CN115886674A - Steam mop - Google Patents

Abstract

The embodiment of the application provides a steam mop, which comprises a machine body, a mop and a steam generator, wherein the mop is arranged at one end of the machine body; steam generator sets up in the fuselage, and steam generator is including the shell that has the water inlet and set up the core that generates heat in the shell, and the core that generates heat has the boiling face, is in the horizontal operating condition that goes out vapour direction and horizontal plane parallel when steam mop, and steam generator is the tilt state, and steam generator satisfies along the contained angle a between the extension line of direction of height and the horizontal plane: when the steam mop is in a working state, water flow injected into the shell from the water inlet can fall onto the boiling surface under the action of self gravity, wherein the working state at least comprises a declination working state and a horizontal working state. The steam mop of this application embodiment all can be fast under decline operating condition and the horizontal operating condition produce lasting steam.

Description

Steam mop

Technical Field

The application relates to the field of electrical equipment, in particular to a steam mop.

Background

Steam mop mainly leans on steam generator to heat water into steam, and steam releases bottom plate, window, kitchen workstation etc. position through the pipeline, and normal steam generator's working interface is its boiling face mainly, and water drops on the boiling face and releases the outside after heating the vaporization, and among the correlation technique, water free fall will have certain water storage capacity to reach the boiling face and heat behind the body, from this, has the heating efficiency low, can not form the problem of lasting steam fast.

Disclosure of Invention

In view of the above, it is desirable to provide a steam mop having high heating efficiency and capable of rapidly generating continuous steam.

To achieve the above objects, embodiments of the present application provide a steam mop including:

a body;

the mop is arranged at one end of the machine body;

set up steam generator in the fuselage, steam generator is including the shell that has the water inlet and setting up heating core in the shell, heating core has the boiling face, works as steam mop is in out the horizontal operating condition that vapour direction and horizontal plane are parallel, steam generator is the tilt state, steam generator satisfies along the contained angle a between the extension line of direction of height and the horizontal plane: when the steam mop is in the downward inclination working state, the machine body is in the inclination state and the mop is positioned at the lower end of the machine body along the inclination direction.

In one embodiment, the working state further comprises a lifting working state, when the steam mop is in the lifting working state, the machine body is in an inclined state, and the mop is positioned at the upper end of the machine body along the inclined direction.

In one embodiment, the steam generator is inclined downwardly from the end adjacent the mop towards the end remote from the mop when the steam mop is in the horizontal operating condition.

In one embodiment, the included angle a is greater than 0 ° and equal to or less than 45 °.

In one embodiment, the included angle a is between 15 ° and 30 °.

In one embodiment, the heat generating core has a secondary heating passage, and an axis of the secondary heating passage extends in a height direction of the steam generator.

In one embodiment, the steam mop further comprises a steam outlet arranged in the machine body, the steam outlet is provided with a steam outlet channel, and when the steam mop is in the horizontal working state, the axis of the steam outlet channel is parallel to the horizontal plane.

In one embodiment, when the steam mop is in the horizontal working state, the inclination direction of the boiling surface is consistent with the inclination direction of the steam generator, and the water inlet is positioned at the upper side of the shell along the inclination direction.

In one embodiment, the boiling surface is located on one side of the heating core close to the water inlet, and when the steam mop is in the horizontal working state, the water inlet is located on the upper side of the heating core.

In one embodiment, the heating core is formed with water inlet channel and water boiling tank, at least one end of the water inlet channel along the opposite two ends of the extending direction is provided with the water boiling tank, the water inlet is communicated with the water inlet channel, the water inlet channel is communicated with the water boiling tank, and the bottom surface of the water boiling tank is the boiling surface.

In one embodiment, when the steam mop is in the horizontal working state, the boiling surface is arranged at a lower height than the bottom surface of the water inlet channel.

In one embodiment, in the working state of the steam mop, the projection range of the water inlet along the vertical direction on the horizontal plane is positioned in the projection range of the boiling plane.

The embodiment of the application provides a steam mop, steam mop includes fuselage, mop and steam generator, is in the horizontal operating condition who goes out vapour direction and horizontal plane parallel when steam mop, and steam generator is the tilt state, and steam generator satisfies along the contained angle a between direction of height's the extension line and the horizontal plane: under steam mop is in operating condition, the rivers that pour into in the shell from the water inlet can fall on steam generator's the boiling face under self action of gravity, therefore, under steam mop is in operating condition, no matter steam generator is in decline operating condition or horizontal operating condition, the rivers that pour into in the shell from the water inlet can both fall on steam generator's the boiling face under self action of gravity, thereby can be so that the rivers that fall on the boiling face are by the heating of boiling face and the vaporization, and then can make steam mop can be quick the steam that the production lasts.

Drawings

FIG. 1 is a schematic structural view of a steam mop according to an embodiment of the present application, wherein the steam mop is in a state in which a body is vertically disposed;

FIG. 2 is a schematic structural view of the steam mop shown in FIG. 1, wherein the steam mop is in a mop mode;

FIG. 3 is a schematic view of the steam mop of FIG. 1 with the mop omitted, wherein the steam mop is in a horizontal working position;

FIG. 4 is a schematic view of the steam mop of FIG. 1 with the mop omitted, wherein the steam mop is in a raised working position;

FIG. 5 is an enlarged view taken at A in FIG. 1;

fig. 6 is a schematic structural view of the steam generator shown in fig. 1;

FIG. 7 is a sectional view taken along line B-B of FIG. 6;

FIG. 8 is a schematic structural view of the heat generating core shown in FIG. 6;

fig. 9 is a schematic structural view of the steam outlet nozzle shown in fig. 1.

Description of the reference numerals

A body 10; a mop 20; a steam generator 30; a housing 31; a water inlet 31a; a heat generating core 32; boiling surface 32a; a water inlet passage 32b; a boiling water tank 32c; a water hanging member 32d; a secondary heating path 321; a steam outlet 33; a steam outlet passage 33a; a water tank 40; an electromagnetic pump 50.

Detailed Description

It should be noted that the embodiments and technical features of the embodiments in the present application may be combined with each other without conflict, and the detailed description in the detailed description should be understood as an explanation of the gist of the present application and should not be construed as an undue limitation to the present application.

The embodiment of the application provides a steam mop, please refer to fig. 1 to 8, the steam mop comprises a machine body 10, a mop 20 and a steam generator 30, the mop 20 is arranged at one end of the machine body 10; the steam generator 30 is arranged in the body 10, the steam generator 30 comprises a shell 31 with a water inlet 31a and a heating core 32 arranged in the shell 31, the heating core 32 has a boiling surface 32a, when the steam mop is in a horizontal working state that the steam outlet direction is parallel to the horizontal plane, the steam generator 30 is in an inclined state, and an included angle a between an extension line of the steam generator 30 along the height direction and the horizontal plane satisfies: when the steam mop is in the working state, the water flow injected into the housing 31 from the water inlet 31a can fall onto the boiling surface 32a under the action of its own gravity, wherein the working state at least includes a declination working state and a horizontal working state, and when the steam mop is in the declination working state, the machine body 10 is in the inclined state and the mop 20 is located at the lower end of the machine body 10 along the inclined direction.

Specifically, the steam mop generally has a floor mop mode and a handheld mode, the working states of the steam mop of this embodiment at least include a declination working state and a horizontal working state, referring to fig. 2, when the steam mop is in the floor mop mode, the steam mop is in the declination working state, the body 10 is in the inclined state, and the floor mop 20 is located at the lower end of the body 10 along the inclined direction, in the floor mop mode, the body 10 generally forms a certain angle b with the ground, exemplarily, the range of b may be 45 ° to 60 °, and when the steam mop is in the handheld mode, the steam mop may form any one of the declination working state and the horizontal working state, wherein, referring to fig. 2, the declination working state of the steam mop in the handheld mode is the same as the floor mop mode, and the body 10 forms a certain angle b with the ground.

Among the correlation technique, steam generator all is vertical or the level setting in the fuselage, is in the horizontal operating condition that steam mop is in a steam direction and the horizontal plane is parallel promptly, and steam generator is 0 or 90 along the contained angle between the extension line of direction of height and the horizontal plane, will reach certain water storage capacity and just can reach the boiling surface and heat after the rivers free fall that pours into the shell into from the water inlet, and then has steam mop heating efficiency low, and the heating reaction speed is slow, the discontinuous and low temperature problem of steam.

In the steam mop provided in the embodiment of the present application, when the steam mop is in a horizontal working state in which the steam outlet direction is parallel to the horizontal plane, please refer to fig. 3, the steam generator 30 is in an inclined state, and an included angle a between an extension line of the steam generator 30 along the height direction and the horizontal plane satisfies: when the steam mop is in a working state, the water flow injected into the housing 31 from the water inlet 31a can fall onto the boiling surface 32a of the steam generator 30 under the action of self gravity, and therefore, when the steam mop is in a working state, no matter whether the steam generator 30 is in a declination working state or a horizontal working state, please refer to fig. 2 and 3, the water flow injected into the housing 31 from the water inlet 31a can fall onto the boiling surface 32a of the steam generator 30 under the action of self gravity, so that the water flow falling onto the boiling surface 32a can be heated and vaporized by the boiling surface 32a, and further the steam mop can rapidly generate continuous steam.

In one embodiment, the working states further include a lifting working state, referring to fig. 4, when the steam mop is in the lifting working state, the body 10 is in a tilted state and the mop 20 is located at the upper end of the body 10 along the tilted direction.

Specifically, when the steam mop is in the hand-held mode, the steam mop can be further in the upward working state, referring to fig. 4, when the steam mop is in the upward working state, the body 10 is in the inclined state and the mop 20 is located at the upper end of the body 10 in the inclined direction.

Referring to fig. 1 to 4, in the present embodiment, no matter the steam mop is in a downward tilting operation state, an upward lifting operation state, or a horizontal operation state, the water flow injected into the housing 31 from the water inlet 31a can fall onto the boiling surface 32a of the steam generator 30 under the action of its own gravity, that is, the steam mop provided by the embodiment of the present invention can improve the steam generation efficiency in two different operation states, i.e., a floor mopping mode and a hand-held mode, and can improve the vaporization effect of the steam.

In one embodiment, when the steam mop is in a horizontal working state, referring to fig. 3, the steam generator 30 is inclined downward from the end close to the mop 20 to the end far from the mop 20, and this arrangement is convenient for the water flow injected into the casing 31 from the water inlet 31a to fall onto the boiling surface 32a of the steam generator 30 under its own weight.

In one embodiment, referring to fig. 5 and 7, the heat generating core 32 has a secondary heating path 321, and an axis of the secondary heating path 321 extends along a height direction of the steam generator 30.

Specifically, referring to fig. 5 and 7, the heat generating core 32 has a secondary heating channel 321 penetrating through the heat generating core 32, a start end of the secondary heating channel 321 in the steam flowing direction is communicated with a tail end of the steam flow channel in the steam flowing direction, and a steam outlet is formed at the tail end of the secondary heating channel 321 in the steam flowing direction, that is, the steam in the steam flow channel can be sprayed out from the steam outlet after being secondarily heated in the heat generating core 32, so that on one hand, the steam dryness of the steam can be improved, and on the other hand, the steam outlet temperature of the steam can be maintained at a higher temperature.

In one embodiment, referring to fig. 3 and 9, the steam mop further comprises a steam outlet 33 disposed in the body 10, the steam outlet 33 has a steam outlet channel 33a, and when the steam mop is in a horizontal working state, an axis of the steam outlet channel 33a is parallel to a horizontal plane.

Specifically, referring to fig. 3, the steam outlet 33 is connected to the steam outlet of the steam generator 30 through a pipe, and when the steam mop is in a horizontal working state, the axis of the steam outlet channel 33a of the steam outlet 33 is parallel to the horizontal plane, that is, the steam is sprayed from the steam outlet 33 located in the middle of the mop 20.

In one embodiment, the included angle a is greater than 0 ° and equal to or less than 45 °, and since the axis of the steam outlet channel 33a of the steam outlet nozzle 33 is parallel to the horizontal plane and the steam outlet nozzle 33 is connected to the steam outlet of the steam generator 30 through a connecting pipe, the included angle a is greater than 0 ° and equal to or less than 45 °, and the connection between the steam outlet nozzle 33 and the steam outlet can be facilitated while allowing the water flow injected into the shell 31 from the water inlet 31a to fall onto the boiling surface 32a of the steam generator 30 by its own weight, preferably, the included angle a is 15 ° to 30 °.

In one embodiment, when the steam mop is in a horizontal working state, the inclined direction of the boiling surface 32a is consistent with the inclined direction of the steam generator 30, and the water inlet 31a is positioned at the upper side of the housing 31 in the inclined direction.

Specifically, when the steam mop is in a horizontal working state in which the steam outlet direction is parallel to the horizontal plane, the steam generator 30 is in an inclined state, the boiling surface 32a of the steam generator 30 is also inclined at a certain angle with the horizontal plane, and the water inlet 31a is located on the upper side of the shell 31 in the inclined direction, so that water flow injected into the shell 31 from the water inlet 31a can fall onto the boiling surface 32a under the action of self gravity, wherein the inclined direction of the boiling surface 32a is consistent with the inclined direction of the steam generator 30, and only the fact that the boiling surface 32a and the steam generator 30 are inclined to the same direction is explained, and the inclined angles of the two can be the same or different.

In one embodiment, the boiling surface 32a is located on the side of the heating core 32 close to the water inlet 31a, and when the steam mop is in the horizontal working state, the water inlet 31a is located on the upper side of the heating core. That is, the water injected into the casing 31 from the water inlet 31a enters the heat generating core 32 by its own weight, and then falls on the boiling surface 32a as soon as possible, thereby improving the heating efficiency of the steam mop.

In an embodiment, referring to fig. 6 to 8, a water inlet channel 32b and a water boiling groove 32c are formed on the heating core 32, the water boiling grooves 32c are respectively disposed at two opposite ends of the water inlet channel 32b along the extending direction, the water inlet 31a is communicated with the water inlet channel 32b, the water inlet channel 32b is communicated with the water boiling groove 32c, and the bottom surface of the water boiling groove 32c is a boiling surface 32a.

Referring to fig. 6 to 8, the steam generator 30 includes a steam outlet, a housing 31, and a heat generating component, wherein the housing 31 has a water inlet 31a; the heating component comprises a heating core 32 and a heating tube arranged in the heating core 32, partial areas of the heating core 32 are arranged in the shell 31, so that a water inlet channel 32b and a water boiling tank 32c which are positioned between the heating core 32 and the shell 31 are formed in the shell 31, the two water boiling tanks 32c are positioned on two opposite sides of the water inlet channel 32b along the extending direction, the water inlet 31a is communicated with the water inlet channel 32b, the steam outlet is respectively communicated with the two water boiling tanks 32c, the bottom surfaces of the water boiling tanks 32c are boiling surfaces 32a, namely, water flow injected into the shell 31 from the water inlet 31a enters the heating core 32 from the water inlet channel 32b and then enters the water boiling tanks 32c on two opposite sides of the water inlet channel 32b along the extending direction, and can fall on the boiling surfaces 32a as soon as possible, and the heating efficiency of the steam mop is improved.

Referring to fig. 8, the water inlet channel 32b is provided with water boiling grooves 32c at opposite ends along the extending direction, so that the water flow injected into the housing 31 from the water inlet 31a enters the water inlet channel 32b and then enters the water boiling grooves 32c, and the water flow can enter the water boiling grooves 32c after entering the water inlet channel 32b, and the two water boiling grooves 32c can heat the water flow at the same time, thereby improving the heating efficiency of the steam mop.

Specifically, referring to fig. 8, the steam generator 30 of the embodiment of the present application is provided with a water inlet passage 32b communicated with the water inlet 31a, and water flows from the water inlet 31a into the water inlet passage 32b and then flows from the water inlet passage 32b into the water boiling tank 32 c. That is, the steam mop can be operated in a tilted-down operation state, a raised-up operation state, or a horizontal operation state, the water injected into the steam generator 30 can flow into the corresponding water boiling grooves 32c along the corresponding bottom wall of the water inlet passage 32b, and thus the steam generator 30 can continuously generate steam, and thus, the steam mop can be normally operated at various angles.

In some embodiments, the heat-generating core 32 is formed with a water inlet channel 32b and a water boiling groove 32c, one end of the water inlet channel 32b along the extending direction is provided with the water boiling groove 32c, the water inlet 31a is communicated with the water inlet channel 32b, the water inlet channel 32b is communicated with the water boiling groove 32c, and the bottom surface of the water boiling groove 32c is a boiling surface 32a.

In one embodiment, referring to fig. 8, the heating core 32 further includes a plurality of water hanging members 32d, and the plurality of water hanging members 32d are disposed at intervals in the water boiling tank 32 c. The water hanging member 32d may be a water hanging column or a water hanging plate, and the water hanging member 32d may slow down the flow speed of the water flow in the corresponding water boiling tank 32c, so that the water flow can be sufficiently heated.

In an embodiment, referring to fig. 1 to 9, a steam flow channel is further formed between the heat generating core 32 and the housing 31, the steam mop further includes a water tank 40, an electromagnetic pump 50, a steam outlet 33 and a mop 20, the water tank 40 is communicated with the water inlet 31a through a pipeline, the electromagnetic pump 50 is disposed on the pipeline, the heat generating core 32 has a secondary heating channel 321 penetrating through the heat generating core 32, a beginning end of the secondary heating channel 321 along a steam flow direction is communicated with a tail end of the steam flow channel along the steam flow direction, a steam outlet is formed at the tail end of the secondary heating channel 321 along the steam flow direction, and the steam outlet 33 is connected with a steam outlet of the steam generator 30 through a connecting pipe.

In an embodiment, when the steam mop is in a horizontal working state, referring to fig. 8, the boiling surface 32a is set to be lower than the bottom surface of the water inlet channel 32b, that is, the water boiling grooves 32c can accommodate more water, that is, the water flows into the corresponding water boiling grooves 32c along the corresponding bottom walls of the water inlet channels 32b and can be stored in the corresponding water boiling grooves 32c, the heating pipes can heat the water in the water boiling grooves 32c at the same time, and thus the heating efficiency of the steam generator 30 can be improved.

In an embodiment, referring to fig. 1 to 4, when the steam mop is in an operating state, the projection range of the water inlet 31a on the horizontal plane along the vertical direction is located within the projection range of the boiling surface 32a, and such a setting position enables the water flow injected into the housing 31 from the water inlet 31a to fall onto the boiling surface 32a under the action of its own gravity no matter which operating state the steam mop is in, so that the water flow falling onto the boiling surface 32a is heated and vaporized by the boiling surface 32a, and further the steam mop can rapidly generate continuous steam.

The various embodiments/implementations provided herein may be combined with each other without contradiction.

The above description is only a preferred embodiment of the present application and is not intended to limit the present application, and various modifications and changes may be made to the present application by those skilled in the art. Any modification, equivalent replacement, improvement and the like made within the spirit and principle of the present application are included in the protection scope of the present application.

Claims (12)

1. A steam mop, comprising:

a body;

the mop is arranged at one end of the machine body;

set up steam generator in the fuselage, steam generator is in including the shell that has the water inlet and setting heating core in the shell, heating core has the boiling face, works as steam mop is in the horizontal operating condition that goes out vapour direction and horizontal plane parallel, steam generator is the tilt state, steam generator satisfies along contained angle a between the extension line of direction of height and the horizontal plane: when the steam mop is in the downward inclination working state, the machine body is in the inclination state and the mop is positioned at the lower end of the machine body along the inclination direction.

2. The steam mop of claim 1, wherein the working states further include a raised working state, and when the steam mop is in the raised working state, the body is in an inclined state and the mop is positioned at an upper end of the body in an inclined direction.

3. The steam mop of claim 1, wherein the steam generator is angled downwardly from an end proximate the mop toward an end distal from the mop when the steam mop is in the horizontal operating position.

4. The steam mop of claim 1, wherein the included angle a is greater than 0 ° and equal to or less than 45 °.

5. The steam mop of claim 4, wherein the included angle a is 15 ° -30 °.

6. The steam mop of claim 1, wherein the heat generating core has a secondary heating channel, an axis of which extends in a height direction of the steam generator.

7. The steam mop of claim 6, further comprising a steam outlet disposed in the body, the steam outlet having a steam outlet channel, an axis of the steam outlet channel being parallel to a horizontal plane when the steam mop is in the horizontal operating state.

8. The steam mop of claim 1, wherein the boiling surface is inclined in a direction corresponding to an inclination of the steam generator when the steam mop is in the horizontal operation state, and the water inlet is positioned at an upper side of the housing in the inclination direction.

9. The steam mop of claim 8, wherein the boiling surface is located on a side of the heat generating core adjacent to the water inlet, and the water inlet is located on an upper side of the heat generating core when the steam mop is in the horizontal operating state.

10. The steam mop as claimed in claim 9, wherein the heating core is formed with a water inlet channel and a water boiling tank, the water boiling tank is disposed at least one of opposite ends of the water inlet channel along an extending direction, the water inlet is communicated with the water inlet channel, the water inlet channel is communicated with the water boiling tank, and a bottom surface of the water boiling tank is the boiling surface.

11. The steam mop of claim 10, wherein the boiling surface is disposed at a lower elevation than a bottom surface of the water inlet channel when the steam mop is in the horizontal operating position.

12. The steam mop of claim 1, wherein in the working state, the projection range of the water inlet along the vertical direction on the horizontal plane is within the projection range of the boiling surface.

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