CN219538078U - A comdenstion water box subassembly and integrated kitchen for culinary art all-in-one - Google Patents

Abstract

The utility model relates to a condensate water box assembly for a cooking integrated machine and an integrated stove, comprising a condensate water box, wherein a first exhaust hole is formed in the bottom wall of the condensate water box, and is connected with an exhaust sleeve extending up and down; the lifting structure is used for driving the exhaust cover plate to move up and down relative to the upper port of the exhaust sleeve; in addition, in the initial state, the upper port of the exhaust sleeve is covered by the exhaust cover plate, and in the state that the temperature of the exhaust gas in the first exhaust hole is increased to a certain value, the lifting structure drives the exhaust cover plate to move upwards relative to the exhaust sleeve, and the upwards moving distance of the exhaust cover plate is in direct proportion to the temperature of the exhaust gas in the first exhaust hole. The utility model can prevent dirt from entering the cooking device through the exhaust sleeve by arranging the exhaust cover plate and can ensure the preheating speed.

Description

A comdenstion water box subassembly and integrated kitchen for culinary art all-in-one

Technical Field

The utility model relates to the field of cooking integrated machines, in particular to a condensate water box assembly for a cooking integrated machine and an integrated kitchen.

Background

The integrated kitchen is a cooking all-in-one machine integrated with a kitchen range, the kitchen range and a cooking device (a steam box, an oven or a steam oven and the like) are generally arranged up and down, and gas exhausted in the working process of the cooking device is uniformly exhausted through the kitchen range. For example, chinese patent application No. CN201910090212.6 (publication No. CN111503672 a) discloses an integrated kitchen range with a cooking device, which comprises a cooking device with a cooking cavity and a kitchen range provided on the cooking device, the kitchen range comprises a kitchen range shell, an air outlet is provided on the cooking cavity, an air inlet and an air outlet are provided on the kitchen range shell, which are in fluid communication with each other, and the air outlet of the cooking cavity is in fluid communication with the air inlet of the kitchen range shell. In the patent, exhaust gas in the cooking cavity is discharged to the kitchen range from bottom to top and is discharged along with oil smoke generated by the kitchen range, so that the integral discharge of the exhaust gas generated by the integrated kitchen range with the cooking device is realized, and the exhaust efficiency is improved.

In order to avoid the gas discharged into the kitchen range from the cooking device from flowing randomly in the kitchen range, and simultaneously in order to avoid condensed water formed in the exhaust process from flowing everywhere in the kitchen range, chinese patent No. ZL202122281685.X (grant publication No. CN 216079989U) discloses an integrated kitchen range, wherein an exhaust box is arranged in a kitchen range shell of the integrated kitchen range, and meanwhile, the condensed water box is embedded in the exhaust box. Thus, the gas discharged into the kitchen range by the cooking device can be concentrated in the exhaust box and discharged outside, thereby avoiding the gas from being mixed in the kitchen range shell, and meanwhile, the formed condensed water is collected in the condensed water box. However, the condensate water box in this patent still has the following problems:

(1) The first exhaust hole in the condensed water box is open, so that external dirt can enter the cooking device through the first exhaust hole, thereby polluting the interior of the cooking device;

(2) The condensed water may accumulate in the condensed water box and, for a long time, may flow into the cooking apparatus through the first exhaust hole, thereby contaminating the cooking apparatus.

Disclosure of Invention

The first technical problem to be solved by the present utility model is to provide a condensate box assembly for a cooking all-in-one machine, which can ensure smooth exhaust of a cooking device and prevent dirt from entering the cooking device.

The second technical problem to be solved by the present utility model is to provide a condensate box assembly for a cooking all-in-one machine, which can ensure smooth exhaust of a cooking device, avoid dirt entering the cooking device, and ensure the preheating speed of the cooking device.

A third technical problem to be solved by the present utility model is to provide a condensate water box assembly for a cooking all-in-one machine, which can achieve self-cleaning of condensate water, in view of the prior art.

A fourth technical problem to be solved by the present utility model is to provide an integrated cooker having the above-mentioned condensate water cartridge assembly, in view of the prior art.

The utility model solves at least one of the technical problems by adopting the following technical proposal: a condensate water box component for a cooking integrated machine comprises a condensate water box, a first exhaust hole is arranged on the bottom wall of the condensate water box, and an exhaust sleeve which extends up and down and is positioned in the condensate water box is connected to the first exhaust hole, and the condensate water box component is characterized by further comprising

The exhaust cover plate is used for covering the upper port of the exhaust sleeve;

the lifting structure is used for driving the exhaust cover plate to move up and down relative to the upper port of the exhaust sleeve;

in addition, in the initial state, the upper port of the exhaust sleeve is covered by the exhaust cover plate, and in the state that the temperature of the exhaust gas in the first exhaust hole is increased to a certain value, the lifting structure drives the exhaust cover plate to move upwards relative to the exhaust sleeve, and the upwards moving distance of the exhaust cover plate is in direct proportion to the temperature of the exhaust gas in the first exhaust hole.

Further, the lifting structure comprises a telescopic rod and a mounting groove for the telescopic rod to pass through and move back and forth, wherein the telescopic rod is fixed on the lower surface of the exhaust cover plate along the lifting direction of the exhaust cover plate, the mounting groove is arranged in the condensate water box along the lifting direction of the exhaust cover plate, and the upper end of the mounting groove is opened for inserting the telescopic rod. Therefore, the up-and-down movement of the exhaust cover plate relative to the upper port of the exhaust sleeve can be realized through the up-and-down movement of the telescopic rod relative to the mounting groove, and further the opening and closing control of the first exhaust hole is realized.

Further, a mounting column is mounted on the inner bottom surface of the condensate water box along the up-down direction on one side of the exhaust sleeve, and the mounting column is hollow to form the mounting groove. Thereby the setting of mounting groove can be realized in the comdenstion water box betterly, and the telescopic link is convenient for realize inserting in the mounting groove and establish.

Further, the telescopic rod is made of expansion with heat and contraction with cold. When the temperature of the telescopic rod is increased to deform, the length of the telescopic rod can be prolonged due to the limitation of the mounting groove, and the exhaust cover plate is jacked up from the upper port of the exhaust sleeve.

Further, the appearance of telescopic link is cylindricly, and the shape of mounting groove and this telescopic link assorted still includes the limit structure who is used for carrying out radial spacing with this telescopic link and mounting groove. Thereby can avoid the telescopic link to take place circumference rotation when deformation because of thermal expansion in the mounting groove, can guarantee the deformation of telescopic link on length better then.

Further, the limiting structure comprises a positioning convex strip which is convexly arranged on one of the outer surface of the telescopic rod or the side surface of the mounting groove along the length direction, and a positioning groove which is concavely arranged on the other one along the length direction and is clamped in by the positioning convex strip. Therefore, the radial limit of the telescopic rod and the mounting groove can be realized by clamping the positioning convex strips on the positioning grooves.

In the utility model, various modes for realizing the thermal expansion of the telescopic rod are provided, for example, the exhaust cover plate is designed to be a heat conducting piece, so that the heat in hot air in the exhaust sleeve can be conducted to the telescopic rod through the exhaust cover plate to deform the telescopic rod, but the heat conducted to the telescopic rod by adopting the mode is effective, and the thermal expansion effect of the telescopic rod is poor. Preferably, the mounting column is a first heating device for heating the telescopic rod, so that the telescopic rod can be directly heated through the mounting column, and the thermal expansion degree of the telescopic rod can better meet the requirement of pushing up the exhaust cover plate.

Further, a first socket for inserting and forming electric connection with the lower end of the mounting column is arranged on the bottom wall of the condensate water box. Thereby be convenient for realize the power supply to the erection column, make it can effectively heat the telescopic link.

Further, the condensed water box is a second heating device. The condensed water box can directly heat condensed water accumulated in the condensed water box, so that the condensed water can be self-cleaned.

Further, the utility model also comprises an exhaust box, wherein the condensed water box is embedded in the exhaust box, a plug is arranged on the bottom surface of the condensed water box, and a second socket for the plug to be inserted into and form electric connection is arranged on the bottom wall of the exhaust box. Thereby realizing the power supply to the condensed water box and effectively heating the condensed water.

Further, the condensing water box is embedded in the exhaust box, a second exhaust hole communicated with the first exhaust hole of the condensing water box is formed in the bottom wall of the exhaust box, a heat dissipation air inlet is formed in one side of the exhaust box, and a notch for exposing the heat dissipation air inlet is formed in the corresponding side wall of the condensing water box. The cold air (relative to the hot air at the first vent) entering from the heat dissipation air inlet can promote condensation of the exhaust gas in the condensate water box, so that the steam content in the exhaust gas is reduced.

Further, the end edge of the exhaust cover plate facing the notch end is arc-shaped. Therefore, the heat energy reduces resistance to air flow blown to the upper port of the exhaust sleeve by the heat radiation air inlet, and is favorable for mixing cold air and hot air, so that steam condensation can be better promoted.

The technical scheme adopted for further solving the fourth technical problem is as follows: an integrated cooking range comprising a cooking device and a range arranged above the cooking device, wherein the cooking device comprises a liner with an exhaust port, and the range comprises a range housing with an exhaust window, characterized in that a condensate water box assembly as described above is arranged in the range housing of the range, a first exhaust hole of the condensate water box is in fluid communication with the exhaust port of the liner, and an upper opening is in fluid communication with the exhaust window on the range housing.

Further, the stove housing of the stove comprises a bottom plate with an upper opening and a panel covered on the opening of the bottom plate, the exhaust window is arranged on the panel, and the condensed water box is arranged on the inner surface of the panel. Thereby enabling better evacuation of the gas.

Compared with the prior art, the utility model has the advantages that: by providing the exhaust cover plate on the upper port of the exhaust sleeve, dirt can be prevented from entering the cooking device through the exhaust sleeve and the first exhaust hole in the initial state (i.e. the cooking device is not in working state). Under the working state of the cooking device, and under the state that the temperature of the discharged gas in the first exhaust hole rises to a certain value, the lifting structure drives the exhaust cover plate to move upwards relative to the exhaust sleeve, the first exhaust hole is opened, and the discharged gas of the cooking device can be smoothly discharged into the condensate water box. And the upward moving distance of the exhaust cover plate is in direct proportion to the temperature of the exhaust gas in the first exhaust hole, so that the actual opening area of the first exhaust hole is smaller in the initial stage of cooking (namely, the preheating stage), thereby ensuring the preheating speed of the cooking device, and the actual opening area of the second exhaust hole is larger in the heating stage, thereby enabling the gas generated in the liner in the cooking process to be smoothly exhausted.

Drawings

FIG. 1 is a schematic view of a part of a cooking stove according to an embodiment of the present utility model;

FIG. 2 is a partially exploded view of a cooking appliance according to an embodiment of the present utility model;

FIG. 3 is a schematic view of a condensate cartridge assembly according to an embodiment of the present utility model;

FIG. 4 is a cross-sectional view of a condensate cartridge assembly in an embodiment of the present utility model;

FIG. 5 is a cross-sectional view of a condensate cartridge assembly in another orientation in an embodiment of the present utility model;

FIG. 6 is an exploded view of a condensate cartridge assembly in accordance with an embodiment of the present utility model;

FIG. 7 is a schematic view of the structure of FIG. 6 in another direction;

fig. 8 is a partially exploded view of a condensate box according to an embodiment of the present utility model.

Detailed Description

The utility model is described in further detail below with reference to the embodiments of the drawings.

In the description of the present utility model, it should be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", "axial", "radial", "circumferential", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings are merely for purposes of describing the present utility model and simplifying the description, and do not indicate or imply that the device or element being referred to must have a specific orientation, be configured and operated in a specific orientation, and because the disclosed embodiments of the present utility model may be arranged in different orientations, these directional terms are merely for illustration and should not be construed as limitations, such as "upper", "lower" are not necessarily limited to orientations opposite or coincident with the direction of gravity. Furthermore, features defining "first", "second" may include one or more such features, either explicitly or implicitly.

As shown in fig. 1 to 8, an integrated cooker includes a cooking device (not shown) and a cooker (not shown) disposed above the cooking device, wherein the cooking device includes a liner having an exhaust port, and the cooker includes a cooker case including a bottom plate having an upper opening and a panel 4 covering the opening of the bottom plate, an exhaust window 41 is opened at a rear side of the panel 4, and an exhaust grill 411 is enclosed in the exhaust window 41.

Further, a condensate box assembly 10 is provided in the above-described range housing, and the condensate box assembly 10 includes an exhaust box 2 and a condensate box 1 fitted in the exhaust box 2. Wherein, the exhaust box 2 is covered on the lower surface of the panel 4 along the left-right direction and is arranged opposite to the exhaust window 41. A second vent hole 22 is formed in the bottom wall of the vent box 2, the second vent hole 22 is communicated with the vent hole of the inner container through a vent pipe (not shown), a first vent hole 11 is formed in the bottom wall of the condensate box 1, the first vent hole 11 and the second vent hole 22 are vertically opposite to each other in the installation state, and a vent joint 16 of the first vent hole 11 positioned on the bottom surface of the condensate box 1 is inserted into the second vent hole 22, as shown in fig. 4.

Further, as shown in fig. 4, a vent sleeve 111 extending vertically and located in the condensate box 1 is connected to the first vent hole 11. In addition, the condensate box assembly 10 further includes an exhaust cover plate 3 and a lifting structure 100, wherein the exhaust cover plate 3 is used for covering the upper port of the exhaust sleeve 111, and the lifting structure 100 is used for driving the exhaust cover plate 3 to move up and down relative to the upper port of the exhaust sleeve 111. In addition, in the initial state, when the exhaust cover plate 3 covers the upper port of the exhaust sleeve 111 and the temperature of the exhaust gas in the first exhaust hole 11 rises to a certain value, the lifting structure 100 drives the exhaust cover plate 3 to move upwards relative to the exhaust sleeve 111, and the upwards moving distance of the exhaust cover plate 3 is in direct proportion to the temperature of the exhaust gas in the first exhaust hole 11, that is, in a certain temperature range, the higher the temperature rise of the exhaust gas, the larger the upwards moving distance of the exhaust cover plate 3, the smaller the temperature rise, and the smaller the upwards moving distance of the exhaust cover plate 3.

The present utility model prevents dirt from entering the cooking apparatus through the exhaust sleeve 111 from the first exhaust hole 11 in an initial state (i.e., in an inactive state of the cooking apparatus) by covering the upper port of the exhaust sleeve 111 with the exhaust cover 3. In the operating state of the cooking apparatus, and in a state in which the temperature of the exhaust gas in the first exhaust hole 11 is raised to a certain value, the lifting structure 100 drives the exhaust cover plate 3 to move upward relative to the exhaust sleeve 111, the first exhaust hole 11 is opened, and the exhaust gas of the cooking apparatus can be smoothly discharged into the condensate box 1. In addition, the upward moving distance of the exhaust cover plate 3 is in direct proportion to the temperature of the exhaust gas in the first exhaust hole 11, so that the temperature of the exhaust gas in the first exhaust hole 11 is relatively low in the initial stage of cooking (namely, the preheating stage), the actual opening area of the first exhaust hole 11 is small, the preheating speed of the cooking device is ensured, the temperature of the interior of the inner container is relatively high in the heating stage, the temperature of the exhaust gas in the first exhaust hole 11 is relatively high, and the actual opening area of the second exhaust hole 22 is large, so that the gas generated in the inner container in the cooking process can be smoothly discharged.

Further, the lifting structure 100 includes a telescopic rod 12 and a mounting groove 130 through which the telescopic rod 12 is inserted and moved back and forth. Wherein the telescopic rod 12 is fixed to the lower surface of the drain cover 3 in the lifting direction of the drain cover 3, the installation groove 130 is opened in the condensate box 1 in the lifting direction of the drain cover 3, and the upper end of the installation groove 130 is opened for inserting the telescopic rod 12. In this way, the up-and-down movement of the exhaust cover plate 3 relative to the upper port of the exhaust sleeve 111 can be realized by the up-and-down movement of the telescopic rod 12 relative to the mounting groove 130, so that the opening and closing control of the first exhaust hole 11 is realized. In order to provide the mounting groove 130 in the condensate water tank 1, a mounting post 13 is vertically mounted on the inner bottom surface of the condensate water tank 1 at one side of the exhaust sleeve 111, and the mounting post 13 is hollow to form the mounting groove 130, so that the telescopic rod 12 is conveniently inserted into the mounting groove 130.

Further, there are various ways of realizing the up-and-down movement of the telescopic rod 12, for example, a mechanical structure is adopted to control the up-and-down expansion of the telescopic rod 12 through an electric control program, specifically, for example, an expansion motor and the like. In this embodiment, the expansion link 12 is preferably made of a heat-expandable and cold-shrinkable material (in this embodiment, a polymer composite material with good heat expansion such as polytetrafluoroethylene is specifically selected). When the temperature of the telescopic rod 12 increases and deforms in this way, the length of the telescopic rod 12 can be increased due to the restriction of the installation groove 130, and the exhaust cover plate 3 can be pushed away from the upper port of the exhaust sleeve 111.

Preferably, the outer shape of the telescopic rod 12 is cylindrical, and the shape of the mounting groove 130 is matched with that of the telescopic rod 12, and the telescopic rod 12 and the mounting groove 130 are further provided with a limiting structure for radially limiting. Thereby, the expansion link 12 can be prevented from rotating circumferentially when deformed by thermal expansion in the mounting groove 130, and the deformation of the expansion link 12 in length can be better ensured. Specifically, the above-mentioned limit structure includes a positioning protrusion 121 protruding in the longitudinal direction on one of the outer surface of the telescopic link 12 and the side surface of the mounting groove 130, and a positioning groove 1301 recessed in the longitudinal direction on the other and into which the above-mentioned positioning protrusion 121 is engaged. Thus, the positioning protruding strips 121 are clamped in the positioning grooves 1301, so that radial limiting of the telescopic rod 12 and the mounting groove 130 can be achieved. In this embodiment, specifically, the positioning protrusion 121 is provided on the telescopic link 12, and the positioning groove 1301 is provided in the mounting groove 130.

Further, there are various ways of realizing thermal expansion of the telescopic rod 12 in the present utility model, for example, the exhaust cover plate 3 is designed as a heat conducting member, so that heat in hot air in the exhaust sleeve 111 can be conducted to the telescopic rod 12 through the exhaust cover plate 3 to deform the telescopic rod 12, but the heat conducted to the telescopic rod 12 in this way is effective, and the thermal expansion effect of the telescopic rod 12 is poor. Preferably, the mounting post 13 is a first heating device for heating the telescopic rod 12, so that the telescopic rod 12 can be directly heated through the mounting post 13, and the thermal expansion degree of the telescopic rod 12 can better meet the requirement of pushing up the exhaust cover plate 3. Still further, in order to facilitate the supply of electricity to the mounting post 13 so that it can effectively heat the telescopic rod 12, the bottom wall of the above-mentioned condensate water cartridge 1 is provided with a first socket 14 into which the lower end of the mounting post 13 is inserted and which forms an electrical connection. In this embodiment, the mounting posts 13 are made of metal (e.g., copper).

Further, the above-described condensate water cartridge 1 in this embodiment is a second heating device. In this way, the condensation water box 1 can directly heat the condensed water accumulated in the condensation water box, and self-cleaning of the condensed water is realized. In order to supply power to the condensate water tank 1 and to heat the condensate water efficiently, a plug 15 is provided on the bottom surface of the condensate water tank 1, and a second socket 21 into which the plug 15 is inserted and electrically connected is provided on the bottom wall of the exhaust tank 2.

In this embodiment, the front side wall of the exhaust box 2 is provided with a heat dissipation air inlet 23, and the front side wall of the condensation water box 1 is provided with a notch 17 from top to bottom for exposing the heat dissipation air inlet 23. The cold air (relative to the hot air at the first exhaust hole 11) entering from the heat radiation air inlet 23 can promote the condensation of the external exhaust gas in the condensate water box 1, so that the steam content in the external exhaust gas is reduced, and the external exhaust gas of the heat radiation channel inside the kitchen range can also pass through the exhaust box 2 and be exhausted from the exhaust window 41 on the panel 4. Preferably, the exhaust cover 3 has an arc shape toward an end edge (i.e., a front end edge) of the notch 17. So that the heat energy reduces resistance to the air flow blown from the heat radiation air inlet 23 to the upper port of the exhaust sleeve 111, and is favorable for mixing cold air and hot air, thereby better promoting steam condensation.

In this embodiment, two pairs of the first exhaust holes 11 are arranged at a left-right interval, the exhaust sleeves 111 are respectively arranged on each first exhaust hole 11, correspondingly, the exhaust cover plates 3 are two and are in one-to-one correspondence with the exhaust sleeves 111, and the lifting structures 100 are also two and are in one-to-one correspondence with the exhaust cover plates 3.

The term "fluid communication" as used herein refers to a spatial positional relationship between two members or portions, hereinafter collectively referred to as a first portion and a second portion, respectively, that is, a fluid gas, a liquid, or a mixture of both can flow along a flow path from the first portion to the second portion, or can be directly communicated between the first portion and the second portion, or can be indirectly communicated between the first portion and the second portion through at least one third member, which may be a fluid passage such as a pipe, a channel, a conduit, a flow guide, a hole, a groove, or the like, or can be a chamber allowing a fluid to flow therethrough, or a combination thereof.

Claims (14)

1. A condensate water box assembly for a cooking integrated machine, comprising a condensate water box (1), wherein a first exhaust hole (11) is arranged on the bottom wall of the condensate water box (1), and the first exhaust hole (11) is connected with an exhaust sleeve (111) which extends up and down and is positioned in the condensate water box (1), characterized in that the condensate water box assembly further comprises

An exhaust cover plate (3) for covering the upper port of the exhaust sleeve (111);

the lifting structure (100) is used for driving the exhaust cover plate (3) to move up and down relative to the upper port of the exhaust sleeve (111);

in the initial state, the upper port of the exhaust sleeve (111) is covered by the exhaust cover plate (3), the exhaust cover plate (3) is driven by the lifting structure (100) to move upwards relative to the exhaust sleeve (111) in a state that the temperature of the exhaust gas in the first exhaust hole (11) rises to a certain value, and the upward moving distance of the exhaust cover plate (3) is in direct proportion to the temperature of the exhaust gas in the first exhaust hole (11).

2. The condensate water box assembly for a cooking all-in-one machine according to claim 1, wherein the elevation structure (100) comprises a telescopic rod (12) and a mounting groove (130) through which the telescopic rod (12) is penetrated and moved back and forth, wherein the telescopic rod (12) is fixed on a lower surface of the exhaust cover plate (3) along an elevation direction of the exhaust cover plate (3), the mounting groove (130) is opened in the condensate water box (1) along the elevation direction of the exhaust cover plate (3), and an upper end opening of the mounting groove (130) is inserted with the telescopic rod (12).

3. The condensate water cartridge assembly for a cooking all-in-one machine as claimed in claim 2, wherein a mounting post (13) is installed on an inner bottom surface of the condensate water cartridge (1) in an up-down direction at one side of the exhaust sleeve (111), and the mounting post (13) is hollow to form the mounting groove (130).

4. A condensation water box assembly for a cooking all-in-one machine according to claim 3, wherein said telescopic rod (12) is made of heat-expansion and cold-contraction material.

5. The water condensation box assembly for a cooking all-in-one machine according to claim 4, wherein the telescopic rod (12) has a cylindrical shape and the mounting groove (130) is shaped to match the telescopic rod (12), and further comprising a limiting structure for radially limiting the telescopic rod (12) and the mounting groove (130).

6. The condensate water cartridge assembly for a cooking all-in-one machine as claimed in claim 5, wherein the limit structure comprises a positioning protrusion (121) protruding in a length direction on one of an outer surface of the telescopic rod (12) or a side surface of the installation groove (130), and a positioning groove (1301) recessed in a length direction on the other and into which the positioning protrusion (121) is caught.

7. The condensation water box assembly for a cooking all-in-one machine according to any one of claims 4 to 6, wherein said mounting post (13) is a first heating means for heating the telescopic rod (12).

8. The condensation water box assembly for a cooking all-in-one machine according to claim 7, characterized in that the bottom wall of the condensation water box (1) is provided with a first socket (14) for inserting and forming an electrical connection with the lower end of the mounting post (13).

9. The condensation water box assembly for a cooking all-in-one machine according to any one of claims 1 to 6, wherein the condensation water box (1) is a second heating device.

10. The condensate box assembly for a cooking all-in-one machine as claimed in claim 9, further comprising an exhaust box (2), wherein the condensate box (1) is embedded in the exhaust box (2), wherein a plug (15) is provided on a bottom surface of the condensate box (1), and wherein a second socket (21) for inserting and electrically connecting the plug (15) is provided on a bottom wall of the exhaust box (2).

11. The condensate water box assembly for a cooking all-in-one machine as claimed in any one of claims 1 to 6, further comprising an exhaust box (2), wherein the condensate water box (1) is embedded in the exhaust box (2), a second exhaust hole (22) communicated with a first exhaust hole (11) of the condensate water box (1) is formed in a bottom wall of the exhaust box (2), a heat dissipation air inlet (23) is formed in one side of the exhaust box (2), and a notch (17) for exposing the heat dissipation air inlet (23) is formed in a corresponding side wall of the condensate water box (1).

12. The condensate water cartridge assembly for a cooking all-in-one machine as claimed in claim 11, wherein an end edge of the vent cover plate (3) facing the end of the notch (17) is arc-shaped.

13. An integrated cooking stove comprising a cooking device and a stove arranged above the cooking device, wherein the cooking device comprises an inner container with an exhaust port, and the stove comprises a stove housing on which an exhaust window (41) is arranged, characterized in that a condensate water box assembly (10) according to any one of claims 1-12 is arranged in the stove housing of the stove, a first exhaust port (11) of the condensate water box (1) is in fluid communication with the exhaust port of the inner container, and an upper opening is in fluid communication with the exhaust window (41) on the stove housing.

14. The integrated hob according to claim 13, characterized in, that the hob shell of the hob comprises a bottom plate with an upper opening and a panel (4) covering the opening of the bottom plate, the exhaust window (41) being open on the panel (4), and the condensate water box (1) being arranged on the inner surface of the panel (4).