation (2) means that the pressure in the reservoir 130 and the pressure in the heating unit 150 is the same. The pressure inside the heating unit 150 is the sum of the pressure caused by the water inside the heating unit 150 and the steam and air pressure inside the heating unit 150.

That is, when there is no water in the heating unit 150 or there is a small amount, water is diverted from the reservoir 130 by the water level difference between the reservoir 130 and the heating unit 150. ) Can be moved.

Therefore, the water level inside the heating unit 150 may be determined by the water level of the reservoir 130.

In summary, the water stored in the reservoir 130 is moved to the heater 150 until the water level in the reservoir 130 and the heater 150 is the same. That is, when the water level of the reservoir 130 and the heating unit 150 is the same, the water will not move any more.

By the above structure, the water of the water tank 110 can be easily moved to the heating unit 150. That is, there is no need for a separate configuration such as a pump or a controller, and there is an advantage in that water can be moved from the water tank to the heating unit 150 by a simple structure.

Hereinafter, the operation of the steam generator according to the present embodiment will be described.

As water flows into the reservoir 130 from the water tank 110, the water level of the reservoir 130 rises. Then, when the water level of the reservoir 130 reaches a certain level h2, the pressure of the water tank 110 and the reservoir 130 is in equilibrium, so that water is no longer introduced.

On the other hand, as the water level of the reservoir 130 rises, the water level difference between the reservoir 130 and the heating unit 150 is generated, and the water of the reservoir 130 according to the water level difference is the inlet 136 It is introduced into the heating unit 150 through.

Water introduced into the heating unit 150 is heated by the heater 151, the steam generated during the heating process is discharged to the outside through the steam discharge unit 155.

According to the steam generator having the above function, since a small amount of water is introduced into the heating unit 150 and heated, the heating time of the water is shortened.

In addition, since the steam generator can be implemented by a simple structure, there is an advantage that the weight of the nozzle having the steam generator is lighter.

Hereinafter, a shield for selectively shielding the outside air inflow hole and the outside air inflow hole formed in the reservoir 130 will be described with reference to the drawings.

7 and 8 are views showing the configuration of a reservoir according to an embodiment of the present invention, Figure 9 is a cross-sectional view taken along the line II 'of FIG. 7, Figure 10 is a line II-II' along FIG. 11 is a cross-sectional view illustrating the outside air inlet hole of the reservoir according to the exemplary embodiment of the present invention.

7 to 11, in the reservoir 130 according to the embodiment of the present invention, an outside air inlet hole 137 is formed to allow external air to flow into the reservoir 130. That is, the reservoir 130 may be in communication with the outside through the outside air inlet hole (137).

The outside air inlet hole 137 may be formed at an approximately upper portion of one surface of the reservoir 130, and a plurality of inlet holes 137 may be formed in a direction parallel to the upper surface of the reservoir 130.

In addition, a shielding portion 160 is provided inside one surface of the reservoir 130 to selectively shield the outside air inlet hole 137. The shielding unit 160 may have a size that allows the plurality of external air inlet holes 137 to be shielded at the same time, and may have a thin film shape.

The shield 160 may shield the outside air inlet hole 137 when the water pressure inside the reservoir 130 is applied. On the other hand, when the water level in the reservoir 130 is low so that the water pressure does not act on the shield 160, the shield 160 is spaced apart from the reservoir 130, the outside air inlet hole 137 Through the outside air can be introduced.

In addition, bending portions 161 that are bent backward from the front surface of the shielding portion 160 are formed at both end portions of the shielding portion 160. An elastic member 164 is connected to the bent portion 161 so that the shield 160 is elastically supported with respect to the reservoir 130. That is, the elastic member 164 may be provided on both sides of the shielding portion 160, respectively.

One side of the elastic member 164 is fixed to the bent portion 161, the other side is fixed to the inner surface of the reservoir (130). Here, fixing portions 163 for fixing the elastic members 164 are provided on the inner surfaces of the bent portion 161 and the reservoir 130, respectively.

In addition, the reservoir 130, through the coupling hole 139 is formed so that the shield 160 is coupled to the reservoir 130. A plurality of coupling holes 139 may be formed between the plurality of outside air inlet holes 137.

In addition, the coupling hole 139 may be larger than the outside air inlet hole 137, and the outside air inlet hole 137 and the coupling hole 139 may be arranged in a line.

In addition, the coupling hole 139 and the outside air inlet hole 137 may be disposed at a position higher than the center height of the reservoir 130, at least on the reservoir 130. Therefore, when the water level in the reservoir 130 is not at a position higher than the center of the reservoir 130, there is less fear that water will flow out through the outside air inlet hole 137 or the coupling hole 139. .

The shielding part 160 is provided with a coupling protrusion 162 inserted into the coupling hole 139. In the process of the shielding unit 160 to shield the outside air inlet hole 137, the coupling protrusion 162 may be inserted into the coupling hole 139.

On the other hand, the lower end of the shielding portion 160 may be disposed further by a distance of t1 than the outside air inlet hole 137 and the coupling hole 139. In this case, in a state in which the shield 160 is spaced apart from the reservoir 130, the water inside the reservoir 130 acts on the shield 160 before being discharged through the outside air inlet hole 137. Can be.

Therefore, the water of the reservoir 130 may be prevented from being discharged through the outside air inlet hole 137.

In addition, when the shield 160 is spaced apart from the inner surface of the reservoir 130, the front portion 160a of the shield 160 may be maintained at a distance of l1 from the reservoir 130. . Here, the shield 160 may be spaced apart from the reservoir 130 by the restoring force of the elastic member 164.

The l1 may be formed to a length of about 1mm.

Hereinafter, the operation of the shield 160 will be described.

When water is not supplied to the reservoir 130 or when a small amount of water is filled, the shield 160 is kept spaced apart from the inner surface of the reservoir 130.

In addition, since the outside air flows into the reservoir 130 through the outside air inlet hole 137, the pressure inside the reservoir 130 may be maintained at atmospheric pressure.

On the other hand, when water is introduced from the water tank 110, the water level of the reservoir 130 is gradually increased. In this process, when water comes into contact with the shield 160, that is, when water pressure acts on the shield 160, the shield 160 overcomes the restoring force of the elastic member 164 and the water tank. It moves in the direction (130).

When the shielding part 160 comes into close contact with the inner surface of the water reservoir 130, the coupling protrusion 162 is inserted into the coupling hole 139. In addition, the front portion 160a of the shielding portion 160 shields the outside air inlet hole 137.

In this case, outside air can no longer be introduced into the reservoir 130 through the outside air inlet hole 137, and the inside of the reservoir 130 is blocked from the outside.

In this state, when the water of the reservoir 130 is moved to the heating unit 150, the water level inside the reservoir 130 is lowered. Then, when the water level of the reservoir 130 is formed below the lower end of the shield 160, the water pressure is no longer applied to the shield 160.

Then, the shield 160 is spaced apart from the inner surface of the reservoir 130 by the restoring force of the elastic member 164, the outside air can be introduced.

By the action of the outside air inlet hole 137 and the shield 160, the pressure inside the reservoir 130 can be easily maintained at atmospheric pressure.

In addition, when the water level inside the reservoir 130 is increased while the outside air inlet hole 137 is opened, since the outside air inlet hole 137 is shielded, the reservoir 137 through the outside air inlet hole 137. There is an advantage that the water inside can be prevented from leaking to the outside.

In addition, even when the water tank is shaken during the operation of the cleaner nozzle, water acts on the shielding portion, and thus the shielding portion may shield the outside air inflow hole, thereby preventing water leakage.

1 is a perspective view of a cleaner nozzle according to an embodiment of the present invention.

Figure 2 is a perspective view of the inside of the nozzle showing the open state of the cover of the cleaner nozzle according to an embodiment of the present invention.

3 is a perspective view showing a steam generating device according to an embodiment of the present invention.

Figure 4 is an exploded perspective view showing the configuration of the steam generator of the present invention.

5 is a plan view of a steam generator according to an embodiment of the present invention.

6 is a cross-sectional view showing the configuration of a steam generator according to an embodiment of the present invention.

7 and 8 are views showing the configuration of the reservoir according to an embodiment of the present invention.

9 is a cross-sectional view taken along the line II ′ of FIG. 7.

FIG. 10 is a cross-sectional view taken along the line II-II ′ of FIG. 7.

11 is a view showing a state that the outside air inlet hole of the reservoir according to the embodiment of the present invention is shielded.

Claims (11)

A nozzle body forming an appearance; And It is provided to the nozzle body, and includes a steam generator for supplying water to generate steam, In the steam generator, A water tank in which water is stored; A heating unit for heating the water supplied from the water tank; And It includes a reservoir for supplying water introduced from the water tank to the heating unit, In the reservoir, The nozzle of the cleaner, characterized in that the outside air inlet is formed so that the outside air can be introduced. The method of claim 1, In the reservoir, The nozzle of the cleaner provided with a shield to selectively shield the outside air inlet. The method of claim 2, In the reservoir, The nozzle of the cleaner, the coupling hole is formed so that the shield is coupled to one side of the reservoir. The method of claim 2, The shielding part of the cleaner nozzle, characterized in that for shielding the outside air inlet hole by the water pressure of the reservoir. The method of claim 1, The outside air inlet hole is a nozzle of the cleaner, characterized in that formed in a position higher than the center height of the reservoir. The method of claim 1, The nozzle of the cleaner is formed with a plurality of outside air inlet hole. Nozzle body; And It is provided in the nozzle body, and includes a steam generating device for generating steam from water, In the steam generator, A water tank in which water is stored; A water tank into which water is introduced from the water tank and in communication with the outside; And The nozzle of the cleaner provided in the reservoir, the shield includes a shield to enable the reservoir to shield the outside. The method of claim 7, wherein The shield unit of the cleaner, characterized in that for shielding the reservoir by the water pressure of the water stored in the reservoir. The method of claim 7, wherein In the reservoir, The nozzle of the cleaner further comprises an elastic member to elastically support the shield. The method of claim 7, wherein At least one outside air inlet hole through which the outside air flows is formed in the reservoir, and the internal pressure of the reservoir is formed at atmospheric pressure. The method of claim 10, The lower end of the shielding nozzle of the cleaner is located below the outside air inlet.

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