CN217560394U - Condensation assembly and micro-steaming and baking equipment - Google Patents

Abstract

The utility model belongs to the technical field of kitchen utensil, a condensation subassembly and evaporate roast equipment a little is disclosed, the condensation subassembly includes the bottom plate, a plurality of condensation plates and condensation fin, be provided with the apopore on the bottom plate, a plurality of condensation plate separate to set up on the bottom plate, the one end of a plurality of condensation plates is towards the apopore, the apopore is kept away from to the other end, the condensation plate is the structure of buckling, form a condensation chamber between two adjacent condensation plates, the condensation fin sets up on the condensation plate and is located the condensation intracavity, condensation plate and/or condensation fin are packaged with phase change material. The condensing assembly of the utility model utilizes the condensing plate and the condensing fins to absorb the heat of the steam entering the condensing cavity, and carries out water-vapor separation and cooling on the steam, wherein part of the steam is cooled to form condensed water and is discharged from the water outlet hole, and the other part of the cooled gas is discharged from one end of the condensing cavity facing the water outlet hole; the phase change material is packaged by the condensing plate and/or the condensing fin, so that the cooling efficiency of steam in the condensing cavity is improved.

Description

Condensation assembly and micro-steaming and baking equipment

Technical Field

The utility model relates to a kitchen utensil technical field especially relates to a condensation subassembly and evaporate roast equipment a little.

Background

The micro steaming and baking equipment is used as a kitchen utensil with comprehensive functions, mainly comprises a box body with an inner container and a steam generator arranged at the bottom of the inner container, and food is processed into cooked food by high-temperature and high-pressure gas generated by the steam generator. At the in-process of evaporating roast equipment work a little, need constantly avoid inner bag high pressure with steam discharge to cause danger, nevertheless evaporate roast equipment a little among the prior art, the majority is with the high temperature steam in the inner bag through the steam vent direct discharge to the external environment in, exhaust high temperature steam contains tiny liquid drop and high temperature gas, thereby the user is scalded very easily to direct exhaust high temperature steam, still can cause kitchen environment high temperature and high humidity simultaneously, influence user's experience and feel.

Therefore, it is desirable to design a new condensing assembly and micro-steaming and baking apparatus to improve the above problems.

SUMMERY OF THE UTILITY MODEL

A first object of the utility model is to provide a condensation subassembly can absorb the heat in the steam, carries out steam-water separation and cooling to steam to the condensation chamber of separately discharging of condensate water and low temperature gas's form.

A second object of the utility model is to provide a evaporate roast equipment a little for evaporate the high temperature steam that roast equipment during operation produced a little and can separately discharge with condensate water and low temperature gas's form fast, avoid high temperature to hurt the user, also solved the problem of kitchen environment high temperature and high humidity simultaneously.

To achieve the purpose, the utility model adopts the following technical proposal:

a condensing assembly, comprising:

the water outlet is formed in the bottom plate;

the plurality of condensation plates are arranged on one side surface of the bottom plate at intervals along the same direction, one end of each condensation plate faces the water outlet hole, the other end of each condensation plate extends in the direction far away from the water outlet hole, each condensation plate is of a bent structure, and a condensation cavity is formed between every two adjacent condensation plates;

the condensation fin, the condensation fin set up in on the condensation plate and be located the condensation intracavity, the condensation plate and/or the condensation fin encapsulates there is phase change material.

Preferably, the condensation assembly further comprises a heat sink disposed on the other side of the base plate.

Preferably, the condensation plate comprises a plurality of connected bending sections and two flat plate sections connected to two bending sections at two ends, and the two flat plate sections are parallel to each other and are positioned on the same straight line.

Preferably, the condensation fins comprise first condensation fins, one ends of the first condensation fins are connected to the bending sections, the other ends of the first condensation fins extend towards the sides of the water outlet holes, and the first condensation fins and the condensation plates with the same trend are parallel and spaced to form first gaps.

Preferably, the condensation fins comprise second condensation fins, the second condensation fins are arranged on the bending section and extend towards the side far away from the water outlet hole, and the second condensation fins are parallel to the condensation plates with the same trend and form second gaps at intervals.

Preferably, the condensing fin includes the third condensing fin, the third condensing fin set up in being close to the apopore on the flat section, the third condensing fin orientation is kept away from the direction of apopore extends, the third condensing fin with the flat section is the contained angle setting.

Preferably, the bottom plate is far away from the condensation plate, a drain pipe is arranged on the surface of the condensation plate, one end of the drain pipe is communicated with the water outlet hole, and the other end of the drain pipe is detachably sleeved with a water collecting cover.

Preferably, the bilateral symmetry of apopore is equipped with two deflectors, the deflector orientation the apopore slope sets up, two the one end of deflector connects respectively in one the flat plate section, and the other end interval sets up in order to form the gas outlet, the gas outlet with the apopore interval sets up.

Preferably, both ends of the two outermost condensation plates extend to the upper and lower edges of the bottom plate, and both ends of the condensation plate located at the inner side are spaced from the upper and lower edges of the bottom plate by a certain distance.

Preferably, the micro steaming and baking equipment comprises a heat radiation fan, a micro steaming and baking equipment body and the condensation assembly, wherein the heat radiation fan is installed on a shell of the micro steaming and baking equipment body, the condensation assembly is installed on a cover plate of the heat radiation fan, a vent hole communicated with the condensation cavity is formed in the cover plate, an inner container of the micro steaming and baking equipment body is communicated with the vent hole, a heat radiation air duct is formed between the cover plate and the shell of the micro steaming and baking equipment body, the condensation assembly is located in the heat radiation air duct, and a blowing port of the heat radiation fan faces one side of the condensation assembly to supply air to the condensation assembly and the heat radiation air duct.

Preferably, the micro steaming and baking equipment further comprises a communicating pipe, and two ends of the communicating pipe are respectively communicated with the inner container of the micro steaming and baking equipment body and the vent hole.

The utility model has the advantages that:

the utility model discloses a condensation subassembly forms the condensation chamber in order to supply the vapor circulation through a plurality of condensation plates that set up on the bottom plate, and when steam passed through the condensation chamber, the condensation subassembly utilized the condensation plate and set up the heat in the condensation fin can absorb steam on the condensation plate, carries out steam-water separation and cooling to steam. Through setting up the condensing panel into the structure of buckling, and cooperation condensing fin is the contained angle setting with the condensing panel, make steam flow with the curvilinear motion orbit when moving in the condensation chamber, thereby on liquid drop in the steam can strike condensing panel and condensing fin, the liquid drop that adsorbs on condensing panel and condensing fin gathers into the water film gradually, flow along condensing panel and bottom plate towards the apopore under the flow effect of gravity and steam, discharge from the apopore on the bottom plate at last, and gas in the steam can continue to flow through in the condensation chamber, the gas that is cooled down at last is discharged from the one end of condensation chamber towards the apopore. In addition, the phase change material is packaged by the condensing plate and/or the condensing fin, so that the steam contacting the outer surface of the condensing plate or the condensing fin can be quickly absorbed with a large amount of heat in a short time, and the cooling efficiency of the steam in the condensing cavity is improved.

The utility model discloses a evaporate roast equipment a little, through evaporating roast equipment a little the inner bag and the air vent intercommunication on the apron, thereby will evaporate the high-temperature steam that produces in roast equipment during operation its inner bag a little and advance the condensation intracavity, supply air simultaneously in condensation chamber and heat dissipation wind channel under cooling fan's cooperation again, thereby the high-temperature steam that flows carries out steam separation cooling on one side in the condensation chamber, accelerate the radiating efficiency of condensation subassembly, make the high-temperature steam that evaporates roast equipment a little and produce can the express delivery separately discharge with condensate water and low-temperature gas's form, avoid the high temperature injury to the user, the problem of kitchen high temperature and high humidity has also been solved simultaneously.

Drawings

Fig. 1 is a schematic structural diagram of a micro steaming and baking apparatus according to an embodiment of the present invention;

fig. 2 is a schematic structural diagram ii of a micro steaming and baking device provided in an embodiment of the present invention;

fig. 3 is a schematic partial structural view of a micro steaming and baking apparatus according to an embodiment of the present invention;

FIG. 4 is an enlarged view of a portion of FIG. 3 at A;

fig. 5 is a first schematic structural diagram of a condensation assembly according to an embodiment of the present invention;

fig. 6 is a schematic structural diagram ii of a condensation assembly according to an embodiment of the present invention;

fig. 7 is a schematic structural diagram three of a condensation assembly provided in the embodiment of the present invention;

fig. 8 is a schematic structural diagram of a condensation plate of a condensation assembly according to an embodiment of the present invention.

In the figure:

1-a bottom plate; 11-water outlet; 12-a guide plate; 120-gas outlet; 13-mounting holes;

2-a cold plate; 20-a condensation chamber; 201-a first gap; 202-a second gap; 21-bending section; 22-a plate section; 221-an extension section; 2201-gas inlet;

31-a first condensing fin; 32-a second condensing fin; 33-a third condensing fin;

4-a heat sink;

5, a drain pipe; 51-a water collecting cover;

6-a heat dissipation fan; 61-a cover plate; 611-a vent hole; 612-connecting tube; 62-an air blowing port;

7-micro steaming and baking equipment body;

8-a heat dissipation air duct;

9-communicating pipe.

Detailed Description

Reference will now be made in detail to the embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the same or similar parts throughout, or parts having the same or similar functions. The embodiments described below with reference to the drawings are exemplary and intended to be used for explaining the present invention, and should not be construed as limiting the present invention.

In the description of the present invention, unless otherwise specifically stated or limited, the terms "connected," "connected," and "fixed" are to be understood broadly, and may include, for example, a fixed connection, a detachable connection, a mechanical connection, an electrical connection, a direct connection, an indirect connection through an intermediary, a connection between two elements, or an interaction between two elements. The specific meaning of the above terms in the present invention can be understood according to specific situations by those skilled in the art.

In the description of the present invention, unless otherwise expressly specified or limited, the recitation of a first feature "on" or "under" a second feature may include the recitation of the first and second features being in direct contact, and may also include the recitation of the first and second features not being in direct contact, but being in contact with another feature between them. Also, the first feature being "on," "above" and "over" the second feature includes the first feature being directly on and obliquely above the second feature, or merely indicating that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature includes the first feature being directly under and obliquely below the second feature, or simply meaning that the first feature is at a lesser elevation than the second feature.

The technical solution of the present invention is further explained by the following embodiments with reference to the accompanying drawings.

As shown in fig. 1 to 3, the utility model provides a evaporate roast equipment a little, evaporate roast equipment a little and include radiator fan 6, evaporate roast equipment body 7 and condensation subassembly a little, radiator fan 6 is installed on evaporating the shell of roast equipment body 7 a little, the condensation subassembly is installed on radiator fan 6's apron 61, form heat dissipation wind channel 8 between radiator fan 6's apron 61 and evaporating the shell of roast equipment body 7 a little, the condensation subassembly is located heat dissipation wind channel 8, radiator fan 6's mouth of blowing 62 sets up towards one side of condensation subassembly, with simultaneously to in the condensation subassembly with in the heat dissipation wind channel 8 air supply. The cover plate 61 is provided with a vent hole 611 communicated with the condensation cavity 20, and the inner container of the micro steaming and baking device body 7 is communicated with the vent hole 611, so that high-temperature steam generated in the inner container of the micro steaming and baking device body 7 is sent into the condensation component through the vent hole 611.

As shown in fig. 4 and 5, the condensing assembly provided in this embodiment includes a bottom plate 1, a plurality of condensing plates 2, and condensing fins, and a water outlet 11 is provided on the bottom plate 1. A plurality of condensation plates 2 set up on bottom plate 1 along same direction interval, the one end of a plurality of condensation plates 2 is towards apopore 11, apopore 11 is kept away from to the other end, condensation plate 2 is the structure of buckling, form a condensation chamber 20 between two adjacent condensation plates 2, through apron 61 closing cap condensation chamber 20 on the cooling fan 6 the accent that deviates from bottom plate 1, the accent that apopore 11 was kept away from to condensation chamber 20 is towards cooling fan 6's mouth 62 of blowing, thereby utilize cooling fan 6 to supply air to one side that condensation chamber 20 is interior and bottom plate 1 deviates from condensation plate 2 simultaneously. The condensing fins are disposed on the condensing plate 2 and located in the condensing cavity 20, the condensing fins and the condensing plate 2 form an included angle, the condensing plate 2 and/or the condensing fins are packaged with a phase change material, and the condensing fins in this embodiment may be flat or bent.

The condensation assembly of this embodiment, through setting up the condensation chamber 20 that a plurality of condensing panels 2 on bottom plate 1 formed in order to supply the circulation of steam, high temperature steam in the inner bag of little roast equipment body 7 gets into condensation chamber 20 through air vent 611 on the apron 61, and cooling blower 6 constantly blows to condensation chamber 20 and heat dissipation wind channel 8. When high temperature steam passes through condensation chamber 20, the heat that condensation assembly utilized condensing plate 2 and set up in condensing plate 2 on condensing fin 3 can absorb steam carries out steam-water separation and cooling to steam to flowing high temperature steam carries out steam-water separation while cooling in condensation chamber 20. Through setting up condensing plate 2 into the structure of buckling, and cooperation condensing fin is the contained angle setting with condensing plate 2, make steam flow with the curvilinear motion orbit when moving in condensation chamber 20, thereby on condensing plate 2 and condensing fin 3 can be strikeed to the liquid drop in the steam, adsorb the liquid drop on condensing plate 2 and condensing fin 3 and gather gradually into the water film, flow towards apopore 11 along condensing plate 2 and bottom plate 1 under gravity and the flow effect of steam, discharge from apopore 11 on the bottom plate 1 at last, and gas in the steam can continue to circulate in condensation chamber 20, gas after the cooling is discharged heat dissipation wind channel 8 from condensation chamber 20 towards apopore 11 accent, the roast equipment of little steaming of discharging at last. In addition, the condensing plate 2 and/or the condensing fins in the embodiment are packaged with the phase change material, so that the steam contacting the outer surface of the condensing plate 2 or the condensing fins can be rapidly absorbed with a large amount of heat in a short time, and the cooling efficiency of the steam in the condensing cavity 20 is improved.

The roast equipment of evaporating a little of this embodiment, through establishing apron 61 lid on a plurality of condensing panels 2 with the accent that closing cap condensation chamber 20 deviates from bottom plate 1, carry the high-temperature steam in roast equipment body 7 inner bag of evaporating a little to condensation chamber 20 in to the air vent 611 on the apron 61, blow the mouth 62 of blowing through with radiator fan 6 to condensation chamber 20 with the wind channel 8 of dispelling the heat simultaneously air supply, thereby the high-temperature steam that flows carries out steam and water separation while cooling in condensation chamber 20, and radiator fan 6 is bloied and also can be accelerated the heat exchange efficiency of bottom plate 1 with the outside air to dispelling the heat in the wind channel 8, make the high-temperature steam that the roast equipment during operation of evaporating a little produce can separately discharge with condensate water and low-temperature gas's form fast, avoid high temperature to hurt the user, the high temperature and high humidity problem in kitchen has also been solved simultaneously.

Optionally, referring to fig. 1 and fig. 4, the micro steaming and baking device of this embodiment further includes a communicating tube 9, a connecting tube 612 is disposed on a surface of the cover plate 61 away from the condensing assembly, one end of the connecting tube 612 is communicated with the vent hole 611, one end of the communicating tube 9 is sleeved on the other end of the connecting tube 612, and the other end of the communicating tube 9 is communicated with the inner container of the micro steaming and baking device body 7. The high-temperature steam in the inner container of the micro-steaming and baking device body 7 is conveyed to the condensation cavity 20 through the communicating pipe 9.

Optionally, referring to fig. 4 and 6, the condensing assembly further includes a heat sink 4, and the heat sink 4 is disposed on the other side surface of the base plate 1 and located in the heat sink air duct 8. Absorb the heat that comes from on condensation plate 2 and the condensation fin 3 through setting up fin 4, and then utilize radiator fan 6 to blow the cold air in the surrounding environment to fin 4, arrange the air through apron 61 in, carry out the heat exchange with higher speed between condensation subassembly and the outside air, improve the radiating efficiency.

Optionally, a plurality of cooling fins 4 are provided, and the plurality of cooling fins 4 are arranged on the bottom plate 1 at intervals, so as to further improve the heat exchange efficiency between the condensation assembly and the outside air.

Optionally, the inside inclosed chamber that holds that is equipped with of condensation fin, the inside intracavity that holds of condensation fin is packaged with phase change material, and phase change material and condensation fin fully contact absorbs the heat of condensation fin through the thermoelectric effect for steam that contacts on the condensation fin surface can be absorbed the heat by a large amount at a short time fast, realizes the steam condensation. Meanwhile, by utilizing the characteristic that the phase change material has liquid-vapor phase change, the condensing fins continuously conduct the heat of the vapor to the radiating fins 4 under the matching of the radiating fins 4.

Optionally, the inside inclosed chamber that holds that is equipped with of cold plate 2, the inside intracavity that holds of cold plate 2 is packaged with phase change material, and phase change material and cold plate 2 fully contact absorb the heat of cold plate 2 through the thermoelectric effect for steam that contacts on the cold plate 2 surface can be absorbed the heat by a large amount fast in the short time. Meanwhile, by utilizing the characteristic that the phase-change material has liquid-vapor phase change, the condensation plate 2 continuously conducts the heat of the vapor to the heat radiating fins 4 under the matching of the heat radiating fins 4.

Optionally, referring to fig. 4 and fig. 6, a drain pipe 5 is arranged on the surface of the bottom plate 1 away from the condensation plate 2, one end of the drain pipe 5 is communicated with the water outlet hole 11, the other end of the drain pipe 5 is detachably sleeved with a water collecting cover 51, and the drain pipe 5 is used to drain condensed water at the water outlet hole 11 into the water collecting cover 51.

Alternatively, referring to fig. 4 and 5, the aperture of the outlet opening 11 is gradually reduced in a direction toward the drain pipe 5, so that the condensed water in the outlet opening 11 is guided to flow into the drain pipe 5.

Optionally, referring to fig. 5, the bottom plate 1 of the condensation assembly of the present embodiment is provided with a mounting hole 13, so as to fasten the bottom plate 1 and the cover plate 61 by using a fastening member, so that the condensation assembly is firmly mounted on the cover plate 61, and the cover plate 61 is covered on the end surface of the condensation plate 2 away from the bottom plate 1 to cover the opening of the condensation chamber 20 away from the bottom plate 1.

Alternatively, referring to fig. 5 and 7, the condensation plate 2 includes a plurality of connected bent segments 21 and two flat segments 22 connected to the two bent segments 21 at both ends, and the two flat segments 22 are parallel to each other and located on the same straight line. The flat plate section 22 far away from the water outlet hole 11 guides the air blown out from the air blowing port 62 on the heat dissipation fan 6 to enter the condensation cavity 20, and the flat plate section 22 facing the water outlet hole 11 guides the gas after the water-vapor separation, the condensed water and the air of the heat dissipation fan 6 to respectively flow out of the condensation cavity 20. The two flat sections 22 at the two ends of the condensing plate 2 are parallel to each other and are positioned on the same straight line, so that the flow direction of the air is prevented from being greatly changed from front to back, and the air blown by the cooling fan 6 through the condensing assembly can smoothly circulate. The steam flows in the condensation chamber 20 in a curved motion track through the bent section 21 between the two flat plate sections 22, so that liquid drops in the steam can impact on the condensation plates 2 and the condensation fins, and the steam-water separation of the high-temperature steam is realized.

Alternatively, referring to fig. 4 and 5, both ends of the two outermost condensation plates 2 extend to the upper and lower edges of the bottom plate 1, and both ends of the condensation plate 2 located at the inner side are spaced from the upper and lower edges of the bottom plate 1. That is, in the embodiment, on the two condensation plates 2 located at the outermost sides, the extension sections 221 are extended from one end of the flat plate section 22 away from the bending section 21, the extension sections 221 at the two ends of the condensation plate 2 are respectively extended to the upper edge and the lower edge of the bottom plate 1, so that the cover plate 61 and the two extension sections 221 away from the water outlet hole 11 are enclosed to form the air inlet 2201, and the air inlet 2201 is used for allowing the air blown out from the air blowing port 62 on the heat dissipation fan 6 to enter the condensation cavity 20.

Alternatively, referring to fig. 4 and 5, two guide plates 12 are symmetrically disposed on two sides of the water outlet hole 11, the guide plates 12 are disposed in an inclined manner toward the water outlet hole 11, one ends of the two guide plates 12 are respectively connected to two extending sections 221 near the water outlet hole 11, and the other ends are spaced to form a gas outlet 120, and the gas outlet 120 is spaced from the water outlet hole 11 along the extending direction of the condensation plate 2. After the condensing assembly is mounted on the cover plate 61, the air cooled by the condensing plate 2 and the condensing fins and the air blown into the condensing cavity 20 by the heat dissipation fan 6 can pass through the air outlet 120 and enter the heat dissipation air duct 8.

Alternatively, the height of the guide plate 12 in the height direction of the bottom plate 1 is equal to or less than the height of the condensation plate 2, and is set according to specific working conditions. When the height of the guide plates 12 and the height of the condensation plate 2 are set to be equal, the wind in the condensation chamber 20 enters the heat dissipation air duct 8 only from the air outlet 120 formed between the guide plates 12. When the height of the guide plate 12 is smaller than that of the condensation plate 2, a vent can be further formed between the cover plate 61 and the end face of the guide plate 12 far away from the bottom plate 1, that is, the air in the condensation chamber 20 can enter the heat dissipation air duct 8 through the air outlet 120 and can also enter the heat dissipation air duct 8 through the vent.

Alternatively, referring to fig. 5 and 7, the distance between the guide plate 12 and the gas inlet 2201 gradually increases in a direction toward the gas outlet 120, i.e., the angle at which the guide plate 12 is obliquely disposed with respect to the extension section 221, so as to guide the gas in each condensation chamber 20 to the gas outlet 120.

Alternatively, referring to fig. 7 and 8, the condensing fin in the present embodiment includes a first condensing fin 31 having a flat plate shape, one end of the first condensing fin 31 is connected to the bent section 21, and the other end extends toward the side of the outlet hole 11, and the first condensing fin 31 is parallel to the condensing plate 2 having the same tendency as the first condensing fin 31 and is spaced apart from the same tendency to form a first gap 201. Through extending towards apopore 11 place side and setting up first condensing fin 31, can increase the area of contact of condensation subassembly and steam, improve the curvilinear motion orbit of steam in condensation chamber 20, first clearance 201 also provides the space of wandering for steam in condensation chamber 20, and first condensing fin 31 extends towards apopore 11 place side and is favorable to leading one side circulation of steam towards apopore 11.

Optionally, referring to fig. 7 and 8, the condensing fin in the present embodiment further includes a second condensing fin 32 in a bent plate shape, the second condensing fin 32 is disposed on the bent section 21 and extends toward a side away from the water outlet hole 11, and a bent end of the second condensing fin 32 is parallel to the condensing plate 2 with the same trend as that of the second condensing fin and spaced to form a second gap 202. The contact area of the condensing assembly and the steam can be increased to a greater extent through the second condensing fins 32 in the shape of bent plates, the curved motion track of the steam in the condensing cavity 20 is improved, the second gaps 202 also provide a space for the steam to wander in the condensing cavity 20, and meanwhile, the second condensing fins 32 extend towards the side away from the water outlet hole 11, so that liquid drops in the flowing steam more easily impact on the second condensing fins 32.

Optionally, referring to fig. 7 and 8, the condensing fin in this embodiment further includes a third condensing fin 33 in a flat plate shape, the third condensing fin 33 is disposed on the flat plate segment 22 near the water outlet hole 11, the third condensing fin 33 extends toward a direction away from the water outlet hole 11, and the third condensing fin 33 is disposed at an angle with respect to the flat plate segment 22. The contact area of the condensing assembly and the steam can be increased by the third condensing fins 33, the third condensing fins 33 extend in a direction away from the water outlet hole 11, and the distance between the third condensing fins 33 and the flat plate section 22 gradually increases in the direction away from the water outlet hole 11, so that a space for steam to wander can be continuously provided immediately before the steam flows out of the condensing cavity 20, and droplets in the steam can more easily impact the third condensing fins 33 to cool the steam immediately before the steam flows out of the condensing cavity 20.

Alternatively, referring to fig. 7 and 8, the connection of the first condensing fin 31 to the bend 21 has a distance from the corner of the bend 21, which is the width of the first gap 201. One end of the second condensation fin 32 is connected to a corner of the bending section 21, and the other end of the second condensation fin 32 is spaced from the bending section 21, so that a second gap 202 is formed between the second condensation fin 32 and the bending section 21, wherein the distance between the other end of the second condensation fin 32 and the bending section 21 is the width of the second gap 202.

Optionally, referring to fig. 7 and 8, in the present embodiment, each bent section 21 is configured with a first condensing fin 31 and a second condensing fin 32, so that the first condensing fin 31 and the second condensing fin 32 on two adjacent bent sections 21 can be matched with each other, thereby improving the steam-water separation effect and the cooling efficiency of the condensing assembly on steam.

Alternatively, a plurality of first gaps 201 are formed between the plurality of first condensing fins 31 and the condensing plate 2 on the plurality of bent sections 21, and the width of the plurality of first gaps 201 may be constant or gradually reduced in a direction toward the water outlet hole 11. On the plurality of bent segments 21, a plurality of second gaps 202 are formed between the plurality of second condensing fins 32 and the condensing plate 2, and the width of the plurality of second gaps 202 may be constant or gradually reduced along the direction toward the water outlet hole 11.

It is obvious that the above embodiments of the present invention are only examples for clearly illustrating the present invention, and are not intended to limit the embodiments of the present invention. Other variations and modifications will be apparent to persons skilled in the art in light of the above description. And are neither required nor exhaustive of all embodiments. 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 claims of the present invention.

Claims (11)

1. A condensing assembly, comprising:

the water-saving device comprises a bottom plate (1), wherein a water outlet hole (11) is formed in the bottom plate (1);

the condensation plates (2) are arranged on one side face of the bottom plate (1) at intervals along the same direction, one end of each condensation plate (2) faces the water outlet hole (11), the other end of each condensation plate extends in the direction far away from the water outlet hole (11), each condensation plate (2) is of a bent structure, and a condensation cavity (20) is formed between every two adjacent condensation plates (2);

the condensation fin, the condensation fin set up in on condensing plate (2) and be located in condensation chamber (20), condensing plate (2) and/or the condensation fin encapsulates there is phase change material.

2. A condensation module according to claim 1, characterized in that the condensation module further comprises a heat sink (4), the heat sink (4) being arranged on the other side of the base plate (1).

3. A condensation unit according to claim 1, characterized in that the condensation plate (2) comprises a plurality of connected bent sections (21) and two plate sections (22) connected to two of the bent sections (21) at both ends, the two plate sections (22) being parallel to each other and in the same line.

4. A condensation assembly according to claim 3, characterized in that the condensation fins comprise first condensation fins (31), one end of each first condensation fin (31) is connected to the bent section (21), the other end of each first condensation fin extends towards the side of the water outlet hole (11), and the first condensation fins (31) are parallel to the condensation plates (2) with the same tendency and are spaced to form first gaps (201).

5. A condensation unit according to claim 3, characterized in that the condensation fins comprise second condensation fins (32), the second condensation fins (32) are arranged on the bent section (21) and extend towards the side away from the water outlet hole (11), and the second condensation fins (32) are parallel to the condensation plate (2) with the same trend and spaced to form second gaps (202).

6. The condensation assembly according to claim 3, wherein the condensation fins comprise third condensation fins (33), the third condensation fins (33) are arranged on the flat plate section (22) close to the water outlet hole (11), the third condensation fins (33) extend towards a direction away from the water outlet hole (11), and the third condensation fins (33) are arranged at an included angle with the flat plate section (22).

7. A condensation unit according to claim 1, characterized in that a drain pipe (5) is arranged on the surface of the bottom plate (1) remote from the condensation plate (2), one end of the drain pipe (5) is connected to the water outlet hole (11), and the other end is detachably sleeved with a water collecting cover (51).

8. The condensation assembly according to claim 3, wherein two guide plates (12) are symmetrically arranged on both sides of the water outlet hole (11), the guide plates (12) are inclined towards the water outlet hole (11), one end of each of the two guide plates (12) is connected to one of the flat plate sections (22), the other end is spaced to form an air outlet (120), and the air outlet (120) is spaced from the water outlet hole (11).

9. A condensation unit according to any one of claims 1-8, characterized in that the two ends of the outermost condensation plates (2) extend to the upper and lower edges of the bottom plate (1), respectively, and the two ends of the condensation plate (2) located inside are spaced from the upper and lower edges of the bottom plate (1), respectively.

10. A micro steaming and baking device, characterized by comprising a heat radiation fan (6), a micro steaming and baking device body (7) and the condensation component as claimed in any one of claims 1 to 9, wherein the heat radiation fan (6) is installed on the shell of the micro steaming and baking device body (7), the condensation component is installed on a cover plate (61) of the heat radiation fan (6), the cover plate (61) is provided with a vent hole (611) communicated with the condensation cavity (20), the inner container of the micro steaming and baking device body (7) is communicated with the vent hole (611), a heat radiation air duct (8) is formed between the cover plate (61) and the shell of the micro steaming and baking device body (7), the condensation component is positioned in the heat radiation air duct (8), and an air blowing port (62) of the heat radiation fan (6) is arranged towards one side of the condensation component so as to blow air to the condensation component and the heat radiation air duct (8).

11. A micro steaming and baking apparatus according to claim 10, further comprising a communicating pipe (9), wherein both ends of the communicating pipe (9) are respectively communicated with the inner container of the micro steaming and baking apparatus body (7) and the vent hole (611).

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