CN115251716A - Instant heating assembly for food processor and food processor - Google Patents

Abstract

The application discloses cooking machine is with instant heating subassembly and cooking machine. The cooking machine is with instant heating subassembly includes instant heating body, trachea, water pipe and heating member. The air pipe and the water pipe are both arranged through the instant heating body and are respectively communicated with the outside of the instant heating body. The heating element heats the gas in the gas pipe to generate high-temperature gas under the condition of electrifying and flowing the gas in the gas pipe; when the power is turned on and water flows through the water pipe, the water in the water pipe is heated to generate high-temperature liquid and/or high-temperature steam. So set up, the subassembly that heats promptly provides at least one of high-temperature gas, high-temperature liquid and high-temperature steam, uses in a flexible way, satisfies the demand of different application scenes, and user experience feels good. Moreover, the high-temperature gas and/or the high-temperature steam can be used for heating the food in the juice receiving cup, the food can be quickly heated, and in addition, the functions of generating the high-temperature gas and the high-temperature steam and/or the high-temperature liquid are integrated, namely the structure of the heating component is simple, the volume is small, and the cost is low.

Description

Instant heating assembly for food processor and food processor

Technical Field

The application relates to a small household electrical appliance technical field especially relates to a cooking machine is with instant heating subassembly and cooking machine.

Background

The food processer comprises a host machine component, a water tank component, a stirring cup component and a juice receiving cup component. The water tank assembly, the stirring cup assembly and the juice receiving cup assembly are all assembled on the host machine assembly. The stirring cup assembly comprises a stirring cup. The water tank assembly supplies water into the stirring cup. In the blender cup, the comminuted food and water are combined into a slurry (also referred to as juice in some cases). The juice cup assembly includes a juice cup (also referred to in some cases as a cook cup). With the juice receiving cup in communication with the blender cup, the slurry is able to flow into the juice receiving cup. In some cases, one needs to heat the slurry in the juice receiving cup.

However, the existing device for heating food in the juice receiving cup is slow in heating and has few application scenes.

Disclosure of Invention

The application discloses cooking machine is with instant heating subassembly and cooking machine. The instant heating assembly can enable the food processor to heat food quickly, has multiple application scenes and is low in cost.

To achieve the above purpose, the embodiments of the present application disclose a material handling machine instant heating assembly. The cooking machine is with instant heating subassembly includes instant heating body, trachea, water pipe and heating member. The air pipe penetrates through the instant heating body and is communicated with the outside of the instant heating body; the water pipe penetrates through the instant heating body and is communicated with the outside of the instant heating body; the heating element heats the gas in the gas pipe to generate high-temperature gas under the condition of electrifying and flowing gas in the gas pipe; heating the water in the water pipe to generate high-temperature liquid and/or high-temperature steam under the condition of electrifying and water flowing in the water pipe. According to the arrangement, the heating element independently provides high-temperature gas under the conditions of electrification, gas flowing in the gas pipe and no water in the water pipe; providing high-temperature liquid and/or high-temperature steam under the conditions of electrifying, no gas in the gas pipe and water flowing in the water pipe; under the circumstances that circular telegram and trachea in-flow have gas and water pipe in-flow have water, provide high-temperature gas, high-temperature liquid and high-temperature steam simultaneously, consequently, the instant heating subassembly can provide at least one of high-temperature gas, high-temperature liquid and high-temperature steam, uses in a flexible way, satisfies the demand of different application scenarios, and user experience feels good. Moreover, the high temperature gas and/or steam can be used to heat the food in the juice cup, which can heat the food quickly, and particularly, in the case of heating the food with the high temperature gas, the food can not be layered and burnt, and the juice cup assembly does not need to be provided with a stirring system and the like. In addition, the functions of generating high-temperature gas and high-temperature steam and/or high-temperature liquid are integrated, so that the instant heating assembly is simple in structure, small in size and low in cost.

Optionally, the heating element is disposed between the air pipe and the water pipe, and the heating element, the air pipe and the water pipe are bent back and forth, stacked and spaced; or the heating element is arranged between the air pipe and the water pipe, and the heating element, the water pipe and the air pipe are bent back and forth in the same plane; or the heating element is arranged between the air pipe and the water pipe, and the water pipe and the heating element are both screwed around the air pipe; or, the heating member set up in the trachea with between the water pipe, the trachea with the heating member all winds the water pipe spiral. So set up, because the water pipe trachea and heating member make a round trip to buckle, range upon range of and be separated by the setting, like this, be favorable to reducing the width of instant heating subassembly, simultaneously, heating member, trachea and water pipe all make a round trip to buckle and can also provide great heating part, and heating effect is good. Because the water pipe trachea and heating member make a round trip to buckle in the coplanar, like this, be favorable to reducing the height of instant heating subassembly, simultaneously, heating member, trachea and water pipe all make a round trip to buckle and can also provide great heating part, and heating effect is good. Under the condition that heating member and water pipe all wind the trachea spiral, the trachea is closer to the center of heating member, and is effectual to the heating of gas. In addition, through with the heating member with the water pipe sets up to helical structure, not only can provide great heating area, and heating effect is good, but also can make hot subassembly promptly cylindricly, is favorable to reducing the width and the height of hot subassembly promptly, is applicable to and can place the scene of the hot subassembly promptly of columnar. Under the condition that the air pipe and the heating element are wound around the water pipe in a spiral mode, the water pipe is close to the center of the heating element, and the water heating effect is good. In addition, through with the heating member with the trachea sets up to helical structure, not only can provide great heating area, and heating effect is good, but also can make hot subassembly promptly cylindricly, is favorable to reducing the width and the height of hot subassembly promptly, is applicable to and can place the scene of the hot subassembly promptly of columnar.

Optionally, the distance between the outer wall of the heating element and the outer wall of the water pipe is D2, D2 is larger than or equal to 1 and smaller than or equal to 15mm, and/or the inner diameter range of the water pipe is R2, R2 is larger than or equal to 1 and smaller than or equal to 10mm. So set up, D2 can make the heating effect better in above-mentioned scope, because the distance can make the heating member can't better heat and make the speed of heating water slow for too big, whole time is long, and the distance is too little makes the preparation complicated, for example, in some embodiments, also can make water pressure be too little be difficult to open water check valve and make high temperature liquid be difficult to get into the stirring cup. The internal diameter R2 of the water pipe is in the range, the heating element can heat water in the water pipe effectively, the internal diameter is too large, the heat of the heating element cannot heat water enough, the temperature of high-temperature liquid is not high enough, the water pipe is too small, the manufacturing process of the water pipe is complex, in addition, in some embodiments, the water pipe is too small, the water pressure is relatively small, and the control valve (such as a one-way valve) between the stirring cup and the instant heating component is not easy to conduct.

Optionally, the distance between the outer wall of the heating element and the outer wall of the air pipe is D1, D1 is greater than or equal to 1 and is less than or equal to 15mm, and/or the inner diameter range of the air pipe is greater than or equal to 1 and is less than or equal to R1 and is less than or equal to 6mm. So set up, D1 can be so that the heating effect is better in above-mentioned scope, because the too big heat that can make the heating member can't be better of distance makes heated gas's speed slow, and whole heating time is long, and the distance is too little makes heating member and trachea preparation complicated, in addition, in some embodiments, also can make atmospheric pressure be too little be difficult to open the water check valve and make high temperature liquid be difficult to get into the stirring cup. The inner diameter R1 of the air pipe is too large, so that the heating speed is slow, and in some embodiments, the cross section area of the air pipe is larger due to the too large inner diameter R1 of the air pipe, so that the gas check valve between the juice receiving cup and the instant heating assembly cannot be communicated due to the small air pressure in the air pipe; too small an internal diameter of the air tube can complicate the manufacturing process and can cause hot gases to be flushed out after the juice cup assembly is removed, i.e., the thermal buffer within the thermal assembly, causing scalding.

Optionally, the terminal of the heating element is located at a first side of the instant heating body, the water inlet and the water outlet of the water pipe are located at a side or opposite to the first side, and/or the air inlet and the air outlet of the air pipe are located at a side or opposite to the first side. So set up, no matter water inlet and delivery port are located the side or the face of first side, still air inlet and gas outlet are located the side or the face of first side can both make air inlet and gas outlet to and, water inlet and delivery port are kept away from wiring end (live wire wiring end and zero line wiring end), avoid leaking and lead to electric leakage etc..

Optionally, the cooking machine includes the control panel with instant heating subassembly, the water pipe is including stretching out the delivery port of instant heating body, the trachea is including stretching out the gas outlet of instant heating body, the gas outlet with at least one of delivery port is provided with temperature sensor, the control panel basis temperature sensor's temperature value control heating member heating. So set up, improve high temperature gas high temperature steam with the accuracy degree of heating temperature of high temperature liquid is surpassing and is predetermineeing under the condition of temperature, can stop heating, improves the security.

In another aspect, an embodiment of the present application discloses a food processor. The food processor comprises a host machine component, a juice receiving cup component, a gas input component and an instant heating component for any one of the food processors, wherein the host machine component comprises a control board which controls the heating element to be electrified; the water tank assembly supplies water to the water pipes to generate the high-temperature liquid and/or high-temperature steam; the juice receiving cup assembly is arranged on the host machine assembly and comprises a juice receiving cup; the gas input assembly inputs gas to the gas pipe to generate the high-temperature gas, and the control board controls the high-temperature gas to be conveyed to food in the juice receiving cup according to a cooking program to heat the food. So set up, because this application produces high-temperature gas through instant heating subassembly, high-temperature liquid and/or high-temperature steam, can provide high-temperature liquid for the cooking machine, high-temperature gas and at least one of high-temperature steam, high-temperature gas or high-temperature steam can get into and connect in the juice cup, the heating is discharged after receiving the food in the juice cup (such as juice or thick liquid), it is fast to heat food, and is special, under the condition that adopts the high-temperature gas heating, high-temperature gas passes food in-process and can make food take place the motion, and then, play the effect of stirring, therefore, can ensure not burnt, not layering, also need not set up mixing system in connecing the juice cup. In addition, the functions of generating high-temperature gas and high-temperature steam and/or high-temperature liquid are integrated, so that the instant heating assembly is simple in structure, small in size and low in cost. Finally, some current methods heat the water in the water tank assembly to obtain water vapor, and heat the food in the juice receiving cup by the water vapor, which has the disadvantages that the water vapor becomes liquid after being cooled to raise the liquid level of the food, the water vapor becomes liquid to dilute the food (such as soybean milk) and affect the taste, and in addition, the water in the water tank of the water tank assembly is consumed. And this application connects the food in the juice cup through high-temperature gas heating, can not make the liquid level of food rise, can not dilute food and influence food taste. High-temperature gas's transmission line is independent with high-temperature liquid's pipeline, can not make high-temperature gas become vapor, can not consume the water in the water tank of water tank set spare, can not dilute food, also can not make the liquid level of food rise, and in addition, high-temperature gas's temperature is higher than the temperature of vapor, and the heating that can be faster connects the food in the juice cup.

Optionally, the cooking machine including assemble in the stirring cup subassembly of host computer subassembly, the stirring cup subassembly is including the stirring cup, tracheal air inlet connect in gas input assembly, tracheal gas outlet connect in the stirring cup with connect the juice cup, the control panel is still according to culinary art program control high temperature gas carry extremely the stirring cup is with the stoving the stirring cup. So set up, dry by the fire through the hot gas stirring cup can play the effect of stoving, disinfecting, improves user experience, moreover, utilizes the hot gas that the thermal unit produced carries out the hot stoving to the stirring cup promptly for the thermal unit can realize more functions promptly, and the cooking machine need not set up the correlation structure who is used for the hot stirring cup that dries by the fire again, simplifies the structure of cooking machine in other words and makes the simple structure and the compactness of cooking machine.

Optionally, the food processor comprises a gas three-way valve, the juice receiving cup and the stirring cup are connected to the gas pipe through the gas three-way valve, and the high-temperature gas enters the juice receiving cup or the stirring cup by switching the gas three-way valve; or, the cooking machine is including connecing juice two-way valve and stirring two-way valve, connect the juice cup to pass through connect the juice two-way valve connect in tracheal gas outlet, the stirring cup passes through the stirring two-way valve connect in tracheal gas outlet, through connect the break-make state of juice two-way valve with the combination of the break-make state of stirring two-way valve is in order to control high temperature gas gets into connect juice cup and/or stirring cup. So set up, realize high-temperature gas flow direction stirring cup through switching gas three-way valve, perhaps, the flow direction connects the juice cup to simple structure has realized high-temperature gas's transport, and control is convenient, and the cooking machine can be applicable to different application scenes, and user experience is good. Through setting up stirring two-way valve with connect the juice two-way valve and realize stirring cup, gas input subassembly and tracheal intercommunication with simple structure relatively, perhaps, connect juice cup, gas input subassembly and tracheal intercommunication, in addition, through control connect juice two-way valve and stirring two-way valve, can also be when connecing the food heating in the juice cup, heat to the stirring cup and dry by the fire, saved whole flow and accomplished the time, improved user experience more.

Optionally, the juice receiving cup comprises a temperature measuring element arranged at the bottom of the juice receiving cup, and the temperature measuring element measures the temperature of the juice receiving cup or the food in the juice receiving cup to obtain a temperature value; the juice receiving cup assembly comprises a wireless transmitting module, and the wireless transmitting module transmits the temperature value outwards; the host computer subassembly includes wireless receiving module, wireless receiving module receives the temperature value, the control panel according to the temperature value control the gas input subassembly stops to carry gas and/or the heating member stops to heat gas. According to the arrangement, the containing cavity is formed by hermetically connecting the cup base and the juice receiving cup, the juice receiving cup assembly is communicated with the control panel through the wireless transmitting module and the wireless receiving module to realize related control, so that the juice receiving cup assembly can be made into an integral waterproof structure to facilitate washing of a dish washing machine and the like.

Optionally, the food processor includes a stirring cup assembly, the host assembly includes a host housing, the host housing includes a housing main body and a placement platform located at the bottom of the housing main body, the instant heating assembly and the gas input assembly are assembled in the housing main body, and the control board and a motor for driving a stirring knife of the stirring cup assembly to rotate are assembled in the housing main body; the juice receiving cup assembly is detachably assembled on the placing platform, and the wireless receiving module is arranged in the placing platform. So set up, wireless receiving module is closer to wireless transmitting module and keeps away from the parts of easy interfering signal transmission such as the coil of control panel or motor, signal transmission is more stable, in addition, wireless receiving module sets up in place the platform, place the platform's surface or the surface that does not have the interface, or only one the disk seat, and only there is the plug to stretch out from the cup on connecing the juice cup subassembly, and constitutes one-way switch-on (only just switch-on under the condition of equipment) with the disk seat, therefore above-mentioned structure can not lead to phenomenons such as electric leakage because of remaining thick liquid drips on place the platform, and the security is high.

Optionally, the gas input assembly inputs external gas into the juice receiving cup when the heating element is in an unheated state, so as to cool the food heated in the juice receiving cup. So set up, pass through the external gas connect the food in the juice cup to reach the purpose of cooling food, the inside back of external gas entering food is discharged from the juice mouth that connects the juice cup, and the cooling food is faster, connects the juice cup subassembly and also need not set up cooling part or cooking machine and need not set up cooling part, connects the simple structure of juice cup subassembly or cooking machine.

Optionally, the food processor includes a stirring cup assembly, and the stirring cup assembly is assembled to the host assembly and includes a stirring cup; the stirring cup is connected with the water pipe through a control valve, the high-temperature liquid flows into the stirring cup through controlling the control valve, the high-temperature liquid and food materials in the stirring cup form slurry, and the slurry flows into the juice receiving cup; or, the cooking machine includes water three-way valve and drink mouth promptly, the stirring cup with drink mouth promptly all through water three-way valve connects in the water pipe, through switching water three-way valve is in order to control high temperature liquid flows in the stirring cup or flow in drink mouth promptly, the high temperature liquid that flows in the stirring cup constitutes the thick liquid with the edible material in the stirring cup, the thick liquid flows in connect the juice cup. According to the arrangement, the high-temperature liquid and the crushed food materials form the slurry, so that the pulping time can be shortened, and in addition, for food such as soybean milk, the high-temperature liquid is adopted for pulping, so that the fishy smell of the food, such as the beany smell, can be removed; finally, utilize the instant heating subassembly produces high temperature liquid, and provide the stirring cup with high temperature liquid, expand the application of instant heating subassembly, the cooking machine need not set up the relevant part that adds hot water again, and then makes simple structure, the compactness of cooking machine, is favorable to the cooking machine miniaturization. In addition, through the water three-way valve will stir the cup and drink the mouth promptly and connect in the water pipe, the beneficial effect of this kind of embodiment has the beneficial effect under only providing the high temperature liquid condition at least, in addition, the cooking machine can also provide the high temperature liquid (also can say hot water) of drinking promptly, and the function is more complete, uses more extensively, and user experience is better.

Optionally, the juice receiving cup comprises a juice receiving cup bottom and a juice receiving port communicating the inside and the outside of the juice receiving cup, and an air inlet assembly is arranged between the juice receiving cup bottom and the host machine assembly, so that the high-temperature gas enters the juice receiving cup from the juice receiving cup bottom and then is discharged from the juice receiving port; or the juice receiving cup comprises a juice receiving port communicated with the inside and the outside of the juice receiving cup, and an air inlet assembly is arranged between the side part of the juice receiving cup and the main machine assembly, so that the high-temperature gas enters the juice receiving cup from the side part of the juice receiving cup. So set up, above-mentioned two kinds of embodiments can both reach the aforesaid heating fast, not layering, can not make food liquid level rise etc.. Compared with the prior art, the high-temperature gas can be longer in moving path by feeding gas from the bottom of the juice receiving cup, the slurry can move more easily, and the heating effect is relatively better.

Drawings

Fig. 1 is an exploded view of a food processor of the first embodiment of the present disclosure;

fig. 2 is a cross-sectional view of the food processor shown in fig. 1;

fig. 3 is an exploded view of a second food processor of the present application;

fig. 4 is a cross-sectional view of the food processor shown in fig. 3;

FIG. 5 is a first schematic view of the blending cup assembly, the water tank assembly, the instant heating assembly, and the juice receiving cup assembly connected together;

FIG. 6 is a schematic diagram corresponding to FIG. 5;

fig. 7 is a flow chart of the operation of the food processor using the connection relationship shown in fig. 5;

FIG. 8 is a second schematic view of the blending cup assembly, water tank assembly, instant heating assembly and juice receiving cup assembly connected;

FIG. 9 is a schematic diagram corresponding to FIG. 8;

fig. 10 is a flow chart of the operation of the food processor using the connection relationship shown in fig. 8;

FIG. 11 is a third schematic view of the blending cup assembly, water tank assembly, instant heating assembly and juice receiving cup assembly connected;

FIG. 12 is a schematic diagram corresponding to FIG. 11;

fig. 13 is a flow chart of the operation of the food processor using the connection relationship shown in fig. 11;

FIG. 14 is a schematic view of a first instant heating assembly of the present application;

FIG. 15 is a cross-sectional view of a first instant heating assembly of the present application;

FIG. 16 is a perspective view of the heating element, gas tube and water tube arrangement of the first instant heating assembly of the present application;

FIG. 17 is a schematic view of a second instant heating assembly of the present application;

FIG. 18 is a cross-sectional view of a second instant heating assembly of the present application;

FIG. 19 is a perspective view of the heating element, gas tube and water tube arrangement of the second instant heating assembly of the present application;

FIG. 20 is another schematic illustration of the heating element, gas line and water line arrangement of the present application;

FIG. 21 is a schematic view of a trachea tube according to the present application.

Detailed Description

Reference will now be made in detail to the exemplary embodiments, examples of which are illustrated in the accompanying drawings. When the following description refers to the accompanying drawings, like numbers in different drawings represent the same or similar elements unless otherwise indicated. The embodiments described in the following exemplary embodiments do not represent all embodiments consistent with the present application. Rather, they are merely examples of devices consistent with certain aspects of the present application, as detailed in the appended claims.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the application. Unless otherwise defined, technical or scientific terms used herein shall have the ordinary meaning as understood by one of ordinary skill in the art to which this application belongs. The use of the terms "a" or "an" and the like in the description and in the claims of this application do not denote a limitation of quantity, but rather denote the presence of at least one. The word "comprising" or "comprises", and the like, means that the element or item listed as preceding "comprising" or "includes" covers the element or item listed as following "comprising" or "includes" and its equivalents, and does not exclude other elements or items. The terms "connected" or "coupled" and the like are not restricted to physical or mechanical connections, but may include electrical connections, whether direct or indirect. "plurality" includes two, and is equivalent to at least two. As used in this specification and the appended claims, the singular forms "a", "an", and "the" are intended to include the plural forms as well, unless the context clearly indicates otherwise. It should also be understood that the term "and/or" as used herein refers to and encompasses any and all possible combinations of one or more of the associated listed items.

Referring to fig. 1 and fig. 2 in combination with fig. 5, fig. 8 and fig. 11, an embodiment of the present application discloses a food processor. The cooking machine comprises a main machine component 1, a water tank component 2, a heating component 3, a stirring cup component 4, a juice receiving cup component 5 and a gas input component 6. The function and the corresponding configuration of the components are described as follows:

the host assembly 1 serves as a mounting carrier for the water tank assembly 2, i.e., the heating assembly 3, the stirring cup assembly 4, the juice receiving cup assembly 5 and the gas input assembly 6, and is not limited in structure and can be assembled, and in various embodiments of the present application, the host assembly 1 includes a host housing 10. In the embodiment of the present application, the water tank assembly 2, the blender cup assembly 4 and the juice receiving cup assembly 5 are assembled to the main body housing 10 and are located outside the main body assembly 1, i.e. the heat assembly 3 and the gas input assembly 6 are assembled to the main body housing 10, of course, the components connected between the above components, the control board and the like can also be assembled to the main body housing 10. The control panel is used for controlling the cooking machine to realize relevant functions, for example, stirring function, control that instant heating subassembly 3 heats gas in order to produce high-temperature gas, control that instant heating subassembly 3 produces high-temperature liquid or high-temperature steam, control gaseous input assembly 6 delivery gas, control water tank set spare 2 and supply water to instant heating subassembly 3 etc.. Of course, in other embodiments, the above components and/or related functions of the food processor may not be implemented by the same control board, but by different control boards. In other embodiments, the main unit assembly 1, the water tank assembly 2, the heating assembly 3, the stirring cup assembly 4, the juice receiving cup assembly 5 and the gas input assembly 6 may be assembled in other manners, and the assembled structure and/or form may not be as shown in fig. 1 and 2.

The water tank assembly 2 is used for supplying water to the instant heating assembly 3, and the structure thereof is not limited, and the purpose of supplying water can be achieved, for example, the water tank assembly 2 includes a water tank, a water pump and the like.

I.e. the heating assembly 3 is used to heat water from the water tank assembly 2 to produce high temperature liquid and/or high temperature steam. Further, in the technical idea of the present application, that is, the heating unit 3 is also used to heat gas to generate high temperature gas, the configuration thereof is not limited as long as gas and water can be heated. The high temperature gas and the high temperature steam are respectively used for heating food, which belongs to the industry terminology, and the temperature range of the high temperature gas and the high temperature steam is known to those skilled in the art. The high temperature liquid is in embodiments of the present application heated water, which may also be referred to as hot water. The gas input module 6 inputs gas in two modes, the first mode is that the gas input module 6 is connected with a gas inlet of the instant heating module 3 and blows gas into the instant heating module 3; the second way is that the gas input assembly 6 is connected to the outlet of the instant heating assembly 3, where air is drawn to input the gas into the instant heating assembly 3, as described in detail below. That is, the heating unit 3 includes a heating member 30, an air pipe 31, and a water pipe 32, as shown in fig. 14 to 20. In the embodiment of the present application, the more specific configuration of the thermal assembly 3 is as described later.

The stirring cup assembly 4 is connected with the instant heating assembly 3 and comprises a stirring cup 40. In the case where the mixing cup 40 is communicated with the water pipe 32, that is, the high-temperature liquid (i.e., hot water) generated from the heating module 3 can flow into the mixing cup 40. The blending cup assembly 4 forms a slurry (also referred to in the art as juice) from the foodstuff and the hot liquid within the blending cup 40.

The juice receiving cup assembly 5 is assembled to the main unit assembly 1 and includes a juice receiving cup 50. With the juice receiving cup 50 in communication with the blender cup 40, the syrup can flow into the juice receiving cup 50, for example, the syrup (also referred to as juice) is discharged from the blender cup 40 through the syrup outlet 12 of the syrup discharge pipe, and flows into the juice receiving cup 50 through the juice outlet 502 at the top of the juice receiving cup 50. The structure for realizing the communication between the juice receiving cup 50 and the stirring cup 40 is not limited. Furthermore, one of the concepts of the present application is to use hot gas and/or steam to heat the slurry in the juice cup 50, which are different cups, and thus the juice cup assembly 5 is also connected to the instant heating assembly 3 to allow hot gas or steam to enter the heated cup (e.g., the juice cup 50). Some configurations that enable hot gases to enter the juice-receiving cup 50 are described below. The pipeline for heating the related cup by using the high-temperature steam can be referred to the pipeline for heating the juice receiving cup by using the high-temperature gas, and the details are not repeated.

The control board controls the input of the high temperature gas into the food in the juice receiving cup 50 according to the cooking program to heat the food, for example, controls the operation of the gas input assembly 6 to input the high temperature gas into the juice receiving cup 50, or controls the valves (such as a gas three-way valve 7 described later) of the connection pipeline between the gas input assembly 6, the juice receiving cup assembly 5 and the instant heating assembly 3 to make the gas input assembly 6, the juice receiving cup assembly 5 and the instant heating assembly 3 constitute a passage. Briefly, the above process is as follows: the gas input assembly 6 can be used to input high temperature gas into the juice receiving cup assembly 5 (juice receiving cup 50), therefore, the structure of the gas input assembly 6 is not limited, for example, in fig. 3, the gas input assembly 6 includes a gas pump, and in other embodiments, the gas input assembly 6 can also include a fan, etc. The gas input assembly 6 can be controlled by the control board to input gas, or the gas input assembly 6 can comprise buttons, and the input of gas is realized or stopped by operating the buttons. Of course, according to the difference that the gas input assembly 6 is connected to the gas inlet or the gas outlet of the instant heating assembly 3, the step of inputting the high-temperature gas into the juice receiving cup 50 includes blowing the high-temperature gas into the juice receiving cup 50 or sucking the high-temperature gas out of the juice receiving cup 50, and more specifically, in the case that the gas input assembly 6 is connected to the gas inlet of the gas pipe 31 and the juice receiving cup 50, the gas input assembly 6 and the gas pipe 31 are communicated (how to communicate the juice receiving cup 50, the gas input assembly 6 and the gas pipe 31 is in various ways, which is not described herein again), the gas input assembly 6 inputs the gas into the gas pipe 31 of the instant heating assembly 3, and the gas is heated by the heating element 30 to generate the high-temperature gas, for example, the control board controls the heating element 30 to heat the gas to generate the high-temperature gas. The high temperature gas is input into the juice receiving cup 50 through the gas outlet 312 of the gas pipe 31. Under the condition that the gas input assembly 6 is connected to the gas outlet of the instant heating assembly 3 at a high temperature and the juice receiving cup 50, the gas input assembly 6 and the gas pipe 31 are communicated (how to communicate is in various manners and is not described in detail), the gas input assembly 6 blows gas into the gas pipe 31, that is, the heating element 30 of the instant heating assembly 3 heats the gas to obtain high-temperature gas, in this case, the high-temperature gas can be sucked out from the gas pipe 31 of the instant heating assembly 3 by the gas input assembly 6 due to the suction force of the gas input assembly 6 at the gas outlet 312 of the gas pipe 31, so that the high-temperature gas is input into the juice receiving cup 50. The gas input member 6 blows gas into the instant heating member 3, and the gas input member 6 can ensure the service life of the gas input member 6 more than the gas input member 6 sucks the high-temperature gas of the instant heating member 3 out and then delivers the gas to the juice receiving cup 50, because the high-temperature gas does not affect the gas input member 6.

After the hot gas enters the juice-catching cup 50, the hot gas passes through the food (such as the serum) to heat the food (not limited to the serum) inside the juice-catching cup 50. In fig. 1 and 2, the high temperature gas passes through the food (slurry or juice) in the juice receiving cup 50 from the bottom 501 of the juice receiving cup 50 upward, and after heat exchange with the food, is discharged from the juice receiving port 502 at the top of the juice receiving cup 50.

In various embodiments of the present application, the gas is heated to form a high temperature gas, and the high temperature gas is used for heating food, so that any gas harmless to the body can be used in the present application, for example, air, and in some embodiments, nitrogen or the like can be used as the gas.

Referring to fig. 3 and 4, fig. 3 and 4 are second food processor of the present application. This food processor is different from the first food processor in the way of introducing the high temperature gas into the juice receiving cup 50, and more specifically, in the embodiment shown in fig. 1 and 2, the high temperature gas enters into the juice receiving cup 50 from the bottom 501 of the juice receiving cup 50, while in the embodiment shown in fig. 3 and 4, the high temperature gas enters into the juice receiving cup 50 from the side of the juice receiving cup 50, in which case, the structure for introducing the high temperature gas into the juice receiving cup 50 may be any structure, and the structure adopted in the embodiments of the present application is as described later. The hot gases enter the juice receiving cup 50 from the side of the juice receiving cup 50 which is adjacent the bottom 501 of the juice receiving cup in figure 4. In other embodiments, the hot gases may not enter from the side near the bottom 501 of the juice receiving cup.

In the two embodiments, the high-temperature gas enters the juice receiving cup 50 from the bottom 501 of the juice receiving cup, and is discharged from the juice receiving port 502 after heat exchange with food (juice or pulp), and according to the position of the juice receiving port 502, the high-temperature gas can also enter the juice receiving cup 50 from other positions, so that the high-temperature gas can only pass through the food, including partial or complete passing. Partially through the hot gas inlet means shown in fig. 3 and 4, and completely through the hot gas inlet means shown in fig. 1 and 2. Furthermore, although the two embodiments described above illustrate the blending cup assembly 4, the skilled artisan will appreciate that in some embodiments, a processor that does not include the blending cup assembly 4 can employ the teachings of the present disclosure as long as it is ensured that the food is within the juice receiving cup 50 of the juice receiving cup assembly 5, in embodiments of the present disclosure, the food is primarily liquid food (e.g., serum), but is not limited to liquid food. In addition, in the embodiment in which the heating unit 3 heats water to generate high-temperature liquid and/or high-temperature steam and also heats gas to generate high-temperature gas, the heating unit 3 includes the heating member 30, the gas pipe 31, and the water pipe 32. In some embodiments, the thermal assembly 3 may also heat only the gas, in which case the thermal assembly 3 includes a heating element 30 and a gas tube 31.

In conclusion, because this application produces high-temperature gas through instant heating subassembly 3, high-temperature gas gets into and connects in juice cup 50, passes food (for example juice or thick liquid) back discharge, high-temperature gas can be comparatively abundant contact food and take place heat exchange at the food in-process of passing, it is fast to heat food, in addition, high-temperature gas passes the food in-process and can make food take place the motion, and then, plays the effect of stirring, consequently, can ensure not stick with paste the end, not layering, also need not set up mixing system in connecing juice cup 50. In addition, under the condition that the food in the juice receiving cup is heated by high-temperature steam, the high-temperature steam can exchange heat with the food in the juice receiving cup, so that the food can be heated quickly. In addition, the functions of generating high-temperature gas and high-temperature steam and/or high-temperature liquid are integrated, so that the instant heating assembly is simple in structure, small in size and low in cost. Finally, some current methods, in which steam is obtained by heating the water in the water tank assembly 2, and the food in the juice receiving cup 50 is heated by the steam, have the disadvantages that the steam becomes liquid when it is cold, so that the liquid level of the food rises, the steam becomes liquid to dilute the food (such as soybean milk) and affect the taste, and in addition, the water in the water tank of the water tank assembly is consumed. And this application is through the food in the high temperature gas heating juice receiving cup 50, can not make the liquid level of food rise, can not dilute food and influence food taste. The transmission pipeline of high-temperature gas is independent of the pipeline of high-temperature liquid, so that the high-temperature gas can not become water vapor, water in the water tank of the water tank assembly can not be consumed, food can not be diluted, the liquid level of the food can not rise, in addition, the temperature of the high-temperature gas is higher than that of the water vapor, and the food in the juice cup 50 can be heated more quickly.

An embodiment of how the connection between the water tank assembly 2, i.e. the heating assembly 3, the stirring cup assembly 4, the juice receiving cup assembly 5 and the gas input assembly 6 and how the related functions are achieved, which can be used in the various processors of the present application, is described in detail. The connection relationships shown in fig. 5, 6, 8, 9, 11 and 12 can be used not only in the food processor shown in fig. 1 and 2, but also in the food processor shown in fig. 3 and 4. The following are described respectively:

in fig. 5 and 6, the water tank assembly 2 is connected to the water pipe 32 of the instant heating assembly 3 by the flow pump 21 and the corresponding piping. The gas input assembly 6 is connected to the gas inlet 311 of the gas pipe 31 for inputting gas (e.g., air, nitrogen, etc.) into the gas pipe 31. The air outlet 312 of the air tube 31 is connected to the juice receiving cup 50, and there are various ways to connect the air tube to the juice receiving cup 50, as long as the high temperature air can enter the juice receiving cup 50 through the related control (such as the control of a valve).

Referring to fig. 7 in conjunction with fig. 5 and 6, based on the connection relationship shown in fig. 5 and 6, a working flow of the food processor is described as follows:

the control panel controls the communication of the water tank assembly 2 and the instant heating assembly 3. The water in the water tank of the water tank assembly 2 flows toward the instant heating assembly 3 and is heated by the heating member 30 of the instant heating assembly 3 to generate a high-temperature liquid. The hot liquid flows into the blender cup 40. The blending cup assembly (e.g., a motor driving a blending blade) forms a slurry (also referred to as juice) from the hot liquid and the food material. The control panel controls the juice outlet valve 41 of the stirring cup assembly 4 to be opened, and the slurry flows into the juice receiving cup 50 through the juice outlet valve 41, the slurry discharge pipeline connected with the juice outlet valve 41 and the slurry outlet 12. Of course, in some embodiments, the control board controls the instant heating module 3 to generate high temperature gas while generating high temperature liquid based on the structure of the instant heating module 3. In some embodiments, the high temperature gas may not be generated simultaneously. In the embodiment shown in fig. 5 and 6, the gas input unit 6 inputs gas into the gas pipe 31 of the instant heating unit 3, and the heating member 30 heats the gas to generate high-temperature gas. The high temperature gas is discharged from the gas outlet 312 of the gas pipe 31, and the high temperature gas is output to the juice receiving cup 50 under the condition that the gas input assembly 6 continuously inputs the gas and the gas pipe 31 and the juice receiving cup 50 are communicated. In the process, the water tank assembly 2 can continuously supply water into the stirring cup 40, and the stirring blades of the stirring blade assembly 4 are rotated to wash the cup wall of the stirring cup 40, and the step can be performed for 1 or 1+N cycles. The slurry produced by the flushing may also continue to flow into the juice cup 50. The serous fluid is boiled in the juice receiving cup 50 until the serous fluid is well cooked, the high-temperature gas is continuously input into the juice receiving cup 50 in the serous fluid boiling process, after the food is well cooked, the gas input assembly 6 stops inputting the gas, namely, the heating assembly 3 stops generating the high-temperature gas, for example, the stop work of the gas input assembly 6 and the stop work of the heating assembly 3 can be controlled by the control panel.

In the above embodiment, the gas input unit 6 is connected to the gas inlet 311 of the gas pipe 31 to blow gas into the instantaneous module 3, but it will be understood by those skilled in the art that the gas input unit 6 may be connected to the gas outlet 312 of the gas pipe 31 to suck out high-temperature gas generated from the instantaneous module 3 and then convey the gas to the juice receiving cup 50.

Referring to fig. 8, 9, 11 and 12, in one embodiment, the food processor includes a stirring cup assembly 4, and the stirring cup assembly 4 includes a stirring cup 40. With the blender cup 40 and the juice-receiving cup 50 in communication, the slurry within the blender cup 40 flows to the juice-receiving cup 50. Under the condition that the stirring cup 40, the gas input assembly 6 and the gas pipe 31 are communicated, the high-temperature gas enters the stirring cup 40 to bake the stirring cup. So set up, through hot drying of high-temperature gas stirring cup 40 can play the effect of stoving, disinfecting, improves user experience. Moreover, utilize the high-temperature gas that instant heating assembly 3 produced carries out the stoving to stirring cup 40 for instant heating assembly 3 can realize more functions, and the cooking machine need not set up the correlation structure who is used for the stoving stirring cup 40 again, simplifies the structure of cooking machine in other words and makes the simple structure and the compactness of cooking machine. How the blender cup 40, the gas input assembly 6 and the gas pipe 31 communicate can take on a variety of embodiments. Embodiments for achieving this communication are described below.

Referring to fig. 8 and 9, the embodiment shown in fig. 8 and 9 is different from the embodiment shown in fig. 5 and 6 in that: the cooking machine includes gas three-way valve 7, connect juice cup 50 with stirring cup 40 passes through gas three-way valve 7 connect in trachea 31. The high-temperature gas enters the juice receiving cup 50 or the stirring cup 40 by switching the gas three-way valve 7. The connection relationship between other components, for example, the connection relationship between the gas input component 6 and the gas pipe 31, is referred to above and will not be described in detail. The switching of the gas three-way valve 7 can be realized by the control board, and the switching of the gas three-way valve 7 can also be realized by other controllers. By providing the gas three-way valve 7, the high temperature gas is supplied to either the juice receiving cup 50 or the blender cup 40. The operation of the food processor having such a component connection relationship will be described below with reference to fig. 10.

Referring to fig. 10, the operations of preparing the juice (or juice) and introducing the high temperature gas into the juice receiving cup 50 are as described above, and will not be described in detail. As shown in fig. 10, after the food (such as the syrup) is cooked, the gas three-way valve 7 is controlled to be switched, for example, the control board controls the gas three-way valve 7 to be switched, so that the gas input assembly 6, the gas three-way valve 7 and the juice receiving cup 50 are disconnected, and the gas input assembly 6, the gas three-way valve 7 and the stirring cup 40 are connected, in this case, since the gas input assembly 6 continuously inputs gas into the gas pipe 31, high-temperature gas generated in the heating assembly 3 is blown to the stirring cup 40 by the gas input assembly 6, and the stirring cup 40 is heated until the heat sterilization is completed. As a variation of the above embodiment, the skilled person can understand that the gas input assembly 6 can also be disposed at the gas outlet 312 of the gas pipe 31, and the working process in this case is the same as the working process in the case of connecting the gas input assembly 6 to the gas outlet 312 in fig. 5 and 6, and will not be described again. So set up, realize high-temperature gas flow direction stirring cup 40 through switching gas three-way valve 7, perhaps, the flow direction connects juice cup 50 to simple structure has realized high-temperature gas's transport, and control is convenient, and the cooking machine can be applicable to different application scenes, and user experience is good.

Referring to fig. 11 and 12, another embodiment for realizing the communication between the mixing cup 40, the gas input assembly 6 and the gas pipe 31 is as follows: compared with the embodiment shown in fig. 5 and 6 or the embodiment shown in fig. 8 and 9, the food processor comprises a juice receiving two-way valve 81 and a stirring two-way valve 82. The juice receiving cup 50 is connected to the air pipe 31 through the juice receiving two-way valve 81, and the stirring cup 40 is connected to the air pipe 31 through the stirring two-way valve 82. More specifically, the juice receiving two-way valve 81 and the stirring two-way valve 82 are connected to the three-way pipe 83, and the three-way pipe 83 is connected to the air outlet 312 of the air pipe 31. The high-temperature gas is controlled to enter the juice receiving cup 50 and/or the stirring cup 40 through the combination of the on-off state of the juice receiving two-way valve 81 and the on-off state of the stirring two-way valve 82. More specifically, the method comprises the following combination: 1) The juice receiving two-way valve 81 is switched on, the stirring two-way valve 82 is switched off, and high-temperature gas flows into the juice receiving cup 50; 2) The juice receiving two-way valve 81 is closed, the stirring two-way valve 82 is switched on, and high-temperature gas flows into the stirring cup 40; 3) The juice receiving two-way valve 81 and the stirring two-way valve 82 are simultaneously turned on, and the high-temperature gas flows into the stirring cup 40 and also flows into the juice receiving cup 50, so that the food (syrup) in the juice receiving cup 50 can be cooked and the stirring cup 40 can be baked. Fig. 13 illustrates the operation of heating the food in the juice receiving cup 50 by the hot gas and then baking the blender cup 40 by the hot gas, which will not be described in detail. So set up to the intercommunication of stirring cup 40, gas input subassembly 6 and trachea 31 is realized to simple structure relatively, perhaps, connects juice cup, gas input subassembly and tracheal intercommunication, perhaps, can carry out the stoving to stirring cup 40 when connecing the food boil out in juice cup 50, has saved whole flow completion time, has improved user experience more.

Referring to fig. 5, 6, 8, 9, 11 and 12, the food processor includes a water tank assembly 2, the instant heating assembly 3 includes a water pipe 32, the heating element 30 adds water in the water pipe 32 to generate high-temperature liquid and/or high-temperature steam under the condition that the water pipe 32 is communicated with the water tank assembly 2, the stirring cup 40 is connected with the water pipe 32 through a control valve, and the control valve is controlled to enable the high-temperature liquid to flow into the stirring cup 40, so that the stirring cup assembly 4 can make the high-temperature liquid and the food material into slurry or juice. How the high-temperature steam heats the food in the juice receiving cup can refer to the way that the high-temperature gas heats the food in the juice receiving cup, and the details are not repeated. The control valve may be a water check valve 42, which is opened by the pressure of water, so that the high temperature liquid can flow into the mixing cup 40, or may be controlled by a control board, and the flow of the high temperature liquid into the mixing cup 40 is controlled or prohibited by controlling the on/off state of the control valve. By the arrangement, the high-temperature liquid and the crushed food materials form the slurry, the pulping time can be shortened, and in addition, for food such as soybean milk, the high-temperature liquid is adopted for pulping, so that the fishy smell of the food, such as the beany smell, can be removed; finally, utilize instant heating subassembly 3 produces high temperature liquid, and provide stirring cup 40 with high temperature liquid, expand instant heating subassembly 3's application, and the cooking machine need not set up the relevant part that adds hot water again, and then makes cooking machine's simple structure, compactness, is favorable to the cooking machine miniaturization.

Referring to fig. 8, 9, 11 and 12 in combination with fig. 5 and 6, in some embodiments, the food processor includes a water three-way valve 91 and a ready-to-drink port 92. The mixing cup 40 and the instant drinking water port 92 are both connected to the water pipe 32 through the water three-way valve 91, and the high-temperature liquid flowing into the mixing cup 40 or flowing into the instant drinking water port 92 is controlled by switching the water three-way valve 91, so that the high-temperature liquid and the food material in the mixing cup 40 form a slurry, the slurry flows into the juice receiving cup 50, and the high-temperature liquid is discharged from the instant drinking water port 92, and hot water, for example, can be provided for use as boiled water. So set up, the beneficial effect of this kind of embodiment has the beneficial effect under only providing the high temperature liquid condition at least, in addition, the cooking machine can also provide the high temperature liquid (hot water) of drinking promptly, and the function is more complete, uses more extensively, and user experience is better.

Referring to fig. 14, 15, 17 and 18 in conjunction with fig. 20, an embodiment of the instant heating element 3 of the present application will be described in detail as follows. Fig. 14 and 15 show a first embodiment of the instant heating module 3 (instant heating module for food processor), and fig. 17 and 18 show a second embodiment of the instant heating module 3 (instant heating module for food processor). Since the instant heating module 3 heats not only water but also gas, it includes a heating member 30, a gas pipe 31, and a water pipe 32. The first heating assembly and the second heating assembly are different in the arrangement of the heating member 30, the air pipe 31 and the water pipe 32, and accordingly, the arrangement of the heating member 30, the air pipe 31 and the water pipe 32 shown in fig. 20 is different from that shown in fig. 14, 15, 17 and 18.

First, the structure of the heating module 3 shown in fig. 14 and 15 will be described below. An instant heating unit 3 for a handler includes an instant heating body 33, an air pipe 31, a water pipe 32, and a heating member 30. The instant heating body 33 is used to assemble the heating member 30, the air pipe 31, the water pipe 32, etc., and the structure is not limited, and in fig. 14, 15, 17, and 18, the air pipe 31 and the water pipe 32 are bent back and forth, for example, in a serpentine shape, so that the instant heating body 33 has a rectangular parallelepiped shape. The air pipe 31 is arranged through the instant heating body 33 and is communicated with the outside of the instant heating body 33. The water pipe 32 penetrates through the instant heating body 33 and is communicated with the outside of the instant heating body 33, and more specifically, referring to fig. 15 and 16 in combination with fig. 14, after being bent back and forth, the air pipe 31 and the water pipe 32 are located inside the instant heating body 33, and only the air inlet 311, the air outlet 312, the water inlet 321, the water outlet 322 and the terminals (in the present embodiment, including the live wire terminal 301 and the neutral wire terminal 302) of the heating element 30 are located outside the instant heating body 33. The heating member 30 is disposed between the gas pipe 31 and the water pipe 32, and heats the gas in the gas pipe 31 to generate high-temperature gas when the gas pipe 31 is energized, and heats the water in the water pipe 32 to obtain high-temperature liquid and/or high-temperature steam when the water pipe 32 is energized. So arranged, the instant heating component 3 provides high-temperature gas independently under the condition of being electrified and gas exists in the gas pipe 31 but no water exists in the water pipe 32; when no gas exists in the electrifying gas pipe 31 but water exists in the water pipe 32, high-temperature liquid and/or high-temperature steam are/is provided; under the circumstances that there is gas and water in the water pipe 32 in the circular telegram and trachea 31, provide high-temperature gas and high-temperature liquid and/or high-temperature steam simultaneously, consequently, use in a flexible way, satisfy the demand of different application scenarios, user experience feels well. Moreover, under the condition that high-temperature gas can be generated, the high-temperature gas can be used for heating food in the juice receiving cup, the food can be quickly heated, the food cannot be layered or burnt, a stirring system does not need to be arranged on the juice receiving cup assembly, and the like. Based on the above arrangement, the configurations of the heating member 30, the gas pipe 31 and the water pipe 32 are not limited, and even for the purpose of supplying at least one of high-temperature gas, high-temperature liquid and high-temperature steam, the heating member 30 may further include independent first and second heating members, the first heating member, when energized, heats the gas in the gas pipe 31 to generate high-temperature gas in the gas pipe 31; the second heating member heats the water in the water pipe 32 under energization to generate high-temperature liquid and/or high-temperature steam in the water pipe 32. The instant heating component integrates the functions of generating high-temperature gas and high-temperature steam and/or high-temperature liquid, so that the instant heating component is simple in structure, small in size and low in cost.

Referring to fig. 16 in conjunction with fig. 14 and 15, in one embodiment, the heating element 30 (e.g., heating tube) is located between the gas tube 31 and the water tube 32, and the heating element 30, the gas tube 31 and the water tube 32 are bent back and forth, as shown, in a serpentine shape. The water pipe 32, the air pipe 31 and the heating member 30 are stacked and spaced apart from each other. While fig. 16 and 15 illustrate the heating element 30, the gas pipe 31 and the water pipe 32 as one layer, those skilled in the art will appreciate that fig. 15 and 16 can be used as a module, and the module can be stacked to form another instant heating assembly. In fig. 16 and 15, the heating element 30 is located between the air pipe 31 and the water pipe 32, specifically, the heating element 30 is located right below the air pipe 31 and is located right above the water pipe 32, and it can be understood by the skilled person that the location of the heating element 30 between the air pipe 31 and the water pipe 32 also includes the case that at least one of the air pipe 31 and the water pipe 32 is staggered with the heating element 30, that is, the air pipe 31 and/or the water pipe 32 may be located obliquely above or obliquely below the heating element 30. This embodiment may be considered as a longitudinal arrangement of the heating member 30, the air pipe 31 and the water pipe 32. As the instant heating component 3 is arranged as above, the water pipe 32, the air pipe 31 and the heating component 30 are bent back and forth and are arranged in a stacked and separated mode, thus being beneficial to reducing the width of the instant heating component 3, and meanwhile, the heating component 30, the air pipe 31 and the water pipe 32 are bent back and forth and can also provide a larger heating part, and the heating effect is good.

Referring to fig. 18 and 19 in conjunction with fig. 17, in another embodiment, the heating element 30 is located between the gas pipe 31 and the water pipe 32, and the heating element 30 (e.g., a heating pipe), the water pipe 32 and the gas pipe 31 are bent back and forth in the same plane, and are bent in a serpentine shape as shown in the figures. This embodiment may be considered as a horizontal arrangement of the heating member 30, the air pipe 31 and the water pipe 32. As the instant heating component 3 arranged as above, because the water pipe 32, the air pipe 31 and the heating element 30 are bent back and forth in the same plane, thus being beneficial to reducing the height of the instant heating component 3, and meanwhile, the heating element 30, the air pipe 31 and the water pipe 32 are bent back and forth to provide a larger heating part, and the heating effect is good.

Referring to fig. 20, in another embodiment, the heating element 30 is located between the air pipe 31 and the water pipe 32, the air pipe 31 is a straight pipe, and the water pipe 32 and the heating element 30 are both spiral around the air pipe 31. Of course, in other embodiments, the air tube 31 may have other shapes, such as a spiral shape. So set up the heating member with the water pipe all winds under the condition of trachea spiral, trachea 31 is closer to heating member 30, and is effectual to gaseous heating. In addition, through will heating member 30 with water pipe 32 sets up to helical structure, not only can provide great heating area, and it is effectual to heat, but also can be with heating subassembly 3 promptly and make cylindricly, is favorable to dwindling heating subassembly 3 promptly's width and height, is applicable to and can place the scene of columnar heating subassembly promptly.

Although the heating tube is exemplified as the heating element 30, the skilled person will understand that the heating element 30 may have other configurations, such as a thick film heating tube or a thick film heating device, a heating wire, a quartz nanotube, a carbon fiber tube, a light wave tube, and so on. In addition, based on the technical idea of the present application that the functions of high-temperature gas, high-temperature liquid and/or high-temperature steam are integrated together, the heating member may not be located the trachea 31 with between the water pipe 32 as long as the purpose of heating water pipe and trachea can be reached.

The air tube 31 of the above embodiments does not have any auxiliary heating components therein, and in some embodiments, auxiliary heating components, such as a heating wire, a heating film, a superconductor, etc., may be disposed in the air tube 31 for increasing the temperature rise speed in the air tube. The air pipe 31 is preferably free of any auxiliary heating means, which may generate harmful substances during heating of air to affect health in the current process. An embodiment in which an auxiliary heating member is provided in the air pipe 31 will be described below. Referring to fig. 21 in conjunction with fig. 15 and 18, fig. 21 illustrates the structure of an air tube including an air tube 31 and an auxiliary heating element 36 disposed in the air tube 31. Such an auxiliary heating member 36 is a heating wire.

As a variation of the above embodiment, in another embodiment, the heating element 30 is located between the air pipe 31 and the water pipe 32, the water pipe 32 is a straight pipe, and the air pipe 31 and the heating element 30 are spirally arranged around the water pipe 32, which can be considered as a circumferential arrangement. Of course, in other embodiments, the water tube 32 may have other shapes, such as a spiral shape. So set up, because trachea 31 with heating member 30 all winds water pipe 32 spiral, water pipe 32 is close to heating member 30's center, and the heating of water is effectual. In addition, through will add heat member 30 with trachea 31 sets up to helical structure, not only can provide great heating area, and it is effectual to heat, but also can be with heating subassembly 3 promptly and make cylindricly, is favorable to reducing width and height that heating subassembly 3 promptly, is applicable to and can place the scene of the columnar subassembly that promptly heats.

With continued reference to FIGS. 15-20, for any of the instant heating elements 3 described above (whether longitudinally, horizontally, or circumferentially), the distance between the outer wall of the heating element 30 and the outer wall of the water tube 32 is D2, 1. Ltoreq. D2. Ltoreq.15 mm, such as, 1mm, 2mm, 3mm, 4mm, 5mm, 6mm, 7mm, 8mm, 9mm, 10mm, 11mm, 12mm, 13mm, 14mm, or 15mm. So set up, D2 can make the heating effect better in above-mentioned scope, because the distance too big can make the heating element can't better heat and make the speed of heating water slow, whole time is long, and the distance is too little makes the preparation complicated, in some embodiments, also can make water pressure too little be difficult to open water check valve 42 and make high temperature liquid be difficult to get into stirring cup 40.

With continued reference to FIGS. 15-20, for any of the instant heating elements 3 described above (whether longitudinally, horizontally, or circumferentially), in another embodiment, the distance between the outer wall of the heating element 30 and the outer wall of the gas tube 31 is D1, D1 is greater than or equal to 1 and less than or equal to 15mm, such as 1mm, 2mm, 3mm, 4mm, 5mm, 6mm, 7mm, 8mm, 9mm, 10mm, 11mm, 12mm, 13mm, 14mm, or 15mm. So set up, D1 can make the heating effect better in above-mentioned scope, because the distance can make the heating member can't better heat and make the speed of heating gas slow too greatly, and whole heating time is long, and the distance is too little makes heating member 30 and trachea 31 preparation complicated, in addition, in some embodiments, also can make the atmospheric pressure be too little be difficult to open water check valve 42 and make high temperature liquid be difficult to get into stirring cup 40.

With continued reference to FIGS. 15-20, for any of the instant heating elements 3 described above (whether longitudinally, horizontally, or circumferentially), the water tube 32 has an inner diameter R2, R2 is 1mm or more and R2 is 10mm or less, such as 1mm, 2mm, 3mm, 4mm, 5mm, 6mm, 7mm, 8mm, 9mm, 10mm, etc. So set up, the internal diameter R2 of water pipe 32 is in above-mentioned scope, can make heating member 30 to the water heating effect in water pipe 32 good, because the internal diameter is too big, heating member 30's heat may be not enough to make the temperature of high temperature liquid not high enough for the heating member's 30 heat, and too little makes the preparation technology of water pipe complicated, and in addition, in some embodiments, water pipe 32 is too little to make the water pressure relatively less, is difficult to make control valve (for example, the check valve) between stirring cup 40 and instant heating component 3 switch on.

With continued reference to FIGS. 15-20, for any of the instant heating elements 3 described above (whether longitudinally, horizontally, or circumferentially), in another embodiment, the inner diameter of the gas tube 31 is 1. Ltoreq. R1. Ltoreq.6 mm, such as 1mm, 1.5mm, 2mm, 2.5mm, 3mm, 4mm, 4.5mm, 5mm, 5.5mm, 6mm, etc. So configured, too large inner diameter R1 of the air pipe 31 will heat slowly, and in some embodiments, too large inner diameter R1 of the air pipe 31 will result in large cross-sectional area of the air pipe 31, so that the gas pressure in the air pipe 31 will not make the gas check valve 61 between the juice receiving cup 50 and the instant heating assembly 3 conductive; too small an inner diameter of the air tube 31 complicates the manufacturing process and also causes high temperature gas to be flushed out after the juice cup assembly 5 is removed, i.e., the thermal buffer in the heating assembly 3, resulting in scalding.

In some embodiments, the inner diameter of the gas pipe 31 may satisfy 1. Ltoreq. R1. Ltoreq.6 mm, and the inner diameter of the water pipe 32 is R2, 1. Ltoreq. R2. Ltoreq.10 mm.

Referring to fig. 14, in one embodiment, the heating element 30 is, for example, a heating tube, the terminals (including the live terminal 301 and the neutral terminal 302) of the heating element 30 are located on a first side of the instant heating body 33, the water inlet 321 and the water outlet 322 of the water tube 32 are located opposite to the first side, and the air inlet 311 and the air outlet 312 of the air tube 31 are located opposite to the first side. In another embodiment, the water inlet 321 and the water outlet 322 may be located at the side of the first side, and the air inlet 311 and the air outlet 312 are also located at the side of the first side. So set up, no matter water inlet 321 and delivery port 322 are located the side or the opposite of first side, still air inlet 311 and gas outlet 312 are located the side or the opposite of first side can both make air inlet 311 and gas outlet 312 to and water inlet 321 and delivery port 322 are kept away from terminal (live wire terminal 301 and zero line terminal 302), avoid leaking and lead to electric leakage etc.. Although fig. 17 illustrates that the terminals (the live terminal 301 and the neutral terminal 302) are located on the same side as the air inlet 311, the air outlet 312, the water inlet 321 and the water outlet 322, a skilled person will understand that the terminals and the air inlet, the air outlet, the water inlet and the water outlet may be located on different sides or opposite sides in the case of a horizontal arrangement, and the terminals and the air inlet, the air outlet, the water inlet and the water outlet may be located in the same way in the case of a circumferential arrangement.

With continuing reference to fig. 14 and 17, in some embodiments, the water pipe 32 includes a water outlet 322 extending out of the instant heating body 33, the air pipe 31 includes an air outlet 312 extending out of the instant heating body 33, and at least one of the air outlet 312 and the water outlet 322 is provided with a temperature sensor, in this embodiment, the air outlet 312 and the water outlet 322 are respectively provided with a temperature sensor 34 for measuring the temperature of the high-temperature gas and the temperature of the high-temperature liquid and/or the high-temperature steam. The control board controls the heating of the gas heating member 30a or the heating member 30b according to the temperature value of the temperature sensor. For example, the temperature controller 35 may be controlled to be turned off to control the heating element 30 not to be heated any more by the temperature value. So set up, improve high-temperature gas high-temperature liquid or the heating temperature's of high-temperature steam the degree of accuracy is surpassing under the condition of predetermineeing the temperature, can stop heating, improves the security.

With continued reference to fig. 5, 6, 8, 9, 11 and 12, in some embodiments, the gas inlet assembly 6 may supply external gas into the juice receiving cup 50 to cool the heated food in the juice receiving cup 50 when the gas heating element 30 is not in a heating state. Similarly, the gas input module 6 may be controlled by the control board to input the external gas, or the gas input module 6 may include a button through which the external gas is input. The external air is an air input from the outside of the food processor, and the temperature of the external air is lower than that of the food in the juice receiving cup 50. So set up, pass through the external gas connect the food in the juice cup 50 to reach the purpose of cooling food, the inside back of external gas entering food is discharged from connecing juice mouth 502 that connects juice cup 50, and the cooling food is faster, connects juice cup subassembly 5 also need not set up cooling part or cooking machine and need not set up cooling part, connects the simple structure of juice cup subassembly 5 or cooking machine.

Referring to fig. 5, 6, 8, 9, 11 and 12, in some embodiments, the gas input assembly 6 is connected to the gas inlet 311 of the gas pipe 31, and at least one of a gas check valve 61 is disposed between the gas input assembly 6 and the gas inlet 311 of the gas pipe 31 and between the juice receiving cup 50 and the gas outlet 312 of the gas pipe 31 to prevent the high temperature gas from flowing back. The gas check valve 61 may be a mechanical valve that opens under the pressure of the gas so that the gas can flow only toward the gas inlet pipe 31 or the high temperature gas flows into the juice receiving cup 50. So set up, gaseous check valve 61 between gaseous input subassembly 6 and the instant heating subassembly 3 can prevent the high temperature gas backward flow to, high temperature gas can not damage gaseous input subassembly 6, ensures the life-span of gaseous input subassembly 6. The gas check valve 61 between the juice receiving cup 50 and the instant heating module 3 can prevent the backflow of high temperature gas and the gas leakage of the juice receiving cup module 5, thereby ensuring the heating effect. In other embodiments, a water check valve 42 is disposed between the mixing cup 40 and the water pipe 32 to prevent the high temperature liquid from flowing back and ensure that the mixing cup 40 leaks water.

Referring to fig. 1 and 2, the food processor includes a main unit assembly 1, the juice receiving cup assembly 5 is disposed in the main unit assembly 1, the juice receiving cup 50 includes a juice receiving cup bottom 501 and a juice receiving port 502 communicating the inside and the outside of the juice receiving cup 50, and an air intake assembly 51 is disposed between the juice receiving cup bottom 501 and the main unit assembly 1, so that the high-temperature gas enters the juice receiving cup 50 from the juice receiving cup bottom 501 and then is exhausted from the juice receiving port 502.

Referring to fig. 3 and 4, in another embodiment, the juice receiving cup 50 includes a juice receiving cup bottom 501 and a juice receiving opening 502 communicating the inside and the outside of the juice receiving cup 50, and an air inlet assembly 51 is disposed between the side of the juice receiving cup 50 and the main machine assembly 1, so that the high-temperature gas enters the juice receiving cup 50 from the side of the juice receiving cup 50 and is discharged from the juice receiving opening 502.

In the above two air intake methods, the structure of the air intake assembly 51 is not limited, and air intake between the juice receiving cup 50 and the main machine assembly 1 can be realized, for example, the air intake assembly 51 is a one-way valve assembly, and includes a plug 511 and a valve seat 512. The plug 511 extends from the juice-receiving cup bottom 501 into the juice-receiving cup 50. The host assembly 1 includes a host housing 10, the host housing 10 including a placement platform 102. The juice receiving cup assembly 5 is placed on the placement platform 102. The valve seat 512 is disposed on the placement platform 102.

So set up, above-mentioned two kinds of embodiments can reach aforementioned heating fast, not layering, can not make food liquid level rise etc.. Compared with the prior art, the high-temperature gas can be moved along a longer moving path by introducing gas from the bottom 501 of the juice receiving cup, so that the slurry can be moved more easily, and the heating effect is relatively better.

With continued reference to fig. 2 and 4 in conjunction with fig. 1 and 3, in some embodiments, the juice receiving cup assembly 5 includes a temperature measuring element 52, a wireless transmitter module 53, and a cup holder 54. The temperature measuring element 52 is disposed at the bottom 501 of the juice receiving cup, and detects the temperature of the juice receiving cup 50 or the food in the juice receiving cup 50 to obtain a temperature value. The cup seat 54 is assembled with the juice receiving cup 50 in a sealing way to form a containing cavity 55; the wireless transmission module 53 is located in the accommodating cavity 55 and sends the temperature value outwards. The temperature measuring element 52 is any element capable of measuring temperature, such as an NTC or the like. The cooking machine includes host computer subassembly 1, host computer subassembly 1 includes control panel (not use in the figure except) and wireless receiving module 11, wireless receiving module 11 receives the temperature value, the control panel basis temperature value control gas input subassembly 6 stops to carry gas and/or heating member 30 stops to heat gas. In this embodiment, the control board and the wireless receiving module 11 are not limited to what kind of components are assembled in the food processor. According to the arrangement, the cup seat 54 is hermetically connected with the juice receiving cup 50 to form the accommodating cavity 55, and the juice receiving cup assembly 5 is communicated with the control board through the wireless transmitting module 53 and the wireless receiving module 11 to realize related control, so that the juice receiving cup assembly 5 can be made into an integral waterproof structure, which is convenient for washing a dishwasher and the like, and in addition, after the wireless transmission mode is adopted, compared with a mode that a coupler and the like are adopted between the juice receiving cup assembly 5 and the control board to transmit signals, only an air inlet assembly is communicated between the juice receiving cup assembly 5 and the host machine assembly 1, even if residual serous fluid drips on the grout outlet 12 of the host machine assembly 1, no interface such as the coupler and the like exists below the grout outlet, and phenomena such as electric leakage and the like caused by the serous fluid flowing into the coupler do not occur. Of course, based on the above structure, the receiving cavity 55 can receive not only the wireless transmitting module 53, but also other components of the juice receiving cup assembly 5. The communication mode between the wireless transmitting module 53 and the wireless receiving module 11 is not limited, for example, RFID, bluetooth, etc.

Referring to fig. 2 and 4 in combination with fig. 1 and 3, the main unit assembly 1 includes a main unit housing 10, the main unit housing 10 includes a housing main body 101 and a placement platform 102 disposed at the bottom of the housing main body 101, and the water tank assembly 2, the instant heating assembly 3, the stirring cup assembly 4 and the gas input assembly 6 are assembled to the housing main body 101. The casing main body 101 is further assembled with a motor and the like for driving the stirring blade of the stirring cup assembly 4 to rotate, and the control board may also be assembled to the casing main body 101. The juice receiving cup assembly is detachably assembled to the placement platform 102. Detachable assembly means that the juice cup assembly 5 is assembled to the placement platform 102 in case juice is required or the food in the juice cup 50 is heated, and the juice cup assembly 5 can be removed from the placement platform 102 and detached from the placement platform 102 in case juice is not required or the like. The wireless receiving module 11 is disposed in the placing platform 102. With such an arrangement, the wireless receiving module 11 is closer to the wireless transmitting module 53 and is far away from the control board or the coil of the motor, which are easy to interfere with signal transmission, so that signal transmission is more stable, in addition, the wireless receiving module 11 is arranged in the placing platform 102, the surface of the placing platform 102 is either a surface without an interface, as shown in fig. 3 and 4, or only one valve seat 512 is arranged, as shown in fig. 1 and 2, only the plug 511 on the juice receiving cup assembly 5 extends out of the cup seat 54 and is in one-way conduction with the valve seat 512 (only in the case of assembly), so that the structure can not cause phenomena such as electric leakage and the like due to the residual slurry dropping on the placing platform 102, and the safety is high.

The above description is only for the purpose of illustrating the preferred embodiments of the present application and is not to be construed as limiting the present application, and any modifications, equivalents, improvements, etc. made within the spirit and principle of the present application should be included in the scope of the present application.

Claims (14)

1. An instant heating assembly for a material handling machine, comprising:

a heating body (33);

the air pipe (31) is arranged in the instant heating body (33) in a penetrating way and is communicated with the outside of the instant heating body (33);

the water pipe (32) is arranged in the instant heating body (33) in a penetrating way and is communicated with the outside of the instant heating body (33);

a heating member (30) that, when energized and gas flows through the gas pipe (31), heats the gas in the gas pipe (31) to generate high-temperature gas; heating the water in the water pipe (32) to generate high temperature liquid and/or high temperature steam when the electricity is supplied and the water flows in the water pipe (32).

2. The instant heating component for the food processor as claimed in claim 1, wherein the heating element (30) is disposed between the air pipe (31) and the water pipe (32), and the heating element (30), the air pipe (31) and the water pipe (32) are all bent back and forth, stacked and spaced;

or the heating element (30) is arranged between the air pipe (31) and the water pipe (32), and the heating element (30), the water pipe (32) and the air pipe (31) are bent back and forth in the same plane;

or, the heating element (30) is arranged between the air pipe (31) and the water pipe (32), and the water pipe (32) and the heating element (30) are both screwed around the air pipe (31);

or, the heating element (30) is arranged between the air pipe (31) and the water pipe (32), and the air pipe (31) and the heating element (30) are both screwed around the water pipe (32).

3. The instant heating component for the food processor as claimed in claim 1 or 2, wherein the distance between the outer wall of the heating member (30) and the outer wall of the water pipe (32) is D2,1 ≤ D2 ≤ 15mm, and/or the inner diameter of the water pipe (32) ranges from R2,1 ≤ R2 ≤ 10mm.

4. The instant heating component for the food processor according to claim 1 or 2, wherein the distance between the outer wall of the heating member (30) and the outer wall of the air pipe (31) is D1, D1 is larger than or equal to 1 and smaller than or equal to 15mm, and/or the inner diameter of the air pipe (31) ranges from 1 to R1 to 6mm.

5. The instant heating assembly for the food processor according to claim 1 or 2, wherein the terminal of the heating element (30) is located at a first side of the instant heating body (33), the water inlet (321) and the water outlet (322) of the water pipe (32) are located at a side or opposite of the first side, and/or the air inlet (311) and the air outlet (312) of the air pipe (31) are located at a side or opposite of the first side.

6. The instant heating component for the food processor as claimed in claim 1 or 2, wherein the instant heating component for the food processor comprises a control board, the water pipe (32) comprises a water outlet (322) extending out of the instant heating body (33), the air pipe (31) comprises an air outlet (312) extending out of the instant heating body (33), at least one of the air outlet (312) and the water outlet (322) is provided with a temperature sensor, and the control board controls the heating element (30) to heat according to a temperature value of the temperature sensor.

7. A food processor, characterized in that it comprises a main machine component (1), a juice receiving cup component (5), a water tank component (2), a gas input component (6) and an instant heating component (3) for the food processor according to any one of claims 1 to 6,

the main machine component (1) comprises a control board which controls the heating element (30) to be electrified; the water tank assembly (2) supplies water to the water pipe (32) to generate the high-temperature liquid and/or high-temperature steam;

the juice receiving cup assembly (5) is arranged on the main machine assembly (1) and comprises a juice receiving cup (50);

the gas input assembly (6) inputs gas into the gas pipe (31) to generate the high-temperature gas, and the control board controls the high-temperature gas to be conveyed into food in the juice receiving cup (50) according to a cooking program to heat the food.

8. The food processor of claim 7, comprising a stirring cup assembly (4) assembled to the main machine assembly (1), the stirring cup assembly (4) comprising a stirring cup (40);

the air inlet (311) of the air pipe (31) is connected to the air input assembly (6), the air outlet (312) of the air pipe (31) is connected to the stirring cup (40) and the juice receiving cup (50), and the control panel further controls the high-temperature air to be conveyed to the stirring cup (40) according to a cooking program so as to bake the stirring cup (40) in a hot mode.

9. The food processor according to claim 8, characterized in that the food processor comprises a gas three-way valve (7), the juice receiving cup (50) and the stirring cup (40) are connected to the gas pipe (31) through the gas three-way valve (7), and the high-temperature gas enters the juice receiving cup (50) or the stirring cup (40) by switching the gas three-way valve (7);

or, the cooking machine is including connecing juice two-way valve (81) and stirring two-way valve (82), connect juice cup (50) to pass through connect juice two-way valve (81) connect in gas outlet (312) of trachea (31), stirring cup (40) are passed through stirring two-way valve (82) connect in gas outlet (312) of trachea (31), through connect the on-off state of juice two-way valve (81) with the combination of the on-off state of stirring two-way valve (82) is in order to control high temperature gas gets into connect juice cup (50) and/or stirring cup (40).

10. The machine according to any of the claims 7 to 9, wherein the juice receiving cup (50) comprises a temperature measuring element (52) arranged at the bottom (501) of the juice receiving cup, the temperature measuring element (52) measuring the temperature of the juice receiving cup (50) or the food in the juice receiving cup (50) to obtain a temperature value; the juice receiving cup assembly (5) comprises a wireless transmitting module (53), and the wireless transmitting module (53) transmits the temperature value outwards;

the host computer subassembly (1) includes wireless receiving module (11), wireless receiving module (11) receive the temperature value, the control panel according to the temperature value control gas input component (6) stop to carry gas and/or heating member (30) stop to heat gas.

11. The food processor according to claim 10, wherein the food processor comprises a stirring cup assembly (4), the host machine assembly (1) comprises a host machine housing (10), the host machine housing (10) comprises a housing main body (101) and a placing platform (102) located at the bottom of the housing main body (101), the instant heating assembly (3), the stirring cup assembly (4) and the gas input assembly (6) are assembled in the housing main body (101), and the control board and a motor for driving a stirring knife of the stirring cup assembly (4) to rotate are assembled in the housing main body (101); the juice receiving cup assembly (5) is detachably assembled on the placing platform (102), and the wireless receiving module (11) is arranged in the placing platform (102).

12. The machine according to any of the claims from 7 to 9, wherein the gas input assembly (6) inputs external gas into the juice receiving cup (50) to cool the food heated in the juice receiving cup (50) when the instant heating assembly (3) is in an unheated state.

13. The food processor of any one of claims 7 to 9, wherein the food processor comprises a stirring cup assembly (4), the stirring cup assembly (4) is assembled to the main machine assembly (1) and comprises a stirring cup (40); the stirring cup (40) is connected with the water pipe (32) through a control valve, the control valve is controlled to enable the high-temperature liquid to flow into the stirring cup (40), the high-temperature liquid and food materials in the stirring cup (40) form slurry, and the slurry flows into the juice receiving cup (50);

or, the food processer includes water three-way valve (91) and drink mouth promptly (92), stirring cup (40) with drink mouth promptly (92) all connect in through water three-way valve (91) water pipe (32), through switching over water three-way valve (91) with control high temperature liquid flows in stirring cup (40) or flow in drink mouth promptly (92), the high temperature liquid that flows in the stirring cup constitutes the thick liquid with the edible material in stirring cup (40), the thick liquid flows in connect juice cup (50).

14. The food processor of any one of claims 7 to 9, wherein the juice receiving cup (50) comprises a juice receiving cup bottom (501) and a juice receiving port (502) for communicating the inside and the outside of the juice receiving cup (50), and an air inlet assembly (51) is arranged between the juice receiving cup bottom (501) and the host machine assembly (1) so that the heating gas enters the juice receiving cup (50) from the juice receiving cup bottom (501) and then is exhausted from the juice receiving port (502);

or the juice receiving cup (50) comprises a juice receiving port (502) communicated with the inside and the outside of the juice receiving cup (50), and an air inlet assembly (51) is arranged between the side part of the juice receiving cup (50) and the main machine assembly (1) so that the heating air enters the juice receiving cup (50) from the side part of the juice receiving cup (50).

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