CN110604487A - Enzyme killing device and food processor - Google Patents

Abstract

The invention discloses an enzyme deactivation device and a food processor using the same, wherein the enzyme deactivation device is used for carrying out enzyme deactivation treatment on materials and comprises: the shell is provided with a first discharge hole; the storage tank is made of metal and arranged in the shell, an enzyme deactivation cavity is formed in the storage tank, and a steam inlet and a second discharge hole are formed in the cavity wall of the enzyme deactivation cavity; the steam generating device is arranged in the shell, and a steam outlet of the steam generating device is communicated with the steam inlet; and the conveying device is arranged in or outside the shell and conveys the materials to the first discharge hole from the second discharge hole. The technical scheme of the invention can shorten the cooking time of the materials in the food processor, improve the cooking efficiency and bring convenience to users.

Description

Enzyme killing device and food processor

Technical Field

The invention relates to the technical field of food processors, in particular to an enzyme deactivation device and a food processor using the same.

Background

With the continuous improvement of the life quality of people, food processors, such as soymilk makers, are also becoming more popular in people's daily life. However, conventional food materials, such as soybean materials, contain various anti-nutritional factors such as lipoxygenase, urease, trypsin inhibitor, and prothrombin, and therefore cannot be eaten raw, and heat treatment is required to inactivate the enzymes. Otherwise, not only the sensory quality and the nutritional value of the soybean milk are affected, but also the health of eaters is harmed. Therefore, in the conventional soymilk machine, the process of preparing soymilk generally comprises the steps of placing soybean raw materials in a cup body of a stirring cup assembly, carrying out heat treatment before stirring to complete an enzyme deactivation process, and then carrying out stirring to prepare soymilk. Obviously, since the enzyme deactivation process and the soymilk making process are both completed in the cup body of the blender cup, the soymilk making process takes a long time, which is very inconvenient for most users who are nervous in the morning.

Disclosure of Invention

The invention mainly aims to provide an enzyme deactivation device, aiming at shortening the cooking time of materials in a food cooking machine, improving the cooking efficiency and bringing convenience to users.

In order to achieve the above object, the present invention provides an enzyme deactivation apparatus for deactivating enzyme in a material, comprising:

the shell is provided with a first discharge hole;

the storage tank is made of metal and arranged in the shell, an enzyme deactivation cavity is formed in the storage tank, and a steam inlet and a second discharge hole are formed in the cavity wall of the enzyme deactivation cavity;

the steam generating device is arranged in the shell, and a steam outlet of the steam generating device is communicated with the steam inlet;

and the conveying device is arranged in or outside the shell and conveys the materials to the first discharge hole from the second discharge hole.

Optionally, the housing comprises:

the steam generating device and the conveying device are arranged in the accommodating cavity, a relief opening is formed in the upper end of the bottom shell, one end of the storage box is located in the accommodating cavity, the other end of the storage box penetrates through the relief opening, and a first discharge hole communicated with the accommodating cavity is formed in the lower end of the bottom shell;

and the top cover covers the upper end of the bottom shell.

Optionally, the top cover is movably connected to the bottom shell, and the top cover is movable relative to the bottom shell to expose or hide the storage box.

Optionally, the storage box comprises:

the lower end of the box body is positioned in the accommodating cavity, the upper end of the box body penetrates through the yielding port, and the upper end of the box body is provided with a feeding port;

the cover body covers the feeding opening and is enclosed with the box body to form the enzyme deactivation cavity.

Optionally, the cover is connected to the top cover.

Optionally, the cavity wall of the enzyme inactivating cavity is further provided with a steam outlet communicated with the outside.

Optionally, the storage box further comprises a heating component arranged in the enzyme deactivation chamber.

Optionally, the storage box further comprises a stirring assembly arranged in the enzyme deactivation cavity.

Optionally, the enzyme deactivation device further comprises a driving assembly, and the driving assembly drives the stirring assembly to stir the material in the enzyme deactivation cavity.

Optionally, a connecting portion is convexly provided at the lower end of the outer shell.

Optionally, the conveying device comprises at least two operating states: a material receiving state and a material leaking state;

the conveying device is used for taking materials from the second discharge hole in the material receiving state, and the conveying device is used for discharging materials to the first discharge hole in the material leakage state.

Optionally, the conveying device includes a rotary table and a conveying cylinder disposed on the rotary table, and the rotary table is rotatably disposed on the housing and located below the storage box;

when the conveying device is in the material receiving state, the conveying cylinder rotates to the position that the upper end of the conveying cylinder is communicated with the second discharge hole so as to take materials;

when the conveying device is in the material leakage state, the conveying cylinder rotates to the position that the lower end of the conveying cylinder is communicated with the second discharge hole to discharge materials.

The invention also provides a food processor, which comprises a host machine, a stirring cup assembly and an enzyme deactivation device, wherein the enzyme deactivation device comprises:

the shell is provided with a first discharge hole;

the storage tank is made of metal and arranged in the shell, an enzyme deactivation cavity is formed in the storage tank, and a steam inlet and a second discharge hole are formed in the cavity wall of the enzyme deactivation cavity;

the steam generating device is arranged in the shell, and a steam outlet of the steam generating device is communicated with the steam inlet;

the conveying device is arranged in or outside the shell and conveys the materials from the second discharge hole to the first discharge hole;

the stirring cup assembly is arranged on the host machine, the enzyme deactivation device is arranged on the host machine, and a first discharge hole of the enzyme deactivation device is communicated with an inner cavity of the stirring cup assembly.

Optionally, the enzyme deactivation device is movably connected with the host; and/or the enzyme deactivation device is detachably connected with the host machine.

According to the technical scheme, the storage box and the steam generating device are arranged in the shell, and the steam outlet of the steam generating device is communicated with the steam inlet of the enzyme deactivation cavity of the storage box, so that high-temperature steam can be generated by the steam generating device and is guided into the enzyme deactivation cavity of the storage box, and therefore the high-temperature steam can be used for carrying out enzyme deactivation treatment on materials to be cooked in the enzyme deactivation cavity. Meanwhile, according to the technical scheme, the first discharge hole is formed in the shell, the second discharge hole is formed in the cavity wall of the enzyme deactivation cavity of the storage box, and the conveying device is arranged in the shell, so that the conveying device can be used for conveying the materials in the enzyme deactivation cavity, which are subjected to the enzyme deactivation treatment process, to the first discharge hole, is guided out, and then the materials are used for the subsequent processing process of the food processor. Like this, independent come out in the cup of stirring cup subassembly with the enzyme deactivation processing procedure of current food processor, the cup that makes food processor's enzyme deactivation processing procedure no longer occupy stirring cup subassembly to make food processor's stirring processing procedure and enzyme deactivation processing procedure can go on simultaneously, and then shortened the cooking time of material in the food processor, promoted cooking efficiency, for the user brings the facility.

In addition, according to the technical scheme of the invention, the enzyme deactivation treatment process of a large number of materials can be simultaneously carried out in the enzyme deactivation cavity, and the single conveying capacity of the conveying device can be quantitatively designed, so that the batch quantitative derivation process of the materials which are subjected to the enzyme deactivation treatment process in the enzyme deactivation cavity can be realized, the material treatment capacity of the food processor is controlled, unnecessary waste is avoided, the actual requirements of users are further met, and the food processor is convenient for the users to use. (in addition, the food materials after enzyme deactivation can be stored in the enzyme deactivation cavity, and when the food materials are needed to be eaten, the food materials which are stored in the enzyme deactivation cavity and are subjected to enzyme deactivation are directly conveyed into the stirring cup to be directly stirred with boiled water, so that the steam treatment time can be saved, and the pulping time can be further shortened.)

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the structures shown in the drawings without creative efforts.

FIG. 1 is a schematic structural diagram of a food processor according to an embodiment of the present invention;

FIG. 2 is a cross-sectional view of the enzyme deactivation device of FIG. 1;

FIG. 3 is a schematic structural view of the conveying device in FIG. 2 when the conveying device stops conveying the materials;

FIG. 4 is a schematic view of the conveyor of FIG. 2 taking material from a second outlet;

FIG. 5 is a schematic structural view of the conveying device in FIG. 2 discharging to the first discharge port;

FIG. 6 is a cross-sectional view of the blender cup assembly and host machine of FIG. 1;

FIG. 7 is a top view of the food processor of FIG. 1;

FIG. 8 is a schematic structural diagram of the disassembly and assembly of the inverted stirring cup assembly after the enzyme deactivation device in FIG. 7 rotates.

The reference numbers illustrate:

reference numerals	Name (R)	Reference numerals	Name (R)
				100	Enzyme deactivation device	55	Steam outlet pipe
10	Outer casing	70	Conveying device
				10a	Containing cavity	71	Rotary disc
11	Top cover	73	Conveying cylinder
				13	Bottom shell	80	Drive assembly
131	First discharge hole	90	Connecting part
				30	Storage box	200	Main unit
30a	Enzyme inactivating cavity	210	Casing (CN)
				31	Cover body	210a	Mounting hole
311	Steam outlet	220	Stirring motor assembly
				33	Box body	230	Heating system
331	Steam inlet	230a	Water pump
				333	Second discharge hole	230b	Heating device
335	Feeding port	240	Water tank
				35	Heating assembly	300	Stirring cup assembly
37	Stirring assembly	310	Cup cover
				39	Steam exhaust channel	310a	Feed inlet
50	Steam generating device	320	Cup body
				51	Water inlet pipe	1000	Food processor
53	Steam generator

The implementation, functional features and advantages of the objects of the present invention will be further explained with reference to the accompanying drawings.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

It should be noted that all the directional indicators (such as up, down, left, right, front, and rear … …) in the embodiment of the present invention are only used to explain the relative position relationship between the components, the movement situation, etc. in a specific posture (as shown in the drawing), and if the specific posture is changed, the directional indicator is changed accordingly.

In addition, the descriptions related to "first", "second", etc. in the present invention are only for descriptive purposes and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In the description of the present invention, "a plurality" means at least two, e.g., two, three, etc., unless specifically limited otherwise.

In the present invention, unless otherwise expressly stated or limited, the terms "connected," "secured," and the like are to be construed broadly, and for example, "secured" may be a fixed connection, a removable connection, or an integral part; can be mechanically or electrically connected; they may be directly connected or indirectly connected through intervening media, or they may be connected internally or in any other suitable relationship, unless expressly stated otherwise. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

In addition, the technical solutions in the embodiments of the present invention may be combined with each other, but it must be based on the realization of those skilled in the art, and when the technical solutions are contradictory or cannot be realized, such a combination of technical solutions should not be considered to exist, and is not within the protection scope of the present invention.

The invention provides an enzyme deactivation device 100, which is used for carrying out enzyme deactivation treatment on materials (food raw materials) so as to shorten the cooking time of the materials in a food processor 1000, improve the cooking efficiency and bring convenience to users.

As shown in fig. 1, fig. 2, and fig. 6, in an embodiment of the enzyme deactivation apparatus 100 of the present invention, the enzyme deactivation apparatus 100 includes:

the shell 10 is provided with a first discharge hole 131;

the storage tank 30 is made of metal, the storage tank 30 is arranged in the shell 10, an enzyme deactivation cavity 30a is formed in the storage tank 30, and a steam inlet 331 and a second discharge hole 333 are formed in the cavity wall of the enzyme deactivation cavity 30 a;

the steam generating device 50 is arranged in the shell 10, and a steam outlet of the steam generating device 50 is communicated with the steam inlet 331;

the conveying device 70 is arranged in or outside the housing 10, and the conveying device 70 conveys the material from the second discharge hole 333 to the first discharge hole 131.

In this embodiment, the housing 10 includes a top cover 11 and a bottom shell 13, a containing cavity 10a is formed in the bottom shell 13, the steam generating device 50 and the conveying device 70 are disposed in the containing cavity 10a, a position-giving opening is formed in the upper end of the bottom shell 13, one end of the storage box 30 is located in the containing cavity 10a, and the other end of the storage box penetrates through the position-giving opening. The top cover 11 can be covered on the upper end of the bottom shell 13 in an opening and closing manner, when the top cover 11 is opened, the storage box 30 in the shell 10 is exposed, and at the moment, a user can add materials to be cooked into the storage box 30; when the top cover 11 is closed, the storage tank 30 in the housing 10 is hidden, and at this time, other components of the enzyme deactivation device 100 can operate, so that the enzyme deactivation treatment is performed on the material to be cooked in the storage tank 30. Further, a first discharge hole 131 communicated with the accommodating cavity 10a is formed in the lower end (bottom wall) of the bottom shell 13, and the first discharge hole 131 is used for guiding out the material in the enzyme deactivation device 100, which has completed the enzyme deactivation process.

An enzyme deactivation chamber 30a is formed in the storage tank 30 for storing materials such as soybeans to be cooked and providing a place for the enzyme deactivation process of high temperature steam. The storage box 30 includes a cover 31 and a box body 33, the lower end of the box body 33 is located in the accommodating cavity 10a of the bottom case 13, the upper end of the box body 33 penetrates through the position-giving opening at the upper end of the bottom case 13, and the feeding opening 335 is formed at the upper end of the box body 33. The cover 31 is openably covered on the feeding port 335 at the upper end of the box 33 and forms an enzyme deactivation chamber 30a with the box 33. When the cover body 31 is opened, the enzyme deactivation cavity 30a is opened, and at the moment, a user can add materials to be cooked into the enzyme deactivation cavity 30 a; when the cover 31 is closed, the enzyme deactivation cavity 30a is closed, and at this time, other components of the enzyme deactivation device 100 can operate, so that the enzyme deactivation treatment is performed on the material to be cooked in the enzyme deactivation cavity 30 a. And, still be equipped with the sealing washer between lid 31 and the box 33, this sealing washer can seal the gap that covers the department between lid 31 and the box 33 to avoid high temperature steam escape to cause the erosion of other components and parts and the reduction of enzyme efficiency that goes out. It can be understood that, in order to further strengthen the sealing reliability of the sealing ring, the sealing ring can be made of rubber or silica gel, so that the deformation of the material per se is utilized, and the sealing effect is effectively improved. Further, a second discharge hole 333 is formed in the lower end (bottom wall) of the box 33, and the second discharge hole 333 is used for guiding out the material in the enzyme deactivation chamber 30a, which has completed the enzyme deactivation process. A steam inlet 331 is opened in a side portion (side wall) of the case 33, and the steam inlet 331 is used to introduce high-temperature steam into the enzyme deactivation chamber 30 a.

It should be noted that box 33 of storage box 30 and bottom case 13 of housing 10 (or cover 31 of storage box 30 and top case 11 of housing 10) may be assembled by separately manufacturing two relatively independent components, for example, box 33 and cover 31 are made of metal such as stainless steel, and bottom case 13 and top case 11 are made of plastic; for example, the box 33 and the bottom case 13 may be formed integrally as a stainless steel structure, and the lid 31 and the top cover 11 may be formed integrally as a stainless steel structure. The technical scheme of the enzyme deactivation device is adopted in the embodiment, so that the enzyme deactivation device 100 is lighter in weight and more convenient to use, and devices, components and parts in the enzyme deactivation device 100 can be more simply and easily disassembled and replaced.

The steam generating device 50 comprises a water inlet pipe 51, a steam outlet pipe 55 and a steam generator 53, wherein the water inlet pipe 51 is provided with a water inlet, and the steam outlet pipe 55 is provided with a steam outlet. The water inlet pipe 51 is communicated with an outlet end of the water pump for delivering water in the water tank 240 or tap water to the steam generator 53; the steam generator 53 can convert water into high-temperature steam, and the converted high-temperature steam is led out through the steam outlet pipe 55; the steam outlet of the steam outlet pipe 55 is communicated with the steam inlet 331 of the enzyme deactivation cavity 30a, and is used for guiding high-temperature steam into the enzyme deactivation cavity 30a, so that the high-temperature steam is in contact with the material to be cooked, and thus, the high-temperature steam is utilized to perform enzyme deactivation treatment on multiple anti-nutritional factors such as lipoxygenase, urease, trypsin inhibitor, prothrombin and the like in the material to be cooked, and further, the taste of the material is richer, and the sweetness is higher. It is understood that the water tank 240 may be built in the enzyme deactivation device 100, for example, the water tank 240 is installed in the accommodating cavity 10a of the bottom case 13; or externally placed in the food processor 1000 or outside; it is also possible to directly pipe a household faucet to the water inlet pipe 51 without using a water tank.

The transport device 70 comprises at least two operating states: a material receiving state and a material leaking state, wherein the conveying device 70 takes materials from the second material outlet 333 when in the material receiving state; the conveying device 70 discharges the material to the first discharge port 131 in the material leakage state.

Specifically, the conveying device 70 comprises a rotary disc 71 and a conveying cylinder 73 arranged on the rotary disc 71, wherein the rotary disc 71 is rotatably arranged on the housing 10 and is positioned below the storage box 30;

when the conveying device 70 is in the material receiving state, the conveying cylinder 73 rotates until the upper end thereof is communicated with the second discharge hole 333 to take materials;

when the conveying device 70 is in a material leakage state, the conveying cylinder 73 rotates to the lower end thereof to be communicated with the second discharge hole 333 for discharging.

More specifically, the conveying device 70 includes a rotary disc 71, a conveying cylinder 73, and a driving motor, wherein the rotary disc 71 is rotatably mounted on the bottom wall of the bottom case 13 and located below the box body 33. The conveying cylinder 73 is a cylindrical structure with two open ends, the upper end opening is used for falling materials, and the lower end opening is used for leaking materials. The conveying cylinder 73 is partially positioned below the rotary disc 71, the upper end of the conveying cylinder is fixedly connected to the rotary disc 71, and the upper end opening of the conveying cylinder is communicated to the upper surface of the rotary disc 71. The driving motor is used for driving the rotary disc 71 to rotate, and it can be understood that the driving motor can drive the edge of the rotary disc 71 by means of the meshing of the gear ring and the gear ring, so as to enable the rotary disc 71 to rotate, and can also directly drive the rotary disc 71 to rotate by means of an output shaft fixed at the center of the rotary disc 71. Further, the upper surface of the rotary disc 71 is attached to the outer surface of the bottom wall of the box body 33, so that the rotary disc 71 can seal the second discharge hole 333 in the bottom wall of the box body 33, and the bottom wall of the box body 33 can seal the upper end opening of the conveying cylinder 73 (when the upper end opening of the conveying cylinder 73 is removed to be communicated with the second discharge hole 333 in the bottom wall of the box body 33), so that the material to be cooked in the enzyme deactivation cavity 30a cannot leak out; the lower end of the conveying cylinder 73 abuts against the bottom wall of the bottom case 13, so that the bottom wall of the bottom case 13 can close the lower end opening of the conveying cylinder 73 (when the lower end opening of the conveying cylinder 73 is removed to communicate with the first discharge port 131 of the bottom wall of the bottom case 13), and the materials in the conveying cylinder 73 which have been subjected to the enzyme deactivation process cannot leak out.

Specifically, as shown in fig. 2 to 5, the conveying cylinder 73 rotates with the turntable 71 to form a rotation path, and the conveying cylinder 73 has two positions, a receiving position and a leakage position, on the rotation path. When the conveying cylinder 73 rotates to the receiving position, the upper opening of the conveying cylinder is communicated with the second discharging hole 333 in the bottom wall of the box body 33, the lower opening of the conveying cylinder is blocked by the bottom wall of the bottom shell 13, and the material in the enzyme deactivation chamber 30a which has completed the enzyme deactivation process falls into the conveying cylinder 73. When the conveying cylinder 73 rotates to the material leakage position, the lower end opening of the conveying cylinder is communicated with the first material outlet 131 on the bottom wall of the bottom shell 13, the upper end opening of the conveying cylinder is blocked by the bottom wall of the box body 33, the second material outlet 333 on the bottom wall of the box body 33 is blocked by the rotary disc 71, and the material which is in the conveying cylinder 73 and has finished the enzyme deactivation process leaks from the first material outlet 131. It can be understood that the material that has been discharged from the first discharge hole 131 and has been processed by the enzyme deactivation process can enter the cup body 320 of the blending cup assembly 300 of the food processor 1000 for subsequent operations. Also, the transporting cylinder 73 may be designed to have a certain capacity, for example, the loaded soybeans can just make a cup of soybean milk, etc., so that the materials in the enzyme deactivation chamber 30a, which have completed the enzyme deactivation process, can be taken out in batches and used.

Of course, in other embodiments, the conveying device 70 may also be a conveying cylinder 73 with an upper opening and a lower opening, and when the opening and closing door at the upper opening of the conveying cylinder 73 is opened and the opening and closing door at the lower opening of the conveying cylinder 73 is closed, the conveying cylinder 73 may be used for receiving the material from the second material outlet 333; when the opening and closing door at the upper end opening of the conveying cylinder 73 is closed and the opening and closing door at the lower end opening of the conveying cylinder 73 is opened, the conveying cylinder 73 can be used for leaking materials to the first discharging hole 131. In addition, the movement of the conveying cylinder 73 between the first discharge port 131 and the second discharge port 333 may be realized by screw transmission, pneumatic or electric telescopic rod transmission, or other reasonable displacement modes, in addition to the rotation of the turntable 71. In addition, the relative positions of the second discharge hole 333 and the first discharge hole 131 may be reasonably arranged according to the difference of the conveying device 70 in practical application, for example, when the conveying device 70 is the conveying cylinder 73 with a door opening and closing up and down, the first discharge hole 131 and the second discharge hole 333 may be overlapped in the vertical direction, and the conveying cylinder 73 may be located between the first discharge hole 131 and the second discharge hole 333. Thus, the moving mechanism of the transport cylinder 73 can be eliminated, the internal structure of the enzyme deactivation device 100 can be simplified, the number of manufacturing processes can be reduced, and the assembly process can be shortened.

Therefore, it can be understood that, according to the technical solution of the present invention, the storage tank 30 and the steam generating device 50 are disposed in the housing 10, and the steam outlet of the steam generating device 50 is communicated with the steam inlet 331 of the enzyme deactivation chamber 30a of the storage tank 30, so that the steam generating device 50 can be used to generate high-temperature steam, and the high-temperature steam is introduced into the enzyme deactivation chamber 30a of the storage tank 30, so that the high-temperature steam can be used to perform enzyme deactivation on the material to be cooked in the enzyme deactivation chamber 30 a. Meanwhile, according to the technical scheme of the invention, the first discharge hole 131 is formed in the housing 10, the second discharge hole 333 is formed in the cavity wall of the enzyme deactivation cavity 30a of the storage box 30, and the conveying device 70 is arranged in the housing 10, so that the conveying device 70 can be used for conveying the material in the enzyme deactivation cavity 30a, which is subjected to the enzyme deactivation treatment process, from the second discharge hole 333 to the first discharge hole 131, so as to be guided out, and then the material is used for the subsequent processing process of the food processor 1000. Like this, the enzyme deactivation course of handling current food processor 1000 has been independent from the cup 320 of stirring cup subassembly 300, i.e. the enzyme deactivation course of handling food processor 1000 no longer occupies the cup 320 of stirring cup subassembly 300, thereby make the stirring course and the enzyme deactivation course of handling food processor 1000 go on simultaneously, and then shortened the cooking time of material in the food processor 1000, promoted cooking efficiency, bring the facility for the user.

In addition, according to the technical scheme of the invention, because the enzyme deactivation processing process of a large number of materials can be simultaneously carried out in the enzyme deactivation cavity 30a, and the single conveying amount of the conveying device 70 can be quantitatively designed, the batch quantitative leading-out process of the materials which are subjected to the enzyme deactivation processing process in the enzyme deactivation cavity 30a can be realized, so that the material processing amount of the food processor 1000 is controlled, unnecessary waste is avoided, the actual requirements of users are further met, and the use by the users is facilitated. (in addition, the food materials after enzyme deactivation can be stored in the enzyme deactivation cavity, and when the food materials are needed to be eaten, the food materials which are stored in the enzyme deactivation cavity and are subjected to enzyme deactivation are directly conveyed into the stirring cup to be directly stirred with boiled water, so that the steam treatment time can be saved, and the pulping time can be further shortened.)

As shown in fig. 1, 2 and 6, the top cover 11 is movably connected to the bottom shell 13, and the top cover 11 is movable relative to the bottom shell 13 to expose or hide the storage box 30. Specifically, the movement mode may be rotation or movement (specifically, movement may be achieved by a screw transmission mechanism, a telescopic transmission mechanism, or the like). In this embodiment, the rear end of the top cover 11 is rotatably connected to the rear end of the bottom case 13 in a hinged manner, and of course, the rotatable connection between the top cover 11 and the bottom case 13 can also be realized in other manners, such as a pivot connection. The top cover 11 rotates relative to the bottom shell 13 and has two positions, namely an open position and a closed position, when the top cover 11 is located at the open position, the storage box 30 is exposed, and a user can add materials to be cooked into the storage box 30 through a corresponding structure (such as a feeding port 335) at the upper end of the storage box 30; when the top cover 11 is in the closed position, the storage tank 30 is hidden, and the steam generating device 50 and the conveying device 70 in the bottom shell 13 can start to operate, so that the materials to be cooked are subjected to enzyme deactivation treatment and are conveyed outwards. Thus, the top cover 11 is connected to the bottom case 13 when being opened or closed, so as to avoid the operation that the top cover 11 needs to be additionally arranged after being opened, and further improve the convenience of the enzyme deactivation device 100 and the food processor 1000 using the enzyme deactivation device 100.

In addition, it should be noted that, when the top cover 11 is located at the closed position, the front end of the top cover 11 can be limited by a fastening structure, so as to effectively reduce the possibility that the top cover 11 is accidentally opened, and ensure the normal operation of the enzyme deactivation device 100. For example, the fastening structure may include a fastening piece rotatably connected to the bottom case 13 and a fastening groove formed in the top cover 11, and a free end of the fastening piece is fastened into the fastening groove to limit the top cover 11; the free end of the buckle piece is separated from the buckle slot, and the release of the top cover 11 is realized.

Further, the cover 31 is connected to the top cover 11. Therefore, the opening of the cover body 31 and the opening of the enzyme deactivation cavity 30a can be easily realized by utilizing the opening process of the top cover 11, so that the tedious process that the cover body 31 needs to be continuously opened after the top cover 11 is opened is avoided, the operation of the enzyme deactivation device 100 is further simplified, and convenience is brought to users. It will be appreciated that the cover 31 may be removably or non-removably attached to the top cover 11. The present embodiment adopts the former technical solution, so that it is not only convenient to clean the cover 31, but also convenient to arrange related components or structures in the enzyme deactivation device 100, such as sensors, circuits, circuit boards, and pressure relief structures.

Furthermore, the cavity wall of the enzyme deactivation cavity 30a is further provided with a steam outlet 311 communicated with the outside. In this embodiment, the steam outlet 311 is opened in the cover 31 of the storage tank 30, and the surface of the cover 31 facing away from the tank body 33 of the storage tank 30 is provided with the steam discharge passage 39 in a protruding manner. The lower end of the steam exhaust channel 39 is communicated with the steam outlet 311, that is, the lower end of the steam exhaust channel 39 is communicated with the enzyme deactivation chamber 30a through the steam outlet 311, and meanwhile, the upper end of the steam exhaust channel 39 penetrates through the top cover 11 of the casing 10 and is communicated with the outside. Thus, after the steam content in the enzyme deactivation chamber 30a reaches saturation, the excessive steam can be discharged to the external atmosphere through the steam outlet 311 and the steam discharge channel 39, so as to avoid the excessive steam pressure in the enzyme deactivation chamber 30a, and further avoid the structure collapse caused by the excessive steam pressure or the injury to the user when the cover 31 is opened.

As shown in fig. 1, 2 and 6, the storage tank 30 further includes a heater assembly 35 disposed in the enzyme deactivation chamber 30 a. Specifically, the heating component 35 may be a heating wire, a heating tube, a heating sheet, or the like, and is used for heating the inner space of the enzyme deactivation chamber 30a of the storage tank 30, so that the temperature of the steam in the enzyme deactivation chamber 30a of the storage tank 30 can be maintained above the set temperature for a long time, thereby shortening the time consumption of the enzyme deactivation process and improving the enzyme deactivation efficiency. In this embodiment, the heating element 35 is mounted on the lower surface of the cover 31 of the storage box 30 for easy assembly and disassembly.

As shown in fig. 1, 2 and 6, the storage tank 30 further includes a stirring assembly 37 disposed in the enzyme deactivation chamber 30 a.

In this embodiment, the stirring member 37 is a stirring rod installed on the bottom wall of the box body 33 of the storage box 30. One end of the stirring rod is located at the middle of the bottom wall of the case 33, and the other end extends toward the side wall of the case 33 and is close to the side wall of the case 33. The one end that the puddler is close to the box 33 lateral wall can be rotated around the one end that the puddler is located box 33 diapire middle part to stir the material when the enzyme process that goes out goes on, thereby greatly increase the contact frequency and the area of contact of material and high temperature steam, guarantee the thermally equivalent of material, avoid arousing the condition emergence that the material is burnt because of local high temperature, effectively promote the homogeneity and the efficiency of enzyme process that go out promptly, promote the practicality of product. It will be appreciated that the agitator arm may be powered for rotation by a drive motor.

Further, the enzyme deactivation device 100 further comprises a driving assembly 80, wherein the driving assembly 80 drives the stirring assembly 37 to stir the material in the enzyme deactivation chamber 30 a.

In this embodiment, the driving component 80 is a driving motor, which is installed on the bottom wall of the bottom casing 13 and located below the box body 33 of the storage box 30. The output shaft of driving motor runs through the diapire of storage box 30 box 33 to be connected with the one end that the puddler is located box 33 diapire middle part, rotate with the drive puddler, realize the stirring to the material. At this time, a through opening is opened in the middle of the turntable 71 of the conveying device 70, and the driving motor passes through the through opening, so that the rotation between the two is not influenced. It can be understood that the structure is reasonable, the processing technology is simple, the subsequent assembly, disassembly and maintenance are convenient, and the popularization is easy.

As shown in fig. 1, 2 and 6, a connecting portion 90 is protruded from a lower end of the housing 10 for connecting with a main body 200 of the food processor 1000, so as to mount and fix the enzyme deactivation device 100 to the main body 200 of the food processor 1000. Specifically, the top of the main body 200 of the food processor 1000 is provided with a mounting hole 210a, and the connecting portion 90 at the lower end of the housing 10 of the enzyme deactivation device 100 is inserted into and fixed in the mounting hole 210 a. So, can effectively promote the stability that enzyme device 100 installation that goes out is fixed in food processor 1000 host computer 200, guarantee going on smoothly of material course of working, bring the facility for user's use. (in addition, as shown in fig. 7 and 8, the enzyme deactivation device 100 can rotate or move relative to the main body 200, when the user needs to disassemble and assemble the blending cup assembly 300, the user can rotate or move the enzyme deactivation device 100 to one side of the main body 200, and the user can disassemble and assemble the blending cup assembly 300 vertically without interference of the housing 10. in addition, the enzyme deactivation device 100 can also move upwards relative to the main body 200 as long as enough space is reserved for disassembling and assembling the blending cup assembly 300.)

The present invention further provides a food processor 1000, the food processor 1000 includes a main machine 200, a stirring cup assembly 300, and an enzyme deactivation device 100, the specific structure of the enzyme deactivation device 100 refers to the above embodiments, and since the food processor 1000 adopts all technical solutions of all the above embodiments, all the beneficial effects brought by all the technical solutions of all the above embodiments are at least provided, and are not repeated herein. The stirring cup assembly 300 is arranged on the host machine 200, the enzyme deactivation device 100 is arranged on the host machine 200, and a first discharge hole 131 of the enzyme deactivation device 100 is communicated with an inner cavity of the stirring cup assembly 300.

Specifically, the blending cup assembly 300 includes a cup body 320 and a cup cover 310 covering the upper end of the cup body 320, the cup cover 310 is provided with a feed inlet 310a, and the first discharge port 131 of the enzyme deactivation device 100 is communicated with the inner cavity of the cup body 320 of the blending cup assembly 300 through the feed inlet 310a, so that the material leaked from the first discharge port 131 and having completed the enzyme deactivation process can smoothly enter the inner cavity of the cup body 320. Further, the main body 200 of the food processor 1000 comprises a casing 210, a stirring motor assembly 220, a heating system 230, and a water tank 240, wherein the stirring motor assembly 220 is installed in the casing 210, and an output shaft thereof is in transmission connection with a stirring blade of the stirring cup assembly 300; the heating system 230 is installed in the cabinet 210, the heating system 230 includes a water pump 230a and a heater 230b, an inlet end of the water pump 230a is communicated with the water tank 240, an outlet end of the water pump 230a is communicated with a water inlet end of the heater 230b, and a water outlet end of the heater 230b is communicated with the water inlet 310a of the stirring cup assembly 300, so as to guide water in the water tank 240 to the heater 230b for heating and guide hot water in the heater 230b to an inner cavity of the cup body 320 of the stirring cup assembly 300 when necessary, thereby assisting the food processor 1000 to complete corresponding processes. It is understood that the water tank 240 may be installed in the cabinet 210 or outside the cabinet 210. The latter technical solution is adopted in the present embodiment, which not only facilitates the assembly and disassembly of the water tank 240, but also facilitates the cleaning of the water tank 240 and the operation of adding water into the water tank 240.

In addition, it should be noted that the blending cup assembly 300 may be a grinding cup assembly, a fermentation cup assembly, a milling cup assembly or other cup 320 assemblies to achieve different purposes and functions.

Preferably, the enzyme deactivation device 100 is movably connected with the host 200; and/or the enzyme deactivation device 100 is detachably connected with the host 200.

Specifically, the movement mode may be rotation or movement (specifically, movement may be achieved by a screw transmission mechanism, a telescopic transmission mechanism, or the like).

As shown in fig. 7 and 8, in the present embodiment, the connecting portion 90 at the lower end of the housing 10 can rotate in the mounting hole 210a at the top of the main body 200 of the food processor 1000, so as to provide a space for the mixing cup assembly 300 to be assembled and disassembled, and the method is simple and convenient. In addition, the enzyme deactivation device 100 is detachably connected to the host 200, which is beneficial to the disassembly, assembly, cleaning and maintenance of the enzyme deactivation device 100.

It can be understood that the food processor of the present invention can be a soymilk maker, a wall breaking machine, a juice extractor, or others.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the scope of the present invention, and all modifications and equivalents of the present invention, which are made by the contents of the present specification and the accompanying drawings, or directly/indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims (14)

1. An enzyme deactivation device for performing enzyme deactivation treatment on materials, comprising:

the shell is provided with a first discharge hole;

the storage tank is made of metal and arranged in the shell, an enzyme deactivation cavity is formed in the storage tank, and a steam inlet and a second discharge hole are formed in the cavity wall of the enzyme deactivation cavity;

the steam generating device is arranged in the shell, and a steam outlet of the steam generating device is communicated with the steam inlet;

and the conveying device is arranged in or outside the shell and conveys the materials to the first discharge hole from the second discharge hole.

2. The enzyme deactivation device of claim 1 wherein said housing includes:

the steam generating device and the conveying device are arranged in the accommodating cavity, a relief opening is formed in the upper end of the bottom shell, one end of the storage box is located in the accommodating cavity, the other end of the storage box penetrates through the relief opening, and a first discharge hole communicated with the accommodating cavity is formed in the lower end of the bottom shell;

and the top cover covers the upper end of the bottom shell.

3. The enzyme deactivation device as claimed in claim 2, wherein said top cover is movably connected to said bottom housing, said top cover being movable relative to said bottom housing to expose or conceal said storage compartment.

4. The enzyme deactivation device as claimed in claim 2, wherein said storage tank includes:

the lower end of the box body is positioned in the accommodating cavity, the upper end of the box body penetrates through the yielding port, and the upper end of the box body is provided with a feeding port;

the cover body covers the feeding opening and is enclosed with the box body to form the enzyme deactivation cavity.

5. The enzyme deactivation device of claim 4 wherein said cover is attached to said cap.

6. The enzyme deactivation device according to claim 1, wherein the cavity wall of the enzyme deactivation chamber is further provided with a steam outlet communicated with the outside.

7. The enzyme deactivation device according to any one of claims 1 to 6, wherein said storage tank further comprises a heating element disposed in said enzyme deactivation chamber.

8. The enzyme deactivation device according to any one of claims 1 to 6, wherein said storage tank further comprises an agitation assembly disposed in said enzyme deactivation chamber.

9. The enzyme deactivation device of claim 8 further comprising a drive assembly, wherein said drive assembly drives said agitation assembly to agitate the material in said enzyme deactivation chamber.

10. The enzyme deactivation device according to any one of claims 1 to 6, wherein a connection portion is convexly provided at a lower end of the housing.

11. The enzyme deactivation device according to any one of claims 1 to 6, wherein said conveying means comprises at least two operating states: a material receiving state and a material leaking state;

the conveying device is used for taking materials from the second discharge hole in the material receiving state, and the conveying device is used for discharging materials to the first discharge hole in the material leakage state.

12. The enzyme deactivation device as claimed in claim 11, wherein said transportation means includes a turntable and a transportation cylinder disposed on said turntable, said turntable being rotatably mounted on said housing and located below said storage box;

when the conveying device is in the material receiving state, the conveying cylinder rotates to the position that the upper end of the conveying cylinder is communicated with the second discharge hole so as to take materials;

when the conveying device is in the material leakage state, the conveying cylinder rotates to the position that the lower end of the conveying cylinder is communicated with the second discharge hole to discharge materials.

13. A food processor, characterized in that, includes host computer, stirring cup subassembly and the enzyme device that goes out of any one of claims 1 to 12, the stirring cup subassembly is located the host computer, the enzyme device that goes out is located the host computer, the first discharge gate that goes out the enzyme device with the inner chamber intercommunication of stirring cup subassembly.

14. The food processor of claim 13, wherein the enzyme deactivation device is movably connected to the main machine; and/or the enzyme deactivation device is detachably connected with the host machine.