RU2455918C1 - Vacuum-cleaner nozzle - Google Patents

Abstract

FIELD: personal use articles.

SUBSTANCE: invention relates to a vacuum cleaner nozzle. Vacuum cleaner nozzle in accordance with the exemplary embodiment can reduce the time of evaporation and prevent leakage of water from the nozzle out. Vacuum cleaner nozzle comprises the nozzle body forming its appearance, the water tank located in the nozzle body and feeding water, a heating unit that heats the water fed from the water tank, and water storage tank having a portion for water storing and supply of water obtained from the water tank into the heating device; and the water storage tank includes a connecting part connecting with the outside air, and a barrier located on one section with the connecting part and providing passage of air but preventing water leakage, and the water storage tank additionally comprises a discharge station which releases water in one direction, and a guide channel located on the section for the storage of water and directing the water to move in the opposite direction to the water storage tanks.

EFFECT: development of a vacuum cleaner nozzle able to reduce the duration of vaporisation through improved design of steam generating unit located in the vacuum cleaner nozzle.

11 cl, 16 dwg

Description

FIELD OF THE INVENTION

An exemplary embodiment relates to a nozzle of a vacuum cleaner and, more specifically, to a nozzle of a vacuum cleaner capable of reducing the duration of vaporization by improving the design of the steam generating device installed in the nozzle of the vacuum cleaner.

Description of the prior art

With regard to vacuum cleaners as a device for facilitating human labor when performing cleaning, various types of vacuum cleaners are disclosed, such as a vacuum cleaner using a suction force, a washing vacuum cleaner sucking both water and air by injecting water, and a vacuum cleaner removing contaminants on the lower surface by steam injection.

In addition, a steam cleaner also appeared, capable of both absorbing contaminants with a vacuum cleaner and steam cleaning with a washing vacuum cleaner.

In this case, the nozzle of the steam vacuum cleaner includes a steam generating device generating steam, and the steam generating device includes a rag fixed on its lower part, and uses the supplied steam to remove contaminants on the lower surface. In addition, the steam generating device comprises a heater and enables the conversion of water into steam by heating to a high temperature.

The steam generating device encompasses an induction heating type comprising a heater in one portion of the water tank and generating steam by heating water in the water tank, and a tubular heating type generating steam by supplying a very small amount of water to the heater.

However, since the known induction heating type steam generating device heats a large amount of water, the duration of steam generation is increased, and the weight of the steam nozzle device is increased. In addition, since it is not easy to disconnect the water tank from the steam generating device, the likelihood that the water storage tank will become contaminated increases.

Moreover, since the steam-generating device of the tubular heating type contains a heater, the size and volume of which are small, the known steam-generating device of the tubular heating type injects water that does not turn into steam. As a result, the efficiency of vaporization is deteriorated, and the stability of the product is not provided.

In addition, the tubular heating type steam generating device must include a pump that delivers water to the heater, so that the cost is high.

A brief description of the present invention

The present invention was carried out with the aim of creating a nozzle of a vacuum cleaner capable of reducing the duration of steam generation by improving the design of the steam generating device.

In addition, the present invention was carried out with the aim of creating a nozzle of a vacuum cleaner, which allows easy passage of water from the water tank into the heating device through the water storage tank by setting the internal pressure of the water storage tank equal to atmospheric pressure.

In addition, the present invention was carried out with the aim of creating a nozzle of a vacuum cleaner, which prevents excessive supply of water to the heating device from the nozzle assembly or leakage of water to the outside.

In addition, the present invention was carried out with the aim of creating a nozzle of a vacuum cleaner, which provides cleaning of the water tank if necessary by disconnecting the water tank from the steam generating device.

An example embodiment of the present invention describes a vacuum cleaner nozzle comprising a nozzle body defining its appearance, a water tank located in the nozzle body and supplying water, a heating device heating water supplied from the water tank, and a water storage tank supplying water, obtained from a water tank into a heating device, the water storage tank including a connecting part connecting to the outside air and a barrier located on one portion of the connecting part and providing air passage, but preventing water leakage.

According to exemplary embodiments of the present invention, since a small amount of water is supplied to the heating device with the heater from the water storage tank, the duration of the steam generation can be reduced.

In addition, the barrier is located in the water storage tank to provide connection of the outdoor air to the water storage tank while preventing water from passing through the barrier, and as a result, the internal pressure of the water storage tank is maintained at atmospheric pressure, and water from the water storage tank is prevented from leakage to the outside.

In addition, the internal pressure of the water storage tank is set equal to atmospheric pressure to allow easy passage of water into the heating device from the water tank through the water storage tank.

A guide channel is formed in the water storage tank to provide a gradual supply of water to the heating device from the water storage tank, thereby preventing water from overflowing when a large amount of water is supplied to the heating device at a time.

Since the water tank can be easily installed in the nozzle body and removed from it, it is easy to supply water by using the water tank or to clean the water tank, thereby increasing user convenience.

In addition, since the steam generating device can be performed in a simple design, the total weight of the nozzle with the steam generating device can be reduced.

Brief Description of the Drawings

Figure 1 is a perspective view of a nozzle of a vacuum cleaner in accordance with a first embodiment of the present invention;

figure 2 is a perspective view of the inner part of the nozzle, showing the open state of the upper cover of the nozzle of the vacuum cleaner in accordance with the first embodiment of the present invention;

figure 3 is a perspective view of the configuration of the steam generating device in accordance with the first embodiment of the present invention;

4 is a schematic view of a configuration of a cap in accordance with a first embodiment of the present invention;

5 is a front view of a configuration of a steam generating device in accordance with a first embodiment of the present invention;

6 is a top view of the configuration of the cap in accordance with the first embodiment of the present invention;

7 is a sectional view showing the operation of a water tank and a water storage tank in accordance with a first embodiment of the present invention;

Fig.8 is a view in section along the line II-II 'in Fig.5;

Fig.9 is a perspective view with a spatial separation of the elements of the nozzle, showing the state in which the water tank is removed in accordance with the first embodiment of the present invention;

10 is a perspective view of a configuration of a removable assembly in accordance with a first embodiment of the present invention;

11 is a perspective bottom view of the configuration of the water tank in accordance with the first embodiment of the present invention;

Fig. 12 is a sectional view taken along line I-I 'in Fig. 1;

13 is a sectional view showing the operation of the removable assembly in accordance with the first embodiment of the present invention;

Fig is a perspective view with a spatial separation of the configuration elements of the steam generating device in accordance with the second embodiment of the present invention;

FIG. 15 is a schematic view of a configuration of a water tank in accordance with a second embodiment of the present invention; FIG. and

Fig.16 is a view in section along the line III-III 'in Fig.14.

Detailed Description of Preferred Embodiments

Embodiments of the present invention will be described in detail below with reference to the accompanying drawings. However, the essence of the present invention is not limited to the proposed embodiments, and another embodiment can be easily proposed by those skilled in the art who understand the idea of the present invention within the same idea of the present invention.

FIG. 1 is a perspective view of a nozzle of a vacuum cleaner in accordance with a first embodiment of the present invention, and FIG. 2 is a perspective view of an interior of a nozzle showing an open state of a top cover of a nozzle of a vacuum cleaner in accordance with a first embodiment of the present invention.

As shown in FIGS. 1 and 2, a vacuum cleaner nozzle according to a first embodiment of the present invention includes a nozzle body 10 defining an appearance of the nozzle, a top cover 20 covering the upper part of the nozzle body 10, side covers 22 covering both parts of the case 10 nozzles, and a connector 30 located on one section of the housing 10 of the nozzle and allowing the passage of air sucked by the nozzle into the main body (not shown) of the vacuum cleaner.

Although not shown in the drawing, the nozzle 1 of the vacuum cleaner is connected to the main body of the vacuum cleaner using an extension tube and a connecting sleeve. The connector 30 provides a connection nozzle 1 with a sliding tube.

The nozzle body 10 includes an air suction device 12, suctioning air containing contaminants from the surface to be cleaned, and a suction channel 13 allowing air to be sucked through the air suction device 12 to the connector 30.

The suction channel 13 may extend to the rear side of the air suction device 12.

In addition, the nozzle body 10 includes a steam generating device 100 that converts the supplied water into steam.

The steam generating device 100 includes a water tank 110 storing the supplied water, a water storage tank 120 located at the bottom of the water tank 110 into which water of a predetermined amount passes from the water tank 110, and a heating device 150 located on one a portion of a water storage tank 120 and heating water that extends from a water storage tank 120.

In the state in which the steam generating device 100 is installed in the nozzle 1, the water tank 110 may form part of the upper surface of the nozzle 1.

The support portion 21 onto which the water tank 110 is mounted is formed on the top cover 20. The support portion 21 may be recessed in a shape corresponding to the water tank 110.

A water storage tank 120 and a heating device 150 may be located on both sides of the suction channel 13.

In addition, the nozzle 1 includes a removable node 200, providing a connection with the possibility of removal of the water tank 110 with the body 10 of the nozzle. The removable assembly 200 includes a pressure member 210 that is pressed to disconnect the water tank 110.

The user actuates the pressure member 210 to enable disconnection of the water tank 110. In addition, when installing the water tank 110 in the nozzle body 10 and pressing down, the water tank 110 can be suspended on the nozzle body 10 using a predetermined suspension device. A detailed description thereof will be given with reference to the accompanying drawings.

In this case, the water tank 110 is located in the upper part of the water storage tank 120. In addition, a cap 140 is located between the water tank 110 and the water storage tank 120 for controlling water passing into the water storage tank 120 from the water tank 110. The cap 140 may be connected to the bottom of the water tank 110.

Below will be described the design of the steam generating device 100 with reference to the accompanying drawings.

FIG. 3 is a perspective view of a configuration of a steam generating device in accordance with a first embodiment of the present invention, and FIG. 4 is a schematic view of a configuration of a cap in accordance with a first embodiment of the present invention.

As shown in FIGS. 3 and 4, the steam generating device 100 according to the first embodiment of the present invention includes a water storage tank 110 storing water, a water storage tank 120 located at the bottom of the water tank 110 and selectively receiving water of a predetermined quantities from the water tank 110, and a heating device 150 located on one portion of the water storage tank 120 and generating steam by heating the water that passes from the water storage tank 120.

Specifically, the water tank 110 includes a storage compartment in which water is stored, and a storage compartment can be arranged in a horizontal direction. The user disconnects the water tank 110 and fills the water tank 110 with water and, after that, can connect the water tank 110 to the nozzle body 10. Therefore, water from the water tank 110 can pass into the heating device 150 through the water storage tank 120.

The water tank 110 includes an opening 115 of the tank (see FIG. 8) through which water exits. While the water tank 110 is connected to the nozzle body 10, the opening 115 of the tank may be positioned to face down.

In addition, the water storage tank 120 may include a storage compartment in which the water of the water tank 110 is stored. The water storage compartment of the water storage tank 120 may be smaller than the storage compartment of the water tank 110. That is, water from the water tank 110 gradually passes into the water storage tank 120 and, after that, is located in the heating device 150.

Therefore, a small amount of water is supplied from the storage tank 120 to the heating device 150, which heats the supplied water, thereby reducing the duration of vaporization.

At the same time, the cap 140, providing selective passage of water into the tank 120 for storing water from the tank 110 for water, is located on the lower portion of the opening of the tank. The cap 140 may be connected to the water tank 110 using a screw connection method. However, when the cap 140 is easily connected to the water tank 110, this will be sufficient, and the connection method is not limited to one connection method. A water tank 110 may be mounted on top of the water tank 120 in a state in which the cap 140 is connected to the water tank 110.

Specifically, the cap 140 includes a cap body 141 defining its appearance, a valve member 142 movably located in the upper part of the cap body and regulating the water supplied to the water storage tank 120 from the water tank 110, a guiding element 143 guiding the movement a valve member 142, and a closure member 145 connected to the guide member 143.

The interior of the cap body 141 is empty to allow water to enter therein. In addition, the upper end and lower end of the cap body 141 are open to allow water to pass into the water storage tank 120 from the water tank 110. That is, the channel for movement for the passage of water can be formed in the housing 141 of the cap.

In a state in which the water tank 110 and the cap 140 are connected to each other, the upper end of the cap body 141 can be mounted on one portion of the protrusion 117 (see FIG. 8) of the water tank 110.

The valve member 142 may be coupled to the guide member 143 using a forced installation method. However, the connection method is not limited to this, and as long as the valve element 142 and the guide element 143 move as a unit, different connection methods can be proposed.

In addition, an elastic element 146 is located in the lower part of the guide element 143 to provide elastic movement of the guide element 143 and the valve element 142. The elastic element 146 can be located on the outside of the guide element 143. In addition, one part of the elastic element 146 is supported in one section body 141 of the cap, and the other part of the elastic element 146 is supported on the closing element 145.

The closure member 145 may interact with the restriction member 125 (see FIG. 5) formed in the water storage tank 120. When the cap 140 is connected to the upper portion of the water storage tank 120, the restriction member 125 presses the lower surface of the closure member 145. During this process, the closure member 145 moves upward and the resilient member 146 is compressed. In addition, when moving the closure member 145, the guide member 143 and the valve member 142 also move upward.

As the valve member 142 moves upward, the valve member 142 may be spaced apart from the upper surface of the cap body 141. In addition, water from the water tank 110 may pass into the interior of the cap body 141 through the gap.

5 is a front view of a configuration of a steam generating device in accordance with a first embodiment of the present invention, and FIG. 6 is a top view of a configuration of a cap in accordance with a first embodiment of the present invention. The steam generating device shown in FIGS. 5 and 6 does not contain a water tank 110 and a cap 140.

As shown in FIGS. 5 and 6, a water storage container 120 in accordance with a first embodiment of the present invention includes a water storage container body 121 comprising a water storage portion and a cap connecting portion 122 formed in an upper portion of the housing 121 containers for storing water and providing the connection of the cap 140. The cap 140 may fit on the plot 122 for connecting the cap.

In addition, the water storage tank 120 includes a restriction member 125, which serves as an obstacle to the closure member 145 when the cap 140 is connected to it. The restriction member 125 protrudes upward from the cap connection portion 122 and can be supported on the water storage tank 120 by the support portion 126.

While the inner part of the tank 120 for storing water is made with the possibility of connection with the outside air, and, as a result, the inner part of the tank 120 for storing water can be at atmospheric pressure.

To ensure this, the connecting part 123, providing the connection of the inner part of the tank 120 for storing water with outside air, is formed in the housing 121 of the tank for storing water. The connecting portion 123 projects upward from the surface of the housing 121 of the water storage container. The connecting portion 123 protrudes upward for easy entry and exit of air, while the water stored in the water storage tank 121 can be prevented from leaking to the outside.

The barrier 170, providing only selective passage of air, is located on the upper portion of the connecting portion 123. The barrier 170 may be made of fiber material.

In addition, the barrier 170 has a size corresponding to the connecting part 123 for closing the connecting part 123. The barrier 170 can prevent water from leaking from the water storage tank 120 to the outside. Therefore, even if the water storage tank 120 oscillates or turns over during use of the nozzle 1, water in the water storage tank 120 can be prevented from overflowing to the outside.

On the other hand, outside air may pass into the water storage tank 120 through the barrier 170, and, as a result, the inside of the water storage tank 120 may be at atmospheric pressure.

The portion 122 for connecting the cap includes a receiving element 127, accommodating the body 141 of the cap, and a sealing element 128 located on the outer side of the receiving element 127 and preventing leakage of water from the cap 140.

The opening 129 of the water storage tank, allowing water passing through the cap 140 to the water storage tank 120, is located in the receiving element 127. When the housing 141 of the cap is received in the receiving element 127, water passing through the inside of the housing 141 of the cap can pass into the tank 120 for storing water through the opening 129 of the tank for storing water.

At the same time, a heating device 150 that converts water obtained from the water storage tank 120 to steam is located on one portion of the water storage tank 120. The heating device 150 includes a heat generating heater 151, and a steam discharging section 155 releasing steam generated by the heater 151. A housing heater, a positive temperature coefficient heater, a ceramic heater and the like can be used as the heater 151.

Although not shown, a heat transfer preventing member preventing direct heat transfer of the heater 151 to the surface of the heating device 150 may be located in at least one portion of the heater 151. The heat transfer preventing member can absorb a predetermined amount of water from the heating device 150. In this case, an element for preventing heat transfer may be located to surround the periphery of the heater 151.

In addition, a heater 151 is located at the bottom of the heating device 150, and a steam discharge portion 155 may be located at the top of the heating device 150. Steam is lighter than water. Therefore, even if the steam discharge portion 155 is located at the top of the heating device 150, steam can easily exit through the steam release portion 155.

A connecting channel 180, allowing water to pass from the water storage tank 120 to the heating device 150, is located between the water storage tank 120 and the heating device 150.

7 is a sectional view showing the operation of a water tank and a water storage tank in accordance with a first embodiment of the present invention.

As shown in FIG. 7, water stored in the water tank 110 according to the first embodiment of the present invention can pass into the water storage tank 120 through the opening 115 of the tank. During this process, the valve element 142 of the cap 140 is open.

In addition, water from the water storage tank 120 passes into the heating device 150 through the connecting channel 180.

Water from the water tank 110 may pass into the heating device 150 through the water storage tank 120 in accordance with Pascal's rule. Pascal's rule confirms the theory that the pressure applied to the fluids contained in a sealed container is transferred to all parts of the fluids and the wall of the container containing the fluids without decreasing its size.

As described above, the air pressure in the tank 120 for storing water is maintained equal to atmospheric pressure. When the water tank 110 is mounted on the water tank 120 in a state in which the cap 140 is connected to the water tank 110, the closure member 145 and the restriction member 125 interact with each other. Therefore, the resilient member 146 is compressed, and the valve member 142 is moved upward to open the container opening 115.

When the cap 140 of the tank is open, water from the water tank 110 drips into the water storage tank 120 by gravity, i.e. water pressure. During this process, air from the water storage tank 120 passes into the water tank 110 through the cap 140.

Then, when the water level in the water storage tank 120 rises and closes the opening 129 of the water storage tank, air from the water storage tank 120 cannot pass into the water tank 110 through the cap 140 of the tank. In this state, vacuum pressure is created in the water tank 110, and water from the water tank 110 can no longer pass into the water tank 120.

Moreover, when the cap is separated from the water storage tank 120, the resilient member 146 returns to its original location, and the valve member 142 moves downward and closes the upper portion of the cap body 141.

Fig.8 is a view in section along the line II-II 'in Fig.5.

As shown in FIG. 8, a water storage tank 120 in accordance with a first embodiment of the present invention includes a water storage tank 121 defining its appearance and a guide channel 130 located in the housing 121 of the water storage tank and directing movement water from a water storage tank.

Specifically, the water storage container body 121 includes a water storage portion 124 and a water storage discharge port 121a for allowing water to pass to the outside of the water storage container body 121 in a state in which a portion of the water storage tank 121 water storage is open. The connecting channel 180 may be connected to the discharge section 121a of the water storage tank.

The guide channel 130 includes a first guide element 131 extending in one direction from one portion of the water storage container body 121, and a second guide element 132 extending in the other direction from the first guide element 131. That is, the first guide element 131 and the second guide element 132 may extend in different directions.

In the guide channel 130, the first guide element 131 and the second guide element 132 can be connected as separate elements, and the first guide element 131 and the second guide element 132 can be integrally formed as one element.

When the first guide member 131 and the second guide member 132 are integrally formed, the second guide member 132 may be bent from the end of the first guide member 131. As one example of implementation, the guide channel 130 may be bent in the form of "רּ", as shown in the drawing .

The operation of the water storage tank 120 and the guide channel 130 in accordance with an embodiment will be described.

When the water level of the water storage tank 120 is higher than the water level of the heating device 150, the water stored in the water storage section 124 is guided by a discharge channel 130 through the discharge section of the water storage tank 121a.

Specifically, the water stored in the water storage portion 124 extends in a direction (first direction) in one portion of the first guide member 131. In this document, a channel formed in a direction is called a “first channel”. In addition, water passing through the first channel may pass in a direction opposite to the direction of passage of water passing through the connecting channel 180.

Water flowing through the first channel turns and then flows in the b direction (second direction) in another portion of the first guide member 131. In this document, the channel formed in the b direction is called the “second channel”. In addition, water passing through the second channel may pass in a direction perpendicular to the direction of passage of water passing through the connecting channel 180.

The water flowing through the second channel turns and then moves in the c direction (third direction) in one section of the second guide member 132. In this document, the channel formed in the c direction is called the “third channel”. Water passing through the third channel extends to the outside of the water storage tank 120 through the discharge section 121a of the water storage tank and can pass into the heating device 150 through the connecting channel 180.

As described above, water stored in the water storage portion 124 is rotated in a plurality of directions for passage before exiting to the outside of the water storage tank 120. In addition, the passage deflected by the guide channel 130 may differ from the direction of passage of the water passing through the connection channel 180.

That is, the water stored in the water storage portion 124 does not immediately pass into the heating device 150, but rather leaves out as a result of rotation in different directions due to the guide channel 130, as a result only a small amount of water can pass into the heating device 150. In addition, even in the case where the nozzle 1 is inclined together with the heating device 150, the water in the water storage portion 124 is prevented from passing into the heating device 150 at a time.

Therefore, since only a small amount of water that is stored in the water storage portion 124 passes into the heating device 150, the duration of vaporization in the heating device 150 can be shortened.

Furthermore, even if the water oscillates while the nozzle 1 oscillates or flips, the guide channel 130 is used as a barrier to prevent water from leaking to the outside of the nozzle.

In this case, although the guide channel 130 includes a first guide element 131 and a second guide element 132 in the drawing, the guide channel 130 may contain more guide elements. In addition, the guide elements 131 and 132 are perpendicular to each other and can be located at different angles with each other.

Fig.9 is a perspective view with a spatial separation of the elements of the nozzle, showing the state in which the water tank is separated in accordance with the first embodiment of the present invention, Fig.10 is a perspective view of the configuration of the removable node in accordance with the first embodiment of the present invention, Fig. 11 is a bottom perspective view of a configuration of a water tank in accordance with a first embodiment of the present invention, and FIG. 12 is a sectional view taken along line II ′ in FIG. 1.

As shown in FIGS. 9-12, the detachable assembly 200 in accordance with the second embodiment of the present invention includes a user-actuated push member 210, a detachable guide member adapted to move forward and backward by actuating the push member 210 and a movement plate 230 selectively mounted on the removable guide member 220.

Specifically, the pressure member 210 is configured to move up and down with respect to the support portion on which the water tank 110 is mounted.

In this case, the protrusion 21a protruding from one surface of the supporting portion 21 is formed on the supporting portion 21. When moving the pressing member 210, at least a portion of the pressing member 210 can be mounted on the protrusion 21a.

The pressure member 210 includes a pressure element housing 211 defining a first tilt 211a, and a suspension hook 225 extending downward from the pressure element housing 211. The hook 225 for hanging fits in the protrusion 21a. In addition, the protrusion 21a includes a guide groove 27a guiding the movement of the hook 215 for hanging.

When the push member 210 is pressed down, the hook 215 moves down in the guide groove 27a, and when the push member 210 moves up, the hook 215 can be mounted on the upper end of the guide groove 27.

The removable guide member 220 is located on one portion of the push member 210. At least one portion of the removable guide member 220 may be positioned to fit in the push member 210.

Specifically, the removable guide member 220 includes a guide body 221 defining a second tilt 221a, a suspension grip 222 extending forward from the guide body 221, and a hanging protrusion 224 extending downward from the guide body 221.

The first slope 211a and the second slope 221a are formed in opposite directions to each other. In addition, the first tilt 211a is configured to contact the upper portion of the second tilt 221a.

In addition, the suspension grip 222 can be mounted on the water tank 110 when the water tank 110 is installed in the support portion 21. In addition, the water tank 110 includes a groove 112 of the vessel located to correspond to the suspension grip 222. The grip 222 for hanging is inserted into the groove 112 of the tank to connect the tank 110 for water with the top cover 20.

In this case, the water tank 110 includes a recess 113 recessed in a predetermined direction. The recess 113 may be located in the lower portion of the groove 112 of the container. When the pressure member 210 is pressed, the recess 113 may be supported on the top of the removable guide member 220, while the water tank 110 is separated from the top cover 20.

In addition, the removable protrusion 115 is located on the front surface of the water tank 110 to provide a connection between the water tank 110 and the support portion 21 in a state in which the water tank 110 is installed on the support portion 21. The removable groove 25 is located at the location of the support portion 21, corresponding to the removable protrusion 115. When connecting the removable protrusion 115 with the removable groove 25, the water tank 110 can easily be connected to the supporting portion 21.

The hanging protrusion 224 extends downward from the guide body 221 and then bends forward. That is, the protrusion 224 for hanging, in General, has the form of "┘".

The hanging protrusion 224 may be mounted on the movement plate 230. While the plate 230 movement includes a groove 231 for hanging, located to correspond with the protrusion 224 for hanging. The hanging protrusion 224 includes a third tilt 224a mounted in the hanging groove 231.

A third slope 224a is formed at the front end of the hanging protrusion 224 and may serve as an obstacle to one surface of the movement plate 230, while the water tank 110 is connected to the support portion 21.

In addition, a first resilient member 232 is located at the bottom of the displacement plate 230 to resiliently displace the displacement plate 230. A conventional spring can be used as the first resilient member 232. The first resilient member 232 is compressed, while the protrusion 224 for hanging is connected to the groove 231 for hanging.

In contrast, when the suspension protrusion 224 is removed from the suspension groove 231, the first resilient member 232 is tensioned, and during this process, the movement plate 230 can move up.

Since the moving plate 230 elastically supports the lower part of the water tank 110, when moving up the moving plate 230, the water tank 110 also moves upward, disconnecting from the supporting portion 21.

The second elastic element 227, providing elastic support for the removable guide element 220 on the support portion 21, is located on the rear portion of the guide housing 221. A conventional spring can be used as the second elastic element 227.

In addition, the removable guide member 220 includes a spring connecting portion 226 connected to the second elastic member 227. The spring connecting portion 226 extends back from the rear surface of the guide body 221. When the removable guide member 220 is moved backward, the second elastic member 227 is compressed, and when moving the removable guide member 220 forward, the second elastic member 227 is pulled.

A removable assembly in accordance with an embodiment will be described below.

13 is a sectional view showing the operation of the removable assembly in accordance with the first embodiment of the present invention. As shown in FIG. 13, in the case of actuating the pressure member 210 to disconnect the water tank 110, a series of sequential operations will be described.

When the user clicks on the pressure member 210, the first tilt 211a presses the second tilt 221a down. In this case, since the removable guide member 220 is resiliently supported on the support portion 21, the removable guide member 220 is limited to move downward.

In addition, the removable guide member 220 moves backward while compressing the second elastic member 227 (direction e). Therefore, the suspension gripper 222 is located at a distance from the groove 112 of the container, and the removable guide member 220 and the water container 110 are disconnected from each other.

Meanwhile, when the removable guide member 220 moves backward, the hanging protrusion 224 also moves backward. Therefore, the protrusion 224 for hanging is located at a distance from the groove 231 for hanging, and the removable guide element 220 and the plate 230 of the movement are disconnected from each other.

In this case, the movement plate 230 can move upward under the action of the restoring force of the first elastic element 232 (direction f). Therefore, the water tank 110 is moved upward by the transfer plate 230, and the user can easily grab and disconnect the water tank 110, which moves upward.

After that, when the pressure member 210 is pressed, the removable guide member 220 moves forward under the action of the restoring force of the second elastic member 227. That is, the grip 222 for hanging and the protrusion 224 for hanging can move forward.

Although not shown in the drawing when the full container 110 is completely disconnected, the suspension gripper 222 is located in the recess 113, and the end of the suspension protrusion 224 is located in the lower part of the transfer plate 230.

Moreover, when the water tank 110 is connected, the lower part of the water tank 110 presses the downwardly moving plate 230. Therefore, the movement plate 230 may interfere with the third tilt 224a, and during this process, the hanging protrusion 224 moves backward.

That is, the removable guide member 220 moves backward. In addition, when the water tank 110 reaches the junction location, the removable guide member 220 moves forward by the restoring force of the second elastic element 227. Therefore, the suspension gripper 222 can be inserted into and connected to the tank groove 112, and the suspension protrusion 224 can inserted into the groove 231 for hanging and connected to it.

According to the above configuration, since the water tank can be disconnected by simply actuating a push-button type element, the user can easily fill the water tank with water and easily clean the water tank.

In addition, since the water tank can be easily connected to the nozzle by pressing the water tank down while connecting the water tank, the convenience of the user is improved, and the reliability of the product is improved.

Fig is a perspective view with a spatial separation of the elements, showing the configuration of the steam generating device in accordance with the second embodiment of the present invention, Fig is a schematic view of the configuration of the water storage tank in accordance with the second embodiment of the present invention, and Fig is a view in section along the line III-III 'in Fig.14.

As shown in FIGS. 14 and 16, the steam generating device 300 according to the second embodiment of the present invention includes a water storage tank 310, a water storage tank 330, located at the bottom of the water tank 310 and selectively receiving water of a predetermined the amount from the water tank 310, and a heating device 350 located on one portion of the water storage tank 330 and generating steam by heating water passing into it from the water storage tank 330.

Specifically, an opening 312 of the container, open to allow the passage of water stored in the water tank 310 to the water storage tank 330, is located on one portion of the water tank 310. In addition, the lower part of the water tank 310 is tilted down to the opening 312 of the tank. Therefore, the water stored in the water tank 310 can easily pass into the opening 312 of the tank.

A container cap 320 selectively closing the container opening 112 is located on the container opening 312. A cap 320 of the container extends into the interior of the water storage container 330.

In addition, the steam generating device 300 includes a support plate 316 onto which a water tank 310 is mounted. The support plate 316 may be located on the same surface as the upper surface of the water storage container 330.

In addition, the removable portion 317 for securing the water tank 310 that is installed is formed on the support plate 317. The removable portion 317 may be in the form of a recess recessed downward. To match this, a removable protrusion 319 formed to connect to the removable portion 317 is formed in the water tank 310. The removable protrusion 319 may be bent into a ╔ shape.

In this case, the water storage tank 330 includes an opening 332 of the water storage tank into which water supplied from the water tank 310 passes. The opening 332 of the water storage container may be larger than the opening 312 of the container. Since the opening 332 of the water storage container is larger than the opening 312 of the container, the cap 320 of the container can easily extend into the interior of the container 330 for storing water from the lower portion of the opening 312 of the container.

A hole 337 for the intake of external air, allowing the passage of external air, is formed in the tank 330 for storing water. The air inlet port 337 may be referred to as the “connecting portion”. A plurality of outdoor air inlets 337 may be formed on the outer surface of the water storage container 330. As air passes through the outside air inlet 337, the inside of the water storage container 330 may be at atmospheric pressure.

A sealing member 314 for preventing water leakage from the water storage tank 330 is located between the water tank 310 and the water storage tank 330. The sealing element 314 is located on the outer peripheral surface of the opening 332 of the water storage tank.

In addition, a heating device 350 that heats the water obtained from the water storage tank 330 into steam is located on one portion of the water storage tank 330.

A heater (not shown) that heats the water to generate steam is located in the heating device 350. In addition, the heating device 350 includes a steam discharge section 355 that releases the generated steam. Section 355 for the release of steam has a tubular shape. Part of the steam discharge section 355 extends inward, and the rest may protrude on the outside of the heating device 350.

Below will be described the configuration of the tank 330 for storing water, including a hole 337 for the intake of external air.

An outside air inlet 337 is located substantially on the upper part of one surface of the water storage container 330. A plurality of outdoor air inlets 337 may be parallel to the upper surface of the water storage container 330.

In addition, a protective device 360 that selectively closes the outside air inlet 337 is located on the inside of one surface of the water storage container 330. The protective device may be called a “barrier." The protective device 360 has a size sufficient to simultaneously close a plurality of outdoor air inlets 137 and may be in the form of a thin film.

The protective device 360 may close the outside air inlet 337 when the water pressure in the water storage tank 330 is in effect. On the contrary, in the case where the water pressure acts on the protective device 360 due to the low water level in the water storage container 330, the protective device 360 is located at a distance from the water storage vessel 330, and the outside air can pass through the outside air inlet 337.

In addition, bent sections 361 bent backward from the front surface of the protective device 360 are located at both ends of the protective device 360. Elastic elements 364 providing elastic support of the protective device 360 to the water storage container 330 are connected to the bent sections 361. The elastic elements 364 can be located on both sides of the protective device 360.

One portion of the elastic member 364 is fixed to the bent portion 361, and another portion of the elastic member 364 is fixed to the inner surface of the water storage container 330.

In addition, the connecting hole 339, providing the connection of the protective device 360 with a tank 330 for storing water, passes through the tank 330 for storing water. A plurality of connecting holes 339 are formed among the plurality of outdoor air inlets 337 and there may be more than the external air inlets 337. In addition, the openings 337 for the intake of external air and the connecting holes 339 can be located on one straight line.

Connecting holes 339 and openings 337 for external air inlet may be located above the center of the water storage container 330 in the upper part of the water storage container 330. Therefore, in the case where the water level in the water storage vessel 330 is not higher than the center of the water storage vessel 330, the likelihood that water will exit through the external air inlets 337 or the connecting openings is reduced.

The connecting protrusion 362 inserted into the connecting hole 339 is located on the protective device 360. While the protective device 360 closes the hole 337 for the intake of external air, the connecting protrusion 362 can be inserted into the connecting hole 339.

In this case, the lower end of the protective device 360 may be located below the opening 337 for the intake of external air and the connecting hole 339 at a distance t1. In this case, in a state in which the protective device 360 is located at a distance from the water storage tank 330, the water in the water storage tank 330 may act on the protective device 360 before the water exits through the openings 337 for external air inlet. Therefore, water in the water storage tank 330 can be prevented from exiting through the openings 337 for the intake of outside air.

Furthermore, in a state in which the protective device 360 is located at a distance from the inner surface of the water storage container 330, the front 360a of the protective device 360 may be located at a distance l1 from the water storage vessel 330. In this document, the protective device 360 may be located at a distance from the water storage container 330 under the action of the restoring force of the elastic member 364. l1 may be approximately 1 mm.

Below will be described the operation of the protective device 360.

When no water is supplied to the water storage tank 330, or the water storage tank 330 is filled with a small amount of water, the protective device 360 is located at a distance from the inner surface of the water storage tank 330. In addition, since the outside air passes into the water storage vessel 330 through the outside air inlets 337, the internal pressure of the water storage vessel 330 may be equal to atmospheric pressure.

Moreover, when water passes from the water tank 310, the water level of the water storage tank 330 gradually rises. In this case, when the water is in contact with the protective device 360, i.e. when water pressure acts on the protective device 360, the protective device 360 overcomes the restoring force of the elastic element 364 and moves to the water storage tank 330.

In addition, when the protective device 360 is in close contact with the inner surface of the water storage container 330, the connecting protrusion 362 is inserted into the connecting hole 339. In addition, the front 360a of the protective device 360 closes the openings 337 for the outside air inlet. In this case, the outside air can no longer pass into the water storage tank 330 through the outside air inlets 337, and the inside of the water storage tank 330 is closed from the outside.

In this state, when water from the water storage tank 330 is moved to the heating device 350, the water level in the water storage tank 330 decreases. In addition, when the water level in the water storage tank 330 is lower than the lower end of the protective device 360, the water pressure no longer acts on the protective device. Therefore, the protective device 360 is located at a distance from the inner surface of the water storage vessel 330 under the action of the restoring force of the elastic element 364, and outside air may enter.

By activating the outdoor air inlets 337 and the protective device 360, the internal pressure of the water storage vessel 330 can be easily set to atmospheric pressure.

Furthermore, when the water level in the water storage tank 330 rises in a state in which the outdoor air inlets 337 are open, the outdoor air inlets 337 are closed, thereby preventing water from leaking from the external water storage tank 337 through openings 337 for external air inlet.

In addition, even when the water storage tank fluctuates when the nozzle of the vacuum cleaner is actuated, the water acts on a protective device that can close the openings for the intake of outside air, thereby preventing water leakage.

According to exemplary embodiments, a barrier is formed in the water storage container to provide connection of outdoor air to the water storage tank while blocking the passage of water through the barrier, and as a result, the internal pressure of the water storage tank is maintained at atmospheric pressure and the water in the tank Water storage is prevented from leaking to the outside. Therefore, industrial applicability is exceptional.

Although the present invention has been described in relation to what is considered to be practical examples of implementation, it should be understood that the present invention is not limited to the disclosed embodiments, but rather is understood to include various modifications and equivalent arrangements included in the essence and the scope of the attached claims. Therefore, exemplary embodiments will be modified without departing from the spirit and scope of the present invention.

Claims (11)

1. The nozzle of the vacuum cleaner containing the nozzle body, forming its appearance, a water tank located in the nozzle body and supplying water, a heating device that heats the water supplied from the water tank, and a water storage tank having a part for storing water and supplying water obtained from the water tank to the heating device, the water storage tank including a connecting part connecting to the outside air and a barrier located on one portion of the connecting part and providing passage REPRESENTATIONS air, but prevents the leakage of water, wherein the water storage tank further comprising a discharge portion, which produces water in one direction, and a guide channel disposed on the water storage portion and to guide the water to move in the other direction in the water storage tank. 2. The nozzle according to claim 1, in which the connecting part protrudes upward from the body of the tank for storing water. 3. The nozzle according to claim 1, in which the guide channel includes a first guide element extending in one direction from the body of the water storage tank and a second guide element extending in the other direction from the first guide element. 4. The nozzle according to claim 3, in which the first guide element and the second guide element are integral, and the second guide element can be bent from the end of the first guide element. 5. The nozzle according to claim 1, in which the barrier closes the open upper surface of the connecting part. 6. The nozzle according to claim 1, additionally containing a removable node, providing a connection with the possibility of disconnecting the water tank with the supporting portion of the nozzle body. 7. The nozzle according to claim 6, in which the removable assembly includes a working pressure member, a removable guide element movable by the pressure member, and an elastic element resiliently supporting the removable guide element on the nozzle body. 8. The nozzle according to claim 7, further comprising a movement plate selectively mounted on a removable guide member and configured to move. 9. The nozzle of claim 8, in which the removable guide element moves forward and backward, and the movement plate moves up and down. 10. The nozzle according to claim 7, in which the pressure element includes a pressure element body forming a first inclination, and a suspension hook extending from the pressure element body and placed in a protrusion of the support portion. 11. The nozzle of claim 10, in which the removable guide element includes a guide body forming a second tilt, the direction of the first tilt being opposite to the direction of the second tilt.

Images