CN113154349A - Steam generating device and clothes treating device - Google Patents

Abstract

The invention provides a steam generating device and a clothes treating device. Wherein, steam generator includes: a body provided with a heating member; the isolator is at least partially accommodated in the machine body, the position height of the isolator is higher than that of the heating element, the isolator and the machine body enclose a first cavity and a second cavity, and the first cavity is communicated with the second cavity; wherein the heating member is configured to supply heat to at least the first chamber, the heating member including at least one heating portion. The isolator and the machine body enclose a first cavity and a second cavity, and the space in the first cavity is fixed, so that the quantity of the medium positioned in the first cavity is limited, and the quantity of the medium to be heated is less influenced by the quantity of the medium and the temperature of the medium in the second cavity, therefore, most of heat is absorbed by the medium in the first cavity of the isolator, the time from normal temperature to boiling of the medium and the generation of relatively stable steam is greatly shortened, the temperature rise of the medium in the second cavity is small, and the rapid generation of high-temperature steam can be realized.

Description

Steam generating device and clothes treating device

Technical Field

The invention relates to the technical field of steam generation, in particular to a steam generating device and a clothes processing device.

Background

The steam generating device of the clothes treating device has long steam generating time, cannot realize quick steam generation, and has poor user experience.

Disclosure of Invention

The present invention is directed to solving at least one of the problems of the prior art or the related art.

To this end, a first aspect of the invention proposes a steam generating device.

A second aspect of the present invention proposes a laundry treating apparatus.

In view of the above, a first aspect of the present invention provides a steam generating apparatus, comprising: a body provided with a heating member; the isolator is at least partially accommodated in the machine body, the position height of the isolator is higher than that of the heating element, the isolator and the machine body enclose a first cavity and a second cavity, and the first cavity is communicated with the second cavity; wherein the heating member is configured to supply heat to at least the first chamber, the heating member including at least one heating portion.

The invention provides a steam generating device which comprises a machine body and an isolator. Wherein, at least part isolator holding is in the organism, and the isolator separates the inner space of organism, promptly, first cavity and second cavity are enclosed out to isolator and organism to make the heating member be configured into at least to first cavity heat supply, when steam generator during operation, the medium in the first cavity is heated and is produced high temperature steam, in the medium volume in the first cavity reduces in the time the medium in the second cavity can be mended into in the first cavity, in order to guarantee that the volume of medium in the first cavity can satisfy the user demand who produces high temperature steam in succession.

Meanwhile, the isolator and the machine body enclose a first cavity and a second cavity, the space in the first cavity is fixed, so that the quantity of the medium positioned in the first cavity is limited, the quantity of the medium to be heated is less influenced by the medium quantity and the medium temperature of the second cavity, most of heat is absorbed by the medium in the first cavity of the isolator, and the medium in the second cavity can only absorb little heat due to the effect of the isolator, so that the time of the medium from normal temperature to boiling and generating relatively stable steam can be greatly shortened by heating the medium in the first cavity, the temperature rise of the medium in the second cavity is very small, the aim of quickly generating high-temperature steam can be achieved, and the energy loss is avoided.

Further, the organism is equipped with the heating member, and the position height of isolator is higher than the position height of heating member, and like this, but the heat that the heating member during operation produced acts on first cavity the very first time, that is to say, the assembly structure through injecing heating member and isolator has shortened thermal diffusion path for the heat that the heating member produced can transmit to first cavity fast in time, and then is favorable to shortening the time of producing relatively stable steam, is favorable to realizing the purpose of producing high temperature steam fast.

Further, the heating member includes at least one heating portion, can set up the quantity of heating portion according to concrete actual conditions pertinence for the heating member includes at least one heating portion, and the event, can make one heating portion work in at least one heating portion, or make the partial heating portion work in a plurality of heating portions, or make all heating portion work in a plurality of heating portions, in order to satisfy diversified user demand, realize different culinary art taste, be favorable to promoting the performance of product.

According to the steam generating device of the present invention, the following additional features may be provided:

in the above technical solution, further, the steam generating device further includes: and the limiting structure is positioned in the machine body, and the machine body and the isolator are detachably connected through the limiting structure.

In this technical scheme, through setting up limit structure for organism and isolator pass through the detachable connection of limit structure, like this, can dismantle the isolator by the organism when needs wash steam generation device, and then realize wasing alone isolator and organism, with effectively driving the incrustation scale in the steam generation device, be favorable to prolonging the life of product and reducing the energy consumption of product.

Further, through setting up limit structure, make isolator and organism accessible limit structure assemble together, namely, accessible limit structure limits the isolator for the activity of organism, make the internal surface of the organism of holding the isolator and the clearance variation between the isolator receive the restriction, and then the medium of having injecing the second cavity enters into the medium volume and the medium velocity of flow in the first cavity, so make the reduction of the temperature of medium in the first cavity have the controllability, make the production of steam can not receive great influence, so can guarantee to continuously produce high temperature steam and guarantee steam generating device's work efficiency.

In any of the above technical solutions, further, the limiting structure includes a magnetic part, and the machine body and the isolator are assembled through magnetic attraction of the magnetic part; and/or the limiting structure comprises a locking part, and the machine body and the isolator are locked and assembled through the locking part; and/or the limiting structure comprises a clamping part, and the machine body and the isolator are clamped and assembled through the clamping part.

In this technical scheme, limit structure includes magnetism portion of inhaling, or limit structure includes the sticking department, or limit structure includes joint portion, promptly, the isolator accessible magnetism portion of inhaling, one in sticking department and the joint portion is in the same place with organism detachably assembly to the purpose of the activity of injecing the isolator for the organism is realized. When the isolator needs to be disassembled, external force can be applied to the isolator to overcome the attraction force or the clamping force between the isolator and the machine body or unlock the locking part, so that the aim of separating the isolator from the machine body is fulfilled. The structure has the advantages of reliable assembly, convenient installation and subsequent disassembly and maintenance, and convenient debugging and calibration of the isolator relative to the machine body in the assembling process.

Furthermore, the isolator is matched and limited in a magnetic attraction or magnetic repulsion mode through the magnetic attraction part and is locked through the locking part; or the isolator is matched and limited in a magnetic attraction or magnetic repulsion mode through the magnetic attraction part and is clamped through the clamping part; or the isolator is locked by the locking part and is clamped by the clamping part; or the isolator is matched and limited in a magnetic attraction or magnetic repulsion mode through the magnetic attraction part, is locked through the locking part and is clamped through the clamping part. At least one of the magnetic attraction, the clamping and the locking has a pre-fixing effect, and other structures in the magnetic attraction, the clamping and the locking have further fixing effects, so that the assembling reliability of the isolator and the machine body can be enhanced, the assembling tightness and precision of the isolator and the machine body can be further calibrated, and the product can be assembled more conveniently.

In any of the above technical solutions, further, the magnetic part is included based on the limiting structure, the limiting structure is provided with an accommodating cavity, and the magnetic part is located in the accommodating cavity; based on the limit structure comprising a locking part, the locking part comprises a mounting hole and/or a mounting groove; based on limit structure includes joint portion, joint portion includes draw-in groove and buckle, and the organism is located to one in draw-in groove and the buckle, and the isolator is located to another.

In this technical scheme, limit structure is equipped with and holds the chamber, and magnetism portion of inhaling is located and holds the intracavity, holds the chamber and has the effect of protection and installation location to magnetism portion for magnetism portion of inhaling is isolated with liquid and air, can effectively avoid like this to inhale the portion and contact with liquid and air and lead to magnetism portion of inhaling to take place by the condition of oxidation because of magnetism, is favorable to prolonging the life of magnetism portion of inhaling.

Further, the locking part of the limiting structure comprises a mounting hole and/or a mounting groove, and the isolator is mounted and locked or unlocked through the mounting hole and/or the mounting groove.

Further, the clamping portion comprises a clamping groove and a buckle, one of the clamping groove and the buckle is arranged on the machine body, and the other one of the clamping groove and the buckle is arranged on the isolator to achieve assembling and disassembling of the isolator and the machine body.

In any of the above technical solutions, further, the isolator includes: the guide cylinder is provided with an exhaust port, and one end of the guide cylinder is provided with a port; the division plate is connected with the guide shell, extends from the edge of the port to the outer side of the guide shell and limits at least one part of the first cavity.

In the technical scheme, the isolator comprises a guide shell and an isolation plate. Wherein, the division board extends the setting to the outside of draft tube from the edge of port, and the division board prescribes a limit to at least partly of first cavity, and the division board can be pressed the medium that flows into in the first cavity into the dielectric layer to increase the area of contact of medium and heating member under the certain circumstances of guaranteeing the dielectric mass, and then be favorable to producing high temperature steam fast, avoided the loss of energy.

Further, the draft tube is provided with the exhaust port, so that the generated high-temperature steam can flow out through the draft tube and the exhaust port, namely, the draft tube limits the flow path of the generated high-temperature steam, and the steam has a gathering effect so that the steam can be concentrated in a preset area to avoid energy loss.

In any of the above technical solutions, further, in a direction from the partition plate to the exhaust port, the cross-sectional area of the guide cylinder includes any one of or a combination of the following: equal, gradually increasing, and gradually decreasing.

In the technical scheme, the structure of the guide shell can be set in a targeted manner according to specific practical conditions, so that the cross-sectional area of the guide shell comprises any one or a combination of the following parts in the direction from the partition plate to the exhaust port: equal, gradually increased and gradually decreased to meet diversified use requirements.

In any of the above technical solutions, further, the guide shell and the isolation plate are of an integrated structure.

In the technical scheme, the guide shell and the isolation plate are of an integrated structure, and the structure saves the assembly process of the guide shell and the isolation plate, so that the investment of fastening the guide shell and the isolation plate is reduced, the assembly and subsequent disassembly processes of the isolator are simplified, the assembly and disassembly efficiency is improved, and the production and maintenance cost can be reduced. In addition, the integral connection of the guide shell and the isolation plate can ensure the requirement of the size precision of the isolator molding, and further can ensure the controllability of the overall dimension of the isolator and the matching dimension between the guide shell and the isolation plate.

In any of the above technical solutions, further, the isolator further includes: the isolating part is at least partially positioned in the guide shell and connected with the guide shell, a gap is formed between the isolating part and the guide shell, and the gap is communicated with the exhaust port; wherein the bottom wall of the partition defines at least a portion of the first chamber.

In the technical scheme, the isolator also comprises an isolating part, a gap is arranged between the isolating part and the guide cylinder, and the gap is communicated with the exhaust port, so that steam generated after the medium is boiled can flow to the exhaust port through the gap and then flows out of the isolator. The structure setting of this gap is guaranteeing that the medium liquid level of first cavity and second cavity is the same under the condition for the space that is used for the holding medium in the isolator is dwindled, like this, makes the inside medium volume of isolator reduced, thereby shortens the medium in the first cavity by a wide margin from the normal atmospheric temperature to the time of boiling and production relatively stable steam. And the structure arrangement ensures that when the medium liquid level in the second chamber is higher, the influence on the temperature of the medium in the first chamber is smaller, so that the time from normal temperature to boiling of the medium and the generation of relatively stable steam can not be obviously prolonged.

In addition, the diapire of isolation part defines at least partly of first cavity, and promptly, the diapire of isolation part can be pressed the medium that flows into in the first cavity into the dielectric layer, and then increases the area of contact of medium and heating member under the certain circumstances of assurance medium volume, and then is favorable to producing high temperature steam fast, has avoided the loss of energy.

In any of the above technical solutions, further, the slit is located on a peripheral side of the partition portion; or one part of the slits is positioned on the peripheral side of the partition, and the other part of the slits is positioned on the top of the partition.

In the technical scheme, the gap is positioned on the peripheral side of the isolation part, and the space on the peripheral side of the isolation part can be communicated with the exhaust port; one part of the slits is located on the peripheral side of the partition portion, and the other part of the slits is located on the top portion of the partition portion, so that the spaces on the peripheral side and the top portion of the partition portion can communicate with the exhaust port.

In any of the above technical solutions, further, the bottom wall of the partition is located between the partition plate and the heating member.

In this technical scheme, the diapire of separator is located between division board and heating member, and like this, partial medium that flows into in the first chamber is suppressed between the diapire of separator and heating member, namely, defines first chamber between the diapire of separator, division board and the partial bottom wall of organism.

In any of the above technical solutions, further, the isolation portion has an opening, and the exhaust port surrounds the opening, or the exhaust port is located at one side of the opening.

In this technical scheme, the isolation portion has the opening to make the gas vent encircle the opening, or the gas vent is located open-ended one side, and the opening has the exhaust effect, with the inside and outside atmospheric pressure of balanced isolation portion.

In any one of the above technical solutions, further, the isolation portion includes: a partition, a bottom wall of the partition defining at least a portion of the first chamber; a connector connected with the spacer, the connector configured to connect the spacer and the draft tube.

In this solution, the spacer includes a spacer and a connecting member. Wherein, the connecting piece is configured to connect isolator and draft tube, i.e. isolator and draft tube pass through the connecting piece and assemble together, and then can guarantee the assembly size of isolator and draft tube, and then can guarantee the size of the gap that forms between isolator and the partial internal surface of draft tube. In addition, at least one part of the first cavity is limited by the bottom wall of the isolating piece, the bottom wall of the isolating piece presses the medium flowing into the first cavity into a medium layer, the contact area of the medium and the heating element is increased under the condition that the medium quality is ensured to be certain, high-temperature steam is favorably and quickly generated, and energy loss is avoided.

In any one of the above technical scheme, further, the draft tube is formed with the installed part, and the installed part is located between the diapire of gas vent and isolation portion, and the connecting piece is connected with the installed part looks joint.

In this technical scheme, the draft tube is formed with the installed part, and connecting piece and installed part looks joint, and then realize the firm and firm assembly of draft tube and separator, and simultaneously, this structural setting can guarantee the assembled position of isolation for the draft tube, and then can guarantee the size of the dielectric film of follow-up formation.

In any of the above technical solutions, further, the isolation portion is provided with at least one first air guide groove, and the first air guide groove is recessed from the outside of the isolation portion to the inside of the isolation portion.

In this technical scheme, the isolation part is equipped with at least one first air guide groove, and first air guide groove is sunken to the inside of isolation part from the outside of isolation part, and the flow path of steam is injectd to first air guide groove, can guarantee that the steam that produces flows into the gap between isolation part and the draft tube fast and steadily, and then flows out the isolator through the gas vent.

In any of the above technical solutions, further, at least one of the partition plate and the draft tube is provided with at least one second air guide groove, and the second air guide groove is recessed from the inside of the isolator to the outside of the isolator.

In this technical scheme, through setting up the second air guide groove for the second air guide groove is sunken to the isolator outside from the isolator is inside, and the second air guide groove prescribes a limit to the flow path of steam, can guarantee that the steam that produces flows into the gap between isolation portion and the division board fast and steadily, and then flows out the isolator through the gas vent.

In any of the above technical solutions, further, the body includes: the heating element is arranged on the first shell; the second shell is detachably connected with the first shell, at least part of the guide shell extends out of the second shell, and the exhaust port is located on the outer side of the second shell.

In this technical scheme, the organism includes first casing and second casing, and wherein, the heating member is located first casing, and the second casing is connected with first casing is detachable, like this, can take off the second casing by first casing when needs wash steam generator, then take out the isolator in by first casing to realize the separation of isolator and organism, and then can realize the purpose of independent cleaning organism and isolator.

In addition, at least part of the guide cylinder extends out of the second shell, and the exhaust port is positioned outside the second shell, so that the second shell has the function of fixing the isolator, namely, the position of the isolator relative to the first shell and the heating element is limited by the assembling structure of the first shell and the second shell, and thus, the change quantity of the gap between the inner surface of the machine body accommodating the isolator and the isolator can be limited.

In any of the above technical solutions, further, the steam generating device further includes: and a medium passage provided in at least one of the body and the separator, the medium passage being configured to communicate the first chamber and the second chamber.

In the technical scheme, the first cavity and the second cavity are communicated through the medium channel, the medium flow rate of the medium flowing into the first cavity from the second cavity is limited by the structure of the medium channel, and therefore the temperature of the medium in the first cavity is reduced in a controllable manner, the steam is not greatly affected, the generated steam is discharged out of the isolator through the exhaust port, and therefore the continuous generation of high-temperature steam and the work efficiency of the cooking pot can be guaranteed.

In any of the above technical solutions, further, the bottom of the separator or the inner surface of the machine body is provided with support ribs, and the support ribs form at least part of the medium channel.

In this technical solution, the bottom of the isolator or the inner surface of the machine body is provided with a support rib, that is, the bottom of the isolator is provided with a support rib, or the inner surface of the machine body is provided with a support rib, one part of the support rib is provided on the inner surface of the machine body, and the other part of the support rib is provided on the bottom of the isolator. The structure makes the isolator separated from the inner surface of the machine body through the support rib, so that the medium can flow into the first cavity through the gap between the machine body and the isolator.

In any of the above technical solutions, further, the support rib is formed with a communication notch and/or a communication hole.

In the technical scheme, the support ribs are provided with the communication notches and/or the communication holes, so that the medium can enter the medium channel through the communication notches and/or the communication holes and then flows into the first cavity, necessary space support is provided for stable and smooth flowing of the medium, and the situation that the heating element is dried due to the fact that the medium outside the isolator cannot effectively flow into the first cavity is avoided.

In any of the above technical solutions, further, the second chamber is located on a peripheral side of the first chamber.

In this technical scheme, the second cavity is located the week side of first cavity, can play thermal-insulated effect, avoids the inside heat loss of first cavity on the one hand, and on the other hand avoids scalding the user, guarantees user safety in utilization.

A second aspect of the present invention provides a laundry treating apparatus comprising: the steam generating device according to any one of the first aspect; and the control device is electrically connected with the heating element of the steam generating device.

The laundry treatment apparatus provided by the present invention includes the steam generating device according to any of the first aspect, and therefore, all the advantages of the steam generating device are provided, which is not described herein.

Specifically, the control device is electrically connected with the heating element of the steam generating device and can control the heating element to work so that the first chamber is heated and steam is generated.

Additional aspects and advantages of the invention will be set forth in part in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention.

Drawings

The above and/or additional aspects and advantages of the present invention will become apparent and readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings of which:

FIG. 1 illustrates a schematic structural view from a first perspective of a steam generator of one embodiment of the present invention;

FIG. 2 is a schematic diagram illustrating a second perspective of a steam generator according to an embodiment of the present invention;

FIG. 3 shows a cross-sectional view taken along line A-A of the first embodiment shown in FIG. 2;

FIG. 4 is an enlarged view of a portion of the embodiment of FIG. 3 at B;

FIG. 5 is an enlarged view of a portion of the embodiment of FIG. 3 at C;

FIG. 6 shows a cross-sectional view taken along line A-A of the second embodiment shown in FIG. 2;

FIG. 7 is a schematic view showing the construction of a separator according to a first embodiment of the present invention;

FIG. 8 is a partial schematic structural view showing a separator according to a first embodiment of the present invention;

FIG. 9 is a schematic view of a spacer according to a second embodiment of the present invention from a first perspective;

fig. 10 shows a schematic view of a second view of the isolator according to the second embodiment of the present invention.

Wherein, the correspondence between the reference numbers and the part names in fig. 1 to 10 is:

100 steam generating device, 110 machine body, 120 heating element, 130 isolator, 140 first chamber, 150 second chamber, 160 buckle, 170 clamping groove, 180 draft tube, 190 exhaust port, 200 isolation plate, 210 isolation part, 220 gap, 230 opening, 240 isolation part, 250 connecting piece, 260 installation part, 270 first air guide groove, 280 second air guide groove, 290 first shell, 300 second shell, 310 medium channel, 320 waterline.

Detailed Description

In order that the above objects, features and advantages of the present invention can be more clearly understood, a more particular description of the invention will be rendered by reference to the appended drawings. It should be noted that the embodiments and features of the embodiments of the present application may be combined with each other without conflict.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention, however, the present invention may be practiced in other ways than those specifically described herein, and therefore the scope of the present invention is not limited by the specific embodiments disclosed below.

The steam generating device 100 and the laundry treating device according to some embodiments of the present invention are described below with reference to fig. 1 to 10.

Example 1:

as shown in fig. 1 to 6, an embodiment of the first aspect of the present invention proposes a steam generating device 100 including a body 110 and a separator 130. The machine body 110 is provided with a heating element 120, at least a part of the isolator 130 is accommodated in the machine body 110, the position height of the isolator 130 is higher than that of the heating element 120, the isolator 130 and the machine body 110 enclose a first cavity 140 and a second cavity 150, the first cavity 140 is communicated with the second cavity 150, the heating element 120 is configured to supply heat to at least the first cavity 140, and the heating element 120 at least comprises a heating part.

In detail, the steam generating device 100 includes a body 110 and a separator 130. At least a portion of the isolator 130 is accommodated in the machine body 110, the isolator 130 separates an inner space of the machine body 110, that is, the isolator 130 and the machine body 110 enclose a first chamber 140 and a second chamber 150, and the heating element 120 is configured to supply heat to at least the first chamber 140, when the steam generating device 100 operates, a medium in the first chamber 140 is heated to generate high-temperature steam, and the medium in the second chamber 150 is supplemented into the first chamber 140 while the medium amount in the first chamber 140 is reduced, so as to ensure that the medium amount in the first chamber 140 can meet the use requirement of continuously generating the high-temperature steam.

Meanwhile, the isolator 130 and the machine body 110 enclose a first chamber 140 and a second chamber 150, because the space in the first chamber 140 is fixed, the amount of the medium in the first chamber is limited, and the amount of the medium to be heated is less influenced by the medium amount and the medium temperature of the second chamber 150, so that most of the heat is absorbed by the medium in the first chamber 140 of the isolator 130, and the medium in the second chamber 150 can only absorb little heat due to the action of the isolator 130, so that the time from normal temperature to boiling of the medium and the generation of relatively stable steam can be greatly shortened by heating the medium in the first chamber 140, and the temperature rise of the medium in the second chamber 150 is small, so that the purpose of quickly generating high-temperature steam can be realized, and the energy loss is avoided.

Further, the machine body 110 is provided with the heating member 120, and the position height of the isolator 130 is higher than that of the heating member 120, so that heat generated by the heating member 120 during operation can act on the first chamber 140 at the first time, that is, the heat diffusion path is shortened by limiting the assembly structure of the heating member 120 and the isolator 130, so that the heat generated by the heating member 120 can be transferred to the first chamber 140 at the first time and in time, thereby being beneficial to shortening the time for generating relatively stable steam and being beneficial to achieving the purpose of rapidly generating high-temperature steam. Specifically, the isolator 130 is positioned above the heating member 120, or the isolator 130 is positioned above the side of the heating member 120, etc., not to mention here.

Specifically, the heating element 120 is configured to supply heat to the first chamber 140; the heating member 120 is configured to supply heat to the first chamber 140 and a portion of the second chamber 150; the heating member 120 is configured to supply heat to the first and second chambers 140 and 150. When the heating member 120 is configured to supply heat to the first chamber 140 and the second chamber 150, or the heating member 120 is configured to supply heat to the first chamber 140 and a part of the second chamber 150, the medium in the second chamber 150 is heated, so that preheating of the medium flowing into the first chamber is achieved, which is beneficial to shortening the time for generating relatively stable steam and achieving the purpose of rapidly generating high-temperature steam.

Specifically, the heating member 120 supplies heat to the first chamber 140 at the same power as the heating member 120 supplies heat to the second chamber 150, or the heating member 120 supplies heat to the first chamber 140 at a different power than the heating member 120 supplies heat to the second chamber 150.

Further, the heating member 120 includes at least one heating portion, and the number of the heating portions can be set up in a targeted manner according to specific practical situations, so that the heating member 120 includes at least one heating portion, and therefore, one heating portion of the at least one heating portion can be operated, or part of the plurality of heating portions can be operated, or all the heating portions in the plurality of heating portions can be operated, so that diversified use requirements can be met, different cooking tastes can be realized, and the use performance of products can be improved. Wherein, the heating power of one part of the heating parts can be the same, and the heating power of the other part of the heating parts is different; the heating powers of the plurality of heating portions can be made the same.

Specifically, the medium includes a liquid, or the medium includes a liquid and a gas.

Specifically, as shown in fig. 3 and 6, the spacer 130 being positioned above the heating member 120 means that the spacer 130 is positioned above the top of the heating member 120.

Example 2:

as shown in fig. 1 and 2, according to an embodiment of the invention, comprising the features defined in any of the above embodiments, and further: the steam generating apparatus 100 further includes: the limiting structure is located in the body 110, and the body 110 and the isolator 130 are detachably connected through the limiting structure.

Specifically, through setting up limit structure for organism 110 and isolator 130 pass through the detachable connection of limit structure, like this, can dismantle isolator 130 by organism 110 in when needs wash steam generation device 100, and then realize wasing isolator 130 and organism 110 alone, with effectively driving the incrustation scale in steam generation device 100, be favorable to prolonging the life of product and reducing the energy consumption of product.

Further, by providing the limiting structure, the isolator 130 and the machine body 110 can be assembled together through the limiting structure, that is, the movement of the isolator 130 relative to the machine body 110 can be limited by the limiting structure, so that the variation of the gap between the inner surface of the machine body 110 accommodating the isolator 130 and the isolator 130 is limited, and the amount and the flow rate of the medium entering the first chamber 140 from the medium of the second chamber 150 are further limited, so that the reduction of the temperature of the medium in the first chamber 140 is controllable, the generation of the steam is not greatly influenced, and the continuous generation of the high-temperature steam and the work efficiency of the steam generating device 100 can be ensured.

Specifically, the limiting structure includes a magnetic part, and the machine body 110 and the isolator 130 are assembled by the magnetic part; and/or the limit structure comprises a locking part, and the machine body 110 and the isolator 130 are locked and assembled through the locking part; and/or the limiting structure comprises a clamping part, and the machine body 110 and the isolator 130 are clamped and assembled through the clamping part.

Wherein, limit structure includes magnetism portion of inhaling, or limit structure includes the sticking portion, or limit structure includes the joint portion, promptly, isolator 130 accessible magnetism portion, one in sticking portion and the joint portion is in the same place with organism 110 detachably assembly to the purpose of the activity of injecing isolator 130 for organism 110 is realized. When the separator 130 needs to be detached, an external force is applied to the separator 130 to overcome an attractive force or a locking force between the separator 130 and the body 110, or to unlock the locking portion, thereby achieving the purpose of separating the separator 130 from the body 110. The structural arrangement has assembly reliability, facilitates installation and subsequent disassembly and maintenance, and also facilitates debugging and calibration of the isolator 130 relative to the body 110 during assembly.

Further, the isolator 130 is matched and limited by the magnetic attraction part in a magnetic attraction or magnetic repulsion mode, and is locked by the locking part; or the isolator 130 is matched and limited in a magnetic attraction or magnetic repulsion mode through the magnetic attraction part and is clamped through the clamping part; or the isolator 130 is locked by the locking part and clamped by the clamping part; or the isolator 130 is matched and limited by the magnetic attraction part in a magnetic attraction or magnetic repulsion mode, is locked by the locking part and is clamped by the clamping part. At least one of the magnetic attraction, the clamping and the locking has a pre-fixing function, and the other structures in the magnetic attraction, the clamping and the locking have further fixing functions, so that the assembling reliability of the isolator 130 and the machine body 110 can be enhanced, the assembling tightness and precision of the isolator 130 and the machine body 110 can be further calibrated, and the product assembly is more convenient.

Specifically, including magnetism portion of inhaling based on limit structure, limit structure is equipped with and holds the chamber, and magnetism portion of inhaling is located and holds the intracavity. Limiting structure is equipped with and holds the chamber, and magnetism portion of inhaling is located and holds the intracavity, holds the chamber and has the effect of protection and installation location to magnetism portion for magnetism portion of inhaling is isolated with liquid and air, can effectively avoid like this to contact and leads to magnetism portion of inhaling to take place by the condition of oxidation because of magnetism portion of inhaling and liquid and air, is favorable to prolonging the life of magnetism portion of inhaling. Wherein, the separator 130 is provided with a containing cavity, and part of the machine body 110 is configured as a metal wall matched with the magnetic part; or the body 110 is provided with a receiving cavity, and a portion of the separator 130 is configured as a metal wall cooperating with the magnetic attraction.

Specifically, the spacer 130 is installed and locked or unlocked through the mounting hole and/or the mounting groove based on the limit structure including the locking portion including the mounting hole and/or the mounting groove.

Specifically, the locking part is disposed on the isolator 130, the inner wall of the mounting hole and/or the inner wall of the mounting groove are formed with threads, the machine body 110 is provided with a positioning member engaged with the mounting hole and/or the mounting groove, and the positioning member is provided with threads, so that the machine body 110 can be screwed with the isolator 130.

Specifically, the locking portion is disposed on the isolator 130, the machine body 110 is provided with a positioning member that is matched with the mounting hole and/or the mounting groove, and the mounting hole and/or the mounting groove and the positioning member are connected together via a fastening member, so as to lock or unlock the installation of the isolator 130 and the machine body 110. Wherein, the fastener includes any one of following: screws, bolts and rivets.

Specifically, based on limit structure includes joint portion, joint portion includes draw-in groove 170 and buckle 160, and organism 110 is located to one in draw-in groove 170 and buckle 160, and isolator 130 is located to another to realize isolator 130 and organism 110's assembly and dismantlement.

Specifically, as shown in fig. 2, 3, 4, 7 and 8, the isolator 130 is provided with a slot 170, and the body 110 is provided with a buckle 160. As shown in fig. 2, 3 and 5, the isolator 130 is provided with a buckle 160, and the body 110 is provided with a slot 170. As shown in fig. 2, 6, 9 and 10, the isolator 130 has a slot 170, and the body 110 has a clip 160.

Specifically, steam generator 100 includes a plurality of limit structure, and a plurality of limit structure interval arrangements, a plurality of limit structure cooperate with the activity of common restriction isolator 130 for organism 110, like this, have increased isolator 130 and organism 110's assembly area and assembly angle, and then are favorable to promoting the steadiness and the reliability of assembly. In addition, a plurality of limit structure interval arrangements, like this, be favorable to guaranteeing the equilibrium and the uniformity of the activity of isolator 130 each position, so can guarantee the uniformity and the homogeneity of the clearance between isolator 130 and the internal surface of organism 110, avoid isolator 130 to take place the condition of slope, and then can effectively avoid leading to the condition of dry combustion method to take place because of the local clearance undersize between isolator 130 and the internal surface of organism 110, be favorable to promoting the security and the reliability that the product used.

Specifically, the separator 130 includes any one or a combination of the following: metal isolators 130, plastic isolators 130, glass isolators 130, ceramic isolators 130, and wooden isolators 130.

Example 3:

as shown in fig. 6, 9 and 10, according to an embodiment of the present invention, including the features defined in any of the above embodiments, and further: the separator 130 includes: the guide cylinder 180 is provided with an exhaust port 190, and one end of the guide cylinder 180 is provided with a port; and a partition plate 200 connected to the guide cylinder 180, the partition plate 200 extending from an edge of the port to an outer side of the guide cylinder 180, the partition plate 200 defining at least a portion of the first chamber 140.

In detail, the separator 130 includes a guide cylinder 180 and a separator plate 200. The isolation plate 200 extends from the edge of the port to the outer side of the guide cylinder 180, at least one part of the first cavity 140 is defined by the isolation plate 200, the isolation plate 200 can press a medium flowing into the first cavity 140 into a medium layer, so that the contact area between the medium and the heating element 120 is increased under the condition that the medium quality is ensured to be certain, high-temperature steam can be generated quickly, and energy loss is avoided.

Further, the guide shell 180 is provided with the exhaust port 190, so that the generated high-temperature steam can flow out through the guide shell 180 and the exhaust port 190, that is, the guide shell 180 defines a flow path of the generated high-temperature steam, and has a convergence effect on the steam, so that the steam can be concentrated in a preset area to avoid energy loss.

Specifically, the cross-sectional area of the guide cylinder 180 in the direction from the partition plate 200 to the exhaust port 190 includes any one or a combination of the following: equal, gradually increasing, and gradually decreasing. The configuration of the guide shell 180 may be specifically configured according to actual conditions, such that the cross-sectional area of the guide shell 180 in the direction from the partition plate 200 to the exhaust port 190 includes any one or a combination of the following: equal, gradually increased and gradually decreased to meet diversified use requirements.

Specifically, as shown in fig. 9 and 10, the guide cylinder 180 is of an integrated structure with the partition plate 200. The guide shell 180 and the isolation plate 200 are of an integrated structure, and the structure reduces the investment of materials for fastening the guide shell 180 and the isolation plate 200 due to the fact that the assembly process of the guide shell 180 and the isolation plate 200 is omitted, so that the assembly and subsequent disassembly processes of the isolator 130 are simplified, the assembly and disassembly efficiency is improved, and the production and maintenance cost can be reduced. In addition, the integral connection of the guide shell 180 and the isolation plate 200 can ensure the dimensional accuracy requirement of the isolator 130 molding, and further ensure the external dimension of the isolator 130 and the controllability of the matching dimension between the guide shell 180 and the isolation plate 200.

Specifically, as shown in fig. 6, 9 and 10, the partition plate 200 defines a portion of the first chamber 140, and a portion of the inner bottom wall of the body 110 defines another portion of the first chamber 140; the outer surface of the guide cylinder 180 and the outer surface of the partition plate 200 define a portion of the second chamber 150, and the remaining inner surface of the body 110 defines another portion of the second chamber 150. It is also possible that the partition plate 200 defines one portion of the first chamber 140, and the heating member 120 and a part of the inner bottom wall of the body 110 define another portion of the first chamber 140. It is also possible for the partition plate 200 to define one part of the first chamber 140 and the heating member 120 to define another part of the first chamber 140.

Example 4:

as shown in fig. 3, 7 and 8, according to an embodiment of the present invention, including the features defined in any of the above embodiments, and further: the separator 130 includes: the guide cylinder 180 is provided with an exhaust port 190, and one end of the guide cylinder 180 is provided with a port; and a partition plate 200 connected to the guide cylinder 180, the partition plate 200 extending from an edge of the port to an outer side of the guide cylinder 180, the partition plate 200 defining at least a portion of the first chamber 140.

In detail, the separator 130 includes a guide cylinder 180 and a separator plate 200. The isolation plate 200 extends from the edge of the port to the outer side of the guide cylinder 180, at least one part of the first cavity 140 is defined by the isolation plate 200, the isolation plate 200 can press a medium flowing into the first cavity 140 into a medium layer, so that the contact area between the medium and the heating element 120 is increased under the condition that the medium quality is ensured to be certain, high-temperature steam can be generated quickly, and energy loss is avoided.

Further, the guide shell 180 is provided with the exhaust port 190, so that the generated high-temperature steam can flow out through the guide shell 180 and the exhaust port 190, that is, the guide shell 180 defines a flow path of the generated high-temperature steam, and has a convergence effect on the steam, so that the steam can be concentrated in a preset area to avoid energy loss.

Specifically, the cross-sectional area of the guide cylinder 180 in the direction from the partition plate 200 to the exhaust port 190 includes any one or a combination of the following: equal, gradually increasing, and gradually decreasing. The configuration of the guide shell 180 may be specifically configured according to actual conditions, such that the cross-sectional area of the guide shell 180 in the direction from the partition plate 200 to the exhaust port 190 includes any one or a combination of the following: equal, gradually increased and gradually decreased to meet diversified use requirements.

Specifically, as shown in fig. 7 and 8, the guide cylinder 180 is of an integrated structure with the partition plate 200. The guide shell 180 and the isolation plate 200 are of an integrated structure, and the structure reduces the investment of materials for fastening the guide shell 180 and the isolation plate 200 due to the fact that the assembly process of the guide shell 180 and the isolation plate 200 is omitted, so that the assembly and subsequent disassembly processes of the isolator 130 are simplified, the assembly and disassembly efficiency is improved, and the production and maintenance cost can be reduced. In addition, the integral connection of the guide shell 180 and the isolation plate 200 can ensure the dimensional accuracy requirement of the isolator 130 molding, and further ensure the external dimension of the isolator 130 and the controllability of the matching dimension between the guide shell 180 and the isolation plate 200.

Specifically, as shown in fig. 3, 7 and 8, the isolator 130 further includes: the isolating part 210, at least part of the isolating part 210 is located in the guide shell 180, the isolating part 210 is connected with the guide shell 180, a gap 220 is arranged between the isolating part 210 and the guide shell 180, and the gap 220 is communicated with the exhaust port 190; wherein the bottom wall of the partition 210 defines at least a portion of the first chamber 140.

In detail, the isolator 130 further includes an isolating portion 210, a gap 220 is formed between the isolating portion 210 and the guide cylinder 180, and the gap 220 is communicated with the exhaust port 190, so that the steam generated after the medium is boiled can also flow to the exhaust port 190 through the gap 220 and then flow out of the isolator 130. The gap 220 is configured to ensure that the medium levels in the first chamber 140 and the second chamber 150 are the same, so that the space for accommodating the medium in the separator 130 is reduced, and thus, the amount of the medium in the separator 130 is reduced, thereby greatly shortening the time from normal temperature to boiling of the medium in the first chamber 140 and generating relatively stable steam. And the structural arrangement makes the temperature influence on the medium in the first chamber 140 smaller when the medium level in the second chamber 150 is higher, so that the time for the medium to boil from normal temperature and generate relatively stable steam is not obviously prolonged.

In addition, the bottom wall of the isolation portion 210 defines at least a part of the first chamber 140, that is, the bottom wall of the isolation portion 210 can press the medium flowing into the first chamber 140 into a medium layer, so as to increase the contact area between the medium and the heating element 120 under the condition of ensuring a certain amount of the medium, thereby facilitating the rapid generation of high-temperature steam and avoiding the loss of energy.

Specifically, the bottom wall of the partition 210 is located between the partition plate 200 and the heating member 120. The bottom wall of the partition 210 is positioned between the partition plate 200 and the heating members 120, so that a part of the medium flowing into the first chamber 140 is pressed between the bottom wall of the partition 210 and the heating members 120, i.e., the first chamber 140 is defined between the bottom wall of the partition 210, the partition plate 200, and a part of the bottom wall of the body 110.

Specifically, as shown in fig. 3, 7 and 8, the partition plate 200 and the bottom wall of the partition 210 define a portion of the first chamber 140, and a portion of the bottom wall of the body 110 defines another portion of the first chamber 140; the outer surface of the guide cylinder 180 and the outer surface of the partition plate 200 define a portion of the second chamber 150, and the remaining inner surface of the body 110 defines another portion of the second chamber 150. It is also possible that the partition plate 200 defines one portion of the first chamber 140, and the heating member 120 and a part of the inner bottom wall of the body 110 define another portion of the first chamber 140. It is also possible for the partition plate 200 to define one part of the first chamber 140 and the heating member 120 to define another part of the first chamber 140.

Specifically, the slit 220 is located on the peripheral side of the partition 210; or a part of slits 220 is located on the peripheral side of separator 210 and another part of slits 220 is located on the top of separator 210. The slit 220 is located on the peripheral side of the isolation portion 210, and the space on the peripheral side of the isolation portion 210 can communicate with the exhaust port 190; a part of the slits 220 is located on the circumferential side of the partition 210, and another part of the slits 220 is located on the top of the partition 210, so that the space on the circumferential side and the top of the partition 210 can communicate with the exhaust port 190.

Specifically, at least part of the partition plate 200 is configured as a flat plate; and/or at least a portion of the separator plate 200 is configured as a curved plate.

Wherein, part of the isolation plate 200 is configured as a flat plate, and the flat plate can press the medium flowing into the first chamber 140 into a medium layer, so as to increase the contact area between the medium and the heating element 120 under the condition of ensuring a certain medium amount, thereby facilitating the rapid generation of high-temperature steam and avoiding the loss of energy. Meanwhile, the flat plate can ensure the uniformity and consistency of the distribution thickness of the medium, avoid the occurrence of dry burning caused by the small thickness of the medium layer at the part of the isolation plate 200, and ensure the use safety and reliability of the product.

Wherein, some division boards 200 are constructed as curved plates, and the structural arrangement of the curved plates can ensure the effective contact area between the isolator 130 and the heating element 120 and at the same time increase the dielectric mass in the first chamber 140 adaptively, which is beneficial to ensuring the continuity and stability of gas generation and avoiding the occurrence of gas cut-off. Simultaneously, this structure setting has the guide effect to the high temperature steam that produces to reduce the convection action of steam, make steam can remove to gas vent 190 department fast, reduce the loss of energy.

Specifically, the curved plate tends to be inclined upward from the edge of the partition plate 200 toward the guide cylinder 180. From the edge of division board 200 to draft tube 180 direction, the curved plate is the trend of tilt up, and the setting can be when guaranteeing isolator 130 and heating member 120 effective area of contact the medium volume in the first cavity 140 of increase of adaptability, is favorable to guaranteeing the continuity and the stability of gaseous production like this, avoids the condition emergence of gas failure. Simultaneously, this structure setting has the guide effect to the high temperature steam that produces to reduce the convection action of steam, make steam can remove to gas vent 190 department fast, reduce the loss of energy.

Specifically, the partition 210 has an opening 230, the exhaust port 190 surrounds the opening 230, or the exhaust port 190 is located at one side of the opening 230. The opening 230 has a venting function to equalize the air pressure inside and outside the partition 210.

Specifically, as shown in fig. 7 and 8, the spacer 210 includes: a partition 240, a bottom wall of the partition 240 defining at least a portion of the first chamber 140; and a connection member 250 connected to the partition 240, the connection member 250 being configured to connect the partition 240 and the guide cylinder 180. The spacer 210 includes a spacer 240 and a connection member 250. Wherein, the connector 250 is configured to connect the spacer 240 and the guide cylinder 180, that is, the spacer 240 and the guide cylinder 180 are assembled together by the connector 250, so that the assembly size of the spacer 240 and the guide cylinder 180 can be ensured, and the size of the gap 220 formed between the spacer 240 and a part of the inner surface of the guide cylinder 180 can be ensured. In addition, the bottom wall of the partition 240 defines at least a part of the first chamber 140, and the bottom wall of the partition 240 presses the medium flowing into the first chamber 140 into a medium layer, so that the contact area between the medium and the heating element 120 is increased under the condition of ensuring a certain medium amount, thereby facilitating the rapid generation of high-temperature steam and avoiding the loss of energy.

Specifically, the connector 250 is connected to the top wall and/or the side wall of the guide shell 180. The assembly relationship of the connection member 250 and the guide shell 180 is set according to practical conditions, for example, the connection member 250 is connected with the top wall of the guide shell 180, for example, the connection member 250 is connected with the side wall of the guide shell 180, for example, the connection member 250 is connected with the top wall and the side wall of the guide shell 180. When the connecting member 250 is connected to the top wall of the guide shell 180, the slit 220 is located on the periphery of the partition 240, when the connecting member 250 is connected to the side wall of the guide shell 180, the slit 220 may be located on the periphery of the partition 240 or on the periphery and top of the partition 240, and when the connecting member 250 is connected to the top and side wall of the guide shell 180, the slit 220 is located on the periphery of the partition 240.

Specifically, the connection member 250 and the guide cylinder 180 are locked together via a fastener; and/or the connecting piece 250 is clamped with the guide shell 180; and/or the connecting piece 250 is in threaded connection with the guide shell 180; and/or the connector 250 is an interference fit with the guide shell 180.

Specifically, as shown in fig. 8, the guide cylinder 180 is formed with a mounting member 260, the mounting member 260 is located between the exhaust port 190 and the bottom wall of the partition 210, and the connector 250 is engaged with the mounting member 260. The guide cylinder 180 is provided with the mounting part 260, the connecting part 250 is clamped with the mounting part 260, so that the guide cylinder 180 and the isolating part 240 are stably and firmly assembled, meanwhile, the structure can ensure the assembling position of the isolating part 210 relative to the guide cylinder 180, and further the size of a subsequently formed dielectric film can be ensured.

Specifically, as shown in fig. 7 and 8, the partition 210 is provided with at least one first air guide groove 270, and the first air guide groove 270 is recessed from the outside of the partition 210 to the inside of the partition 210. The isolation part 210 is provided with at least one first air guide groove 270, the first air guide groove 270 is recessed from the outside of the isolation part 210 to the inside of the isolation part 210, the first air guide groove 270 defines a flow path of steam, and the generated steam can be ensured to flow into the gap 220 between the isolation part 210 and the guide cylinder 180 rapidly and smoothly, and then flow out of the isolator 130 through the air outlet 190.

Specifically, based on the number of the first air guide grooves 270 being plural, the plural first air guide grooves 270 are arranged at intervals in the circumferential direction of the partition 210.

Specifically, the first air guide groove 270 is disposed at the bottom of the isolation portion 210; or the first air guide groove 270 is provided at the side of the partition 210; or a part of the first air guiding groove 270 is disposed at the bottom of the isolation portion 210, and another part of the first air guiding groove is disposed on the sidewall of the isolation portion 210.

Example 5:

as shown in fig. 7, 8, 9 and 10, according to an embodiment of the present invention, including the features defined in any of the above embodiments, and further: at least one of the partition plate 200 and the guide cylinder 180 is provided with at least one second air guide groove 280, and the second air guide groove 280 is recessed from the inside of the separator 130 to the outside of the separator 130.

In detail, by disposing the second air guide groove 280 such that the second air guide groove 280 is recessed from the inside of the separator 130 to the outside of the separator 130, the second air guide groove 280 defines a flow path of the steam, and it can be ensured that the generated steam rapidly and smoothly flows into the gap 220 between the separator 210 and the separator 200, and further flows out of the separator 130 through the air outlet 190.

Specifically, the number of the second air guide grooves 280 is plural, and the plural second air guide grooves 280 are arranged at intervals in the circumferential direction of the separator 130.

Specifically, the second air guide groove 280 is provided in the partition plate 200; or the second air guide groove 280 is arranged on the guide shell 180; or a part of the second air guide groove 280 is formed in the isolation plate 200, and another part of the second air guide groove 280 is formed in the guide cylinder 180.

Example 6:

as shown in fig. 3 and 6, according to an embodiment of the invention, including the features defined in any of the above embodiments, and further: the body 110 includes: a first housing 290, the heating member 120 being provided in the first housing 290; the second housing 300 is detachably connected to the first housing 290, at least a portion of the guide cylinder 180 extends out of the second housing 300, and the exhaust port 190 is located outside the second housing 300.

In detail, the machine body 110 includes a first housing 290 and a second housing 300, wherein the heating element 120 is disposed on the first housing 290, and the second housing 300 is detachably connected to the first housing 290, so that when the steam generating device 100 needs to be cleaned, the second housing 300 can be taken down from the first housing 290, and then the isolator 130 can be taken out from the first housing 290, so as to separate the isolator 130 from the machine body 110, thereby achieving the purpose of cleaning the machine body 110 and the isolator 130 separately.

In addition, since at least a portion of the guide cylinder 180 extends out of the second housing 300 and the exhaust port 190 is located outside the second housing 300, the second housing 300 has a function of fixing the isolator 130, that is, the position of the isolator 130 relative to the first housing 290 and the heating element 120 is defined by the assembly structure of the first housing 290 and the second housing 300, so that the amount of change in the gap between the inner surface of the machine body 110 accommodating the isolator 130 and the isolator 130 can be limited.

Specifically, the position relationship of the isolator 130 relative to the first housing 290 and the second housing 300 may be set according to actual situations, for example, the isolator 130 is located in the machine body 110, and the exhaust port 190 of the isolator 130 is arranged corresponding to the outlet on the second housing 300, so as to ensure the smoothness and feasibility of steam exhaust.

Example 7:

as shown in fig. 7, 9 and 10, according to an embodiment of the present invention, including the features defined in any of the above embodiments, and further: the steam generating apparatus 100 further includes: a medium passage 310 provided on at least one of the body 110 and the separator 130, the medium passage 310 being configured to communicate the first chamber 140 and the second chamber 150.

In detail, by providing the medium passage 310, the first chamber 140 and the second chamber 150 are communicated with each other through the medium passage 310, and the structural arrangement of the medium passage 310 defines the flow rate of the medium flowing into the first chamber 140 from the second chamber 150, so that the temperature reduction of the medium in the first chamber 140 is controllable, the generation of steam is not greatly affected, and the generated steam is discharged out of the separator 130 through the exhaust port 190, thereby ensuring the continuous generation of high-temperature steam and the work efficiency of the cooking pot.

Specifically, the bottom of the separator 130 or the inner surface of the body 110 is provided with support ribs that form at least part of the media passage 310. That is, the bottom of the isolator 130 is provided with a support rib, or the inner surface of the machine body 110 is provided with a support rib, a part of the support rib is provided on the inner surface of the machine body 110, and the other part of the support rib is provided on the bottom of the isolator 130. The structure is configured such that the separator 130 is separated from the inner surface of the body 110 by the support rib, so that the medium can pass through the first chamber 140 in the gap between the body 110 and the separator 130.

Specifically, the support rib is formed with a communication notch and/or a communication hole. The support rib is formed with a communication notch and/or a communication hole, so that the medium can enter the medium channel 310 through the communication notch and/or the communication hole and then flow into the first chamber 140, a necessary space support is provided for the stable and smooth flow of the medium, and the occurrence of dry burning of the heating element 120 caused by the fact that the medium outside the isolator 130 cannot effectively flow into the first chamber 140 is avoided.

Specifically, the support ribs are configured as closed or open ring-shaped structures distributed around the circumference of the separator 130; or the support ribs are constructed in an arc-shaped structure arranged along the circumference of the separator 130; or the supporting rib comprises a plurality of sub-ribs which are arranged at intervals.

Example 8:

as shown in fig. 3 and 6, according to an embodiment of the invention, including the features defined in any of the above embodiments, and further: the second chamber 150 is located on the peripheral side of the first chamber 140.

In detail, the second chamber 150 is located on the periphery of the first chamber 140, so as to achieve a heat insulation effect, on one hand, the heat loss inside the first chamber 140 is avoided, on the other hand, the user is prevented from being scalded, and the use safety of the user is ensured.

Example 9:

an embodiment of a second aspect of the present invention proposes a laundry treating apparatus, including: the steam generating device 100 of any embodiment of the first aspect; and a control device electrically connected to the heating member 120 of the steam generating device 100.

The laundry treating apparatus according to the present invention includes the separator 130 according to any of the embodiments of the first aspect, so that the laundry treating apparatus has all the advantages of the separator 130, which is not described herein.

Specifically, the control device is electrically connected to the heating member 120 of the steam generating device, and controls the heating member 120 to operate, so that the first chamber 140 or the second chamber 150 is heated and generates steam.

In particular, the laundry treating apparatus may be a steamer.

Specifically, the heating member 120 is a heat generating plate.

Specifically, as shown in fig. 3 and 5, the arrow direction indicates the flow direction of the airflow. Fig. 3 indicates the position of the water line 320, and when the steam generating device 100 is used, the water line 320 is located above the first chamber 140, and the volume of the first chamber 140 is smaller.

The specific embodiment is as follows:

as shown in fig. 1 to 10, the steam generating device 100 includes a separator 130, a heating plate, a body 110, a thermostat mounted on the heating plate, a power cord, and the like.

1. The isolator 130 comprises an isolation plate 200 and a guide cylinder 180, the isolation plate 200 is matched with the machine body 110, a gap is formed between the isolation plate 200 and the machine body 110 or between the isolation plate 200 and the heating plate, the periphery of the isolation plate 200 is placed in the machine body 110, and the isolator 130 can also be fixed in the machine body 110 through a buckle 160 and a clamping groove 170. Since the body 110 includes the first housing 290 and the second housing 300, the second housing 300 can be used to press the isolator 130, so as to prevent the isolator 130 from floating under the action of water pressure; water inside the body 110 can enter the first cavity between the partition plate 200 and the bottom wall of the body 110 through the gap between the partition plate 200 and the bottom wall of the body 110. The guide cylinder 180, the isolation plate 200 and the heating plate enclose a first chamber 140 with a small area, or the guide cylinder 180, the isolation plate 200 and the inner bottom wall of the body 110 enclose the first chamber 140 with a small area. The water in the first chamber 140 is directly heated by the heating plate, and quickly reaches a boiling state, so that steam is quickly realized; meanwhile, the isolator 130 is detachable and can clean the heating plate.

2. The bottom of the isolator 130 is provided with a water inlet groove, so that the water inlet resistance is reduced, and dry burning is prevented.

3. The separator 130 is provided with a groove or a convex water inlet structure.

In an exemplary embodiment, the laundry treating apparatus is a steamer, and includes a steam generating device 100 and a control device, the steam generating device 100 includes a body, an isolator 130, a heating element 120, a thermostat, a power cord, and the like, and the heating element 120 is disposed in the body 110.

In one aspect, as shown in fig. 6, 9 and 10, the separator 130 includes a guide cylinder 180 and a partition plate 200, the partition plate 200 is disposed in the machine body 110 and located above the heating element 120, an inner surface of the partition plate 200 and the machine body 110 and/or the heating element 120 enclose the first chamber 140, the guide cylinder 180 is communicated with the partition plate 200, at least a portion of the guide cylinder 180 is disposed outside the machine body, an outer surface of the separator 130 and the machine body enclose the second chamber 150, and the partition plate 200 is provided with a medium passage 310 communicating the first chamber 140 and the second chamber 150, so that a medium contained in the second chamber 150 flows into the first chamber 140 through the medium passage 310. Since the space in the first chamber 140 is constant and contains a small amount of medium, that is, the volume or volume of the medium in the first chamber 140 is small, the heating element 120 acts on the small amount of medium in the first chamber 140 to rapidly generate high-temperature steam, and the steam is discharged to a designated area through the exhaust port 190 on the guide cylinder 180.

On the other hand, as shown in fig. 3, 4, 5, 7 and 8, the separator 130 includes a guide cylinder 180, a partition plate 200 and a partition 210, at least a portion of the partition 210 is located inside the guide cylinder 180, the partition plate 200 and the partition 210 are disposed in the machine body and above the heating element 120, an inner surface of the partition plate 200, the partition 210, the machine body 110 and/or the heating element 120 enclose the first chamber 140, a gap 220 is formed between the partition 210 and the guide cylinder 180, the gap 220 is communicated with the exhaust port 190 of the guide cylinder 180, at least a portion of the guide cylinder 180 is disposed outside the machine body, an outer surface of the separator 130 and the machine body enclose the second chamber 150, and the partition plate 200 is provided with a medium passage 310 communicating the first chamber 140 and the second chamber 150, so that a medium contained in the second chamber 150 flows into the first chamber 140 through the medium passage 310. Since the space in the first chamber 140 is constant and a relatively small amount of the medium is contained, that is, the volume or volume of the medium in the first chamber 140 is small, the heating element 120 acts on the small amount of the medium in the first chamber 140 to rapidly generate high-temperature steam, and the steam is discharged to a designated area through the gap 220 between the guide cylinder 180 and the partition 210 through the exhaust port 190.

Further, in the separator 130 according to the above two aspects, the first chamber 140 and the second chamber 150 are communicated with each other through the medium passage 310 (e.g., a water inlet tank), so that in the process that the medium in the first chamber 140 is reduced due to the generation of steam, the medium in the second chamber 150 gradually enters the first chamber 140 for replenishment, the water inlet resistance is reduced, the problem that the heating element 120 is damaged due to dry burning caused by a small amount of the medium in the first chamber 140 can be avoided, and the reliability of the product is further improved.

Further, connect heating member 120 and temperature controller through controlling means, and the operating condition according to the switching state control heating member 120 of temperature controller, make when the temperature of heating member 120 is higher the temperature controller move and then will connect the circuit disconnection of heating member 120, make heating member 120 stop work, can avoid heating member 120 to continue to heat effectively when the temperature is higher and have the problem of damage, can avoid heating member 120 to burn futilely promptly, prolonged the life of heating member 120, the reliability of product has been improved. Specifically, when the medium passage 310 is a water inlet groove, the water inlet groove may be a water inlet groove formed by a protrusion or a groove provided at the bottom of the partition plate 200.

Further, the body 110 includes a first housing 290 and a second housing 300, the second housing 300 is covered at the opening 230 of the first housing 290, the isolation plate 200 of the isolator 130 is disposed in the first housing 290, specifically, in one aspect, the isolation plate 200 is disposed in the first housing 290, the inner surface of the isolation plate 200 forms the first chamber 140 with the bottom wall of the first housing 290 and/or the heating element 120, or the inner surface of the isolation plate 200, the isolation part 210 forms the first chamber 140 with the bottom wall of the first housing 290 and/or the heating element 120. The guide cylinder 180 is disposed through the second housing 300, so that at least a part of the guide cylinder 180 is located outside the second housing 300, and steam generated by the heating element 120 acting on the medium in the first chamber 140 is exhausted to a designated area outside the second housing 300 through the exhaust port 190 on the guide cylinder 180, or the steam is exhausted to the designated area outside the second housing 300 through the exhaust port 190 through the gap 220 between the guide cylinder 180 and the partition 210.

Specifically, on the one hand, the periphery of the isolation plate 200 is matched with the first housing 290 through the buckle 160 and the clamping groove 170 to fix the isolator 130 in the first housing 290, so that the isolator 130 can be prevented from floating upward under the action of water pressure, the positions and the gap variation of the isolation plate 200 and the first housing 290 and/or the heating element 120 are limited, and then the amount and the flow rate of liquid entering the first chamber 140 from the outside of the isolator 130 are limited, so that the reduction of the temperature of the liquid in the first chamber 140 is controllable, the generation of steam is not greatly influenced, and the steam can be rapidly discharged. Furthermore, the isolator 130 is detachably connected to the first housing 290, and when the isolator 130 is detached from the first housing 290, a user can clean the machine body and the isolator 130 or remove scales conveniently.

On the other hand, the isolator 130 is connected to the second housing 300, and specifically, after the isolator 130 is placed in the first housing 290, the second housing 300 is connected to the first housing 290, so that the second housing 300 presses the isolator 130, so that the isolator 130 is fixed in the first housing 290, the effect of preventing the isolator 130 from floating under the action of water pressure can also be achieved, and the purpose of facilitating cleaning can be achieved.

In the present invention, the term "plurality" means two or more unless explicitly defined otherwise. The terms "mounted," "connected," "fixed," and the like are to be construed broadly, and for example, "connected" may be a fixed connection, a removable connection, or an integral connection; "coupled" may be direct or indirect through an intermediary. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

In the description herein, the description of the terms "one embodiment," "some embodiments," "specific embodiments," etc., means that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

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

Claims (20)

1. A steam generating apparatus, comprising:

a body provided with a heating member;

the isolator is at least partially accommodated in the machine body, the position height of the isolator is higher than that of the heating element, the isolator and the machine body enclose a first cavity and a second cavity, and the first cavity is communicated with the second cavity;

wherein the heating element is configured to supply heat to at least the first chamber, the heating element comprising at least one heating portion.

2. The steam generating apparatus of claim 1, further comprising:

and the limiting structure is positioned in the machine body, and the machine body and the isolator are detachably connected through the limiting structure.

3. Steam generating device according to claim 2,

the limiting structure comprises a magnetic part, and the machine body and the isolator are assembled through the magnetic part in a magnetic way; and/or

The limiting structure comprises a locking part, and the machine body and the isolator are assembled in a locking way through the locking part; and/or

The limiting structure comprises a clamping portion, and the machine body and the isolators are assembled in a clamping mode through the clamping portion.

4. Steam generating device according to claim 3,

the limiting structure comprises the magnetic suction part, the limiting structure is provided with an accommodating cavity, and the magnetic suction part is positioned in the accommodating cavity;

based on the limit structure comprising the locking part, the locking part comprises a mounting hole and/or a mounting groove;

based on limit structure includes joint portion, joint portion includes draw-in groove and buckle, and one of draw-in groove and buckle is located the organism, another is located the isolator.

5. A steam generating device according to any one of claims 1 to 4, wherein the separator comprises:

the guide cylinder is provided with an exhaust port, and one end of the guide cylinder is provided with a port;

the baffle plate is connected with the guide shell, extends from the edge of the port to the outer side of the guide shell, and defines at least one part of the first chamber.

6. Steam generating device according to claim 5,

the cross-sectional area of the guide shell in the direction from the partition plate to the exhaust port comprises any one or a combination of the following: equal, gradually increasing, and gradually decreasing.

7. The steam generating apparatus of claim 5, wherein the separator further comprises:

the isolating part is at least partially positioned in the guide cylinder and connected with the guide cylinder, a gap is formed between the isolating part and the guide cylinder, and the gap is communicated with the exhaust port;

wherein a bottom wall of the partition defines at least a portion of the first chamber.

8. Steam generating device according to claim 7,

the slit is positioned on the peripheral side of the isolation part; or

A part of the slits are located on the peripheral side of the partition, and another part of the slits are located on the top of the partition.

9. Steam generating device according to claim 7,

the bottom wall of the partition is located between the partition plate and the heating member.

10. Steam generating device according to claim 7,

the partition has an opening, and the exhaust port surrounds the opening, or is located at one side of the opening.

11. The steam generating device as recited in claim 7, wherein the partition comprises:

a partition having a bottom wall defining at least a portion of the first chamber;

a connector connected with the spacer, the connector configured to connect the spacer and the draft tube.

12. The steam generator of claim 11, wherein the guide cylinder is formed with a mounting member, the mounting member is located between the exhaust port and the bottom wall of the isolation portion, and the connecting member is engaged with the mounting member.

13. Steam generating device according to claim 7,

the isolating part is provided with at least one first air guide groove, and the first air guide groove is sunken from the outside of the isolating part to the inside of the isolating part.

14. Steam generating device according to claim 5,

at least one of the isolation plate and the guide cylinder is provided with at least one second air guide groove, and the second air guide groove is sunken from the inside of the isolator to the outside of the isolator.

15. The steam generating device as claimed in claim 5, wherein the body comprises:

the heating element is arranged in the first shell;

the second shell is detachably connected with the first shell, at least part of the guide cylinder extends out of the second shell, and the air outlet is located on the outer side of the second shell.

16. A steam generating device as recited in any of claims 1-4, further comprising:

a media passage provided in at least one of the body and the separator, the media passage being configured to communicate the first chamber and the second chamber.

17. Steam generating device according to claim 16,

and support ribs are arranged at the bottom of the isolator or on the inner surface of the machine body, and at least part of the medium channel is formed by the support ribs.

18. Steam generating device according to claim 17,

the support rib is provided with a communication notch and/or a communication hole.

19. Steam generating device according to one of claims 1 to 4,

the second chamber is located on the peripheral side of the first chamber.

20. A laundry treating apparatus, comprising:

a steam generating device as claimed in any one of claims 1 to 19; and

and the control device is electrically connected with the heating element of the steam generating device.

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