CN112137443A - Rotating head, rotating assembly, container and food processor - Google Patents

Abstract

The invention relates to the technical field of rotation, and provides a rotating head, a rotating assembly, a container and a food processor. The rotating head includes: the mounting sleeve is internally provided with a mounting hole with at least one open end; the rotary executing component is fixed outside the mounting sleeve; the lock cylinder mounting body is fixed in the mounting hole and is provided with a moving channel, and the moving channel has an extension amount along the rotating circumference of the rotary execution component; the lock core is movably arranged in the moving channel, part of the lock core is exposed out of the moving channel, the lock core moves in the moving channel in the positive direction to be locked, and the lock core moves in the moving channel in the reverse direction to be unlocked; the first magnetic piece is fixed at the end part of the mounting sleeve corresponding to the opening. This rotating head can prevent to drop from the drive shaft among the rotation process, when guaranteeing quick assembly disassembly, has still guaranteed the safety in utilization of product. The first magnetic part is fastened on the driving shaft to prevent the rotating head from sliding off the driving shaft under a specific working condition.

Description

Rotating head, rotating assembly, container and food processor

Technical Field

The invention relates to the technical field of rotation, in particular to a rotating head, a rotating assembly, a container and a food processor.

Background

With the development of science and technology, stirring equipment is increasingly applied to daily life of people, such as a flour-mixing machine, a soybean milk machine, a juice extractor, a wall breaking machine and the like. These agitated vessel all drive various stirring executive component rotations such as stirring sword, stirring hook, stirring claw through the drive shaft, stir the material automatically to realize the purpose such as cutting, smashing, even of material.

Because each part such as the stirring executive component, the stirring shaft, the container of the stirring equipment and the like can be contacted with the materials, the stirring executive component, the stirring shaft and the container are required to be fully cleaned at a specific time.

However, in some products of the prior art, the stirring implement is fixed on the driving shaft and located inside the container, and in order to clean the stirring device sufficiently, the user needs to spend a lot of time and effort to disassemble the stirring implement. Sometimes, in order to avoid disassembling the stirring execution part, even directly extending a hand into a stirring container of the stirring device for cleaning, the user is easily scratched by the stirring execution part on one hand, and cannot clean in many places on the other hand.

There are some products, its stirring executive component directly suit is on the stirring executive component and easy to detach, but this kind of mounting means is very high to the requirement of drive shaft, and once the drive shaft is uneven, can exert along the axial power of drive shaft to the stirring executive component, and then make the stirring executive component fly away the drive shaft, not only cause the damage to mixing equipment, also can cause the use accident. In addition, in order to make the driving shaft drive the stirring executing component to rotate, the driving shaft needs to be specially designed, and the driving shaft is guaranteed to be a non-revolving body.

Disclosure of Invention

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

One of the objects of the invention is: the utility model provides a rotating head, rotating assembly, container and food processor, solve the current rotatory executive component who conveniently dismantles that exists among the prior art and break away from and then lead to equipment to damage or even the problem of use accident easily from the drive shaft.

In order to achieve the object, the present invention provides a rotary head comprising:

the mounting sleeve is internally provided with a mounting hole, and at least one end of the mounting hole is provided with an opening;

a rotation executing component fixed outside the mounting sleeve;

a lock cylinder mounting body fixed in the mounting hole, and formed with a moving passage having an extension along a rotation circumference of the rotary actuator;

the lock cylinder is movably arranged in the moving channel, part of the lock cylinder is exposed out of the moving channel, the lock cylinder moves in the positive direction of the moving channel to be locked, and the lock cylinder moves in the reverse direction of the moving channel to be unlocked;

the first magnetic piece is fixed at the end part of the mounting sleeve corresponding to the opening.

In one embodiment, the first magnetic member is fixed at the opening, and the first magnetic member is fixed between the inner wall of the mounting hole and the outer wall of the lock cylinder mounting body.

In one embodiment, the first magnetic member is fixed at the opening, and the lock cylinder mounting body and the first magnetic member are sequentially arranged along the extending direction of the central axis of the mounting hole.

In one embodiment, an installation groove is formed on an end surface of the installation sleeve corresponding to the opening, and the first magnetic member is fixed in the installation groove.

In one embodiment, the cross section of the first magnetic member is annular, and the first magnetic member is provided with a through hole.

In one embodiment, the moving passage comprises a transition surface, the transition surface comprises a locking end and an unlocking end, and the distance between the transition surface and the central axis of the mounting hole is gradually increased from the locking end to the unlocking end; the lock cylinder is locked by moving towards the locking end, and the lock cylinder is unlocked by moving towards the unlocking end.

In one embodiment, a reset member is provided on the key cylinder mounting body, the reset member maintaining the home position of the key cylinder at the unlocking end.

In one embodiment, the reset component is an elastic member, a first end of the elastic member is fixed on the lock cylinder mounting body, a second end of the elastic member is connected with the lock cylinder, and the lock cylinder is located at the unlocking end when the elastic member is in a free state.

In one embodiment, the moving passage includes a circumferential surface, and the lock cylinder is positively locked for rotation and negatively unlocked for rotation.

In one embodiment, the key cylinder mounting body includes:

an outer ring;

the retainer is annular and matched with the outer ring, is coaxially arranged in the outer ring, and forms the moving channel between the retainer and the outer ring;

the lock core comprises rolling bodies which are arranged in one-to-one correspondence with the moving channels.

In one embodiment, the rolling elements are needles, rollers, balls or wedges.

In one embodiment, the mounting hole is closed at one end and is open at one end;

the rotary head further comprises:

the installation axle is fixed in the blind end of installation cover and with the installation cover is coaxial the installation axle with form first spacing step between the installation cover, rotatory executive component suit is in install epaxial and butt first spacing step.

In one embodiment, the fitting positions of the mounting shaft and the rotation executing component are non-rotary parts.

In one embodiment, the rotary head further comprises:

and the first stop piece is fixed on the mounting shaft and abuts the rotation executing component to the first limit step.

In one embodiment, the first stop is an elastic stop collar or a threaded sleeve with a hand-held portion formed at the end.

In one embodiment, the rotation performing part comprises one or more of a rotating knife, a rotating hook, a rotating claw, a rotating rod or a rotating paddle.

In order to achieve this object, the present invention provides a rotary assembly comprising a drive shaft and a rotary head, the rotary head being the rotary head described above, the drive shaft and rotary head being configured to:

the lock cylinder is in an unlocking state, the driving shaft enters the mounting hole, and the driving shaft rotates to drive the lock cylinder to move to a locking state;

the rotating assembly further comprises:

and the second magnetic part is fixed on the driving shaft, is opposite to the first magnetic part and is mutually attracted.

In one embodiment, the rotating assembly further comprises:

and the second stop piece is fixed on the driving shaft and is positioned on one side of the second magnetic piece, which is far away from the first magnetic piece.

In one embodiment, the second stopper is a circlip, a stopper step, a stopper projection, or a friction portion.

In order to achieve the purpose, the invention provides a container which comprises a container body and a rotating assembly, wherein the rotating assembly is the rotating assembly, one end of a driving shaft is installed at the bottom of the container body, and the other end of the driving shaft enters a lock cylinder installation body.

In order to achieve this object, the present invention provides a food processor comprising the above-mentioned container; the food processor is a soybean milk machine, a wall breaking machine, a juice extractor, an egg beater, a flour mixer, a food stirrer, an air fryer, a chopper, a shredder, a self-cooking pot, a frying pan, a soup making machine or a self-frying pan.

The technical scheme of the invention has the following advantages: the installation sleeve, the rotation execution component, the lock cylinder installation body, the lock cylinder and the first magnetic part of the rotating head are integrated. When mounting, only the rotating head needs to be directly mounted on the driving shaft. Along with the rotation of drive shaft, the drive shaft can drive the lock core and move to the locking state to realize the locking between rotating head and the drive shaft, prevent that rotatory in-process rotating head from droing from the drive shaft. After the rotating process is finished, the lock cylinder is unlocked under the action of external force, and then the rotating head and the driving shaft can be easily separated at the moment, so that the rotating head can be quickly detached. Therefore, the rotating head ensures the use safety of products while ensuring the quick disassembly and assembly, and prevents equipment from being damaged and using accidents from happening. Furthermore, the rotary head may be fastened to the drive shaft by means of a first magnetic element to prevent the rotary head from slipping off the drive shaft under certain operating conditions.

Furthermore, according to the rotating assembly, the rotating head is sleeved on the driving shaft in a pluggable manner, so that the rotating head is convenient to disassemble and assemble and clean. And the rotating head can tightly hold the driving shaft under the action of centripetal force in the rotating process, so that the use is safe.

Furthermore, the container is provided with the driving shaft and the rotating head which is detachable from the driving shaft in the container body, the rotating head is convenient to detach and clean the bottom of the container, residues are prevented from being accumulated on the bottom of the container, particularly the periphery of the bottom close to the driving shaft, the container can be thoroughly cleaned, no cleaning dead angle is formed, and pain points of users are solved.

Furthermore, the food processor of the invention adopts the container, and can also realize convenient disassembly of the rotating head, convenient disassembly and cleaning of the rotating head and convenient cleaning of the bottom of the food processor after the rotating head is disassembled, thereby realizing thorough cleaning of the food processor, having no cleaning dead angle and safe use.

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 drawings without creative efforts.

FIG. 1 is a schematic view of an assembly relationship of a mounting sleeve, a mounting shaft, a lock cylinder mounting body and a first magnetic member according to an embodiment of the present invention;

fig. 2 is a schematic structural view of a rotary head according to an embodiment of the present invention;

FIG. 3 is a schematic view of the transition surface of the lock cylinder mounting body and the assembly relationship of the lock cylinder in an unlocked state according to the embodiment of the present invention;

FIG. 4 is a schematic view of a transition surface of a lock cylinder mounting body and an assembly of a lock cylinder in a locked state according to an embodiment of the present invention;

FIG. 5 is a schematic illustration of the assembly of a lock cylinder mounting body and one of the wedge block lock cylinders in an embodiment of the present invention;

FIG. 6 is a schematic view of the assembly relationship between the peripheral surface of the key cylinder mounting body and the key cylinder in an unlocked state according to the embodiment of the present invention;

FIG. 7 is a schematic view showing the assembly relationship between the peripheral surface of the key cylinder mounting body and the key cylinder in a locked state according to the embodiment of the present invention;

FIG. 8 is a schematic illustration of the assembly of a plug mounting body and an alternative wedge lock cylinder according to an embodiment of the present invention;

FIG. 9 is a schematic illustration of the assembly of a lock cylinder mounting body and yet another wedge block lock cylinder in an embodiment of the present invention;

FIG. 10 is a schematic view illustrating an assembly relationship of the driving shaft, the second magnetic member and the second stopper according to the embodiment of the present invention;

FIG. 11 is a schematic structural view of a rotating assembly of an embodiment of the present invention;

in the figure: 1. installing a sleeve; 2. a lock cylinder mounting body; 201. a moving channel; 202. an outer ring; 203. mounting a bracket; 204. a transition surface; 3. a rotation executing part; 4. a drive shaft; 6. installing a shaft; 601. a first shaft section; 602. a second shaft section; 7. a first stopper; 8. a second magnetic member; 9. a second stopper; 10. a first magnetic member; 11. a lock cylinder; 12. a reset component; 13. a first limit step; 15. and a third limiting step.

Detailed Description

The embodiments of the present invention will be described in further detail with reference to the drawings and examples. The following examples are intended to illustrate the invention but are not intended to limit the scope of the invention.

In the description of the present invention, it should be noted that the terms "center", "longitudinal", "lateral", "up", "down", "front", "back", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", etc., indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "connected" and "connected" are to be interpreted broadly, e.g., as being fixed or detachable or integrally connected; can be mechanically or electrically connected; may be directly connected or indirectly connected through an intermediate. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Referring to fig. 1 to 3, the rotary head of the embodiment includes a mounting sleeve 1, a rotary actuator 3, a key cylinder mounting body 2, a key cylinder 11, and a first magnetic member 10. Wherein, the mounting sleeve 1 is internally provided with a mounting hole. The rotation executing component 3 is fixed outside the mounting sleeve 1. The key cylinder mounting body 2 is fixed in the mounting hole, and a moving passage 201 is formed, and the moving passage 201 has an extension along the rotation circumference of the rotation actuator. The lock core 11 is movably disposed in the moving channel 201, and a portion of the lock core is exposed out of the moving channel 201. The lock cylinder 11 is locked when the moving channel 201 moves forward; the lock cylinder 11 is unlocked when the moving passage 201 moves reversely. The first magnetic member 10 is fixed to the end of the mounting sleeve 1 corresponding to the opening.

Wherein "the moving channel 201 has an extension along the circumference of rotation of the rotary actuator" i.e. "the direction of extension of the moving channel 201 has a tangential component along the circumference of rotation of the rotary actuator 3" means that: when the rotary head and the driving shaft 4 are installed and the driving shaft 4 rotates along the set direction, the lock cylinder 11 can be driven to move forward along the moving channel 201 and be locked. That is, the moving passage 201 does not extend in a direction having only a component in the axial direction of the mounting hole or the radial direction of the rotation circumference, but has a component in the tangential direction of the rotation circumference. The "rotation circle" refers to an arbitrary circle having the central axis of the drive shaft 4 as the center axis.

In addition, references to "forward" and "reverse" in this document are only relative concepts. For example, the forward direction may be clockwise or counterclockwise, the forward direction may be leftward or rightward, or the forward or backward direction may be forward. When the direction of the forward representation is determined, the reverse representation is the direction opposite to the forward representation.

The mounting sleeve 1, the rotation executing component 3, the lock cylinder mounting body 2, the lock cylinder 11 and the first magnetic part 10 of the rotating head are integrated. When mounting, it is only necessary to mount the rotary head directly on the drive shaft 4. Along with the rotation of drive shaft 4, drive shaft 4 can drive lock core 11 motion for lock core 11 locking is in order to realize the locking between rotating head and the drive shaft 4, prevents that rotatory in-process rotating head from droing from drive shaft 4. After the rotation process is finished, the lock cylinder 11 is unlocked by reverse movement under the action of external force, and then the rotating head and the driving shaft 4 can be easily separated at the moment, so that the rotating head can be quickly detached. Therefore, the rotating head ensures the use safety of products while ensuring the quick disassembly and assembly, and prevents equipment from being damaged and using accidents from happening. Furthermore, the rotary head may be fastened to the drive shaft 4 by means of the first magnetic element 10 to prevent the rotary head from slipping off the drive shaft 4 under certain operating conditions.

Because the installation sleeve 1, the rotation executing component 3, the lock cylinder installation body 2, the lock cylinder 11 and the first magnetic part 10 are taken as a whole during the disassembly and assembly, namely the rotating head has no other redundant parts, the condition that one or more parts are forgotten in the disassembly and assembly process of the rotating head is avoided. The rotating head is fast to disassemble and assemble, a disassembling tool is not needed, and a user does not need to check whether the rotating head is disassembled and assembled in place after the rotating head is disassembled and assembled; and can be repeatedly disassembled and assembled. To the container of installing this kind of rotating head and even food processor, its dismantlement is convenient, in order to realize fully rinsing, need not to stretch out inside the hand gets into the container, consequently can avoid user's hand injured in the cleaning process, and safety in utilization promotes greatly.

The "first magnetic member 10 is fixed to the end of the corresponding opening of the mounting sleeve 1" includes: the two open ends of the mounting sleeve 1 are provided, and the first magnetic element 10 is fixed at only one open end; the two open ends of the mounting sleeve 1 are respectively fixed with the first magnetic part 10; and, the open end of the mounting sleeve 1 is one, and the first magnetic member 10 is fixed at the open end. The end of the mounting sleeve 1 corresponding to the opening is also the opening end of the mounting sleeve 1.

When the two open ends of the mounting sleeve 1 are provided with the first magnetic element 10, the driving shaft enters the mounting hole through any one of the two open ends, and the mounting between the driving shaft and the rotating head can be realized.

The first magnetic member 10 refers to an object that can react to a magnetic field in some way, and does not need to be able to generate a magnetic field by itself. The first magnetic member 10 can be made of any magnetic material, such as a magnet, mild steel, etc.; of course, the first magnetic member may be an energized coil. Also, the second magnetic member 8 mentioned later may be made of any magnetic material or may be in the form of an energized coil, and the specific form is not limited as long as the first magnetic member 10 and the second magnetic member 8 can generate magnetic attraction force.

The expression that the lock cylinder mounting body 2 is fixed in the mounting hole means that the lock cylinder mounting body 2 is tightly fixed in the mounting hole, and then the lock cylinder mounting body 2 cannot slide from the mounting sleeve 1 and cannot move in the mounting hole of the mounting sleeve 1.

In one embodiment, in order to fixedly mount the key cylinder mounting body 2 and the mounting sleeve 1, an interference fit is adopted between the outer surface of the key cylinder mounting body 2 and the mounting hole.

In another embodiment, in order to fixedly mount the key cylinder mounting body 2 and the mounting sleeve 1, the mounting sleeve 1 is made of an elastic material, and then when the key cylinder mounting body 2 is mounted in the mounting hole, the mounting sleeve 1 is tensioned to fasten the key cylinder mounting body 2 in the mounting hole.

Of course, the lock cylinder mounting body 2 can also be fixed in the mounting hole of the mounting sleeve 1 by any fixed connection method disclosed in the prior art.

The term "the first magnetic member 10 is fixed to the end of the mounting sleeve 1 corresponding to the opening" includes the following situations:

in the first situation, referring to fig. 1, the first magnetic member 10 is fixed in the installation hole and located at the opening, and the first magnetic member 10 is fixed between the inner wall of the installation hole and the outer wall of the lock cylinder installation body. In this case, the first magnetic member 10 is provided without increasing the size of the spin head in the center axis direction of the mounting hole. When installing this kind of rotating head to the drive epaxial, also can not increase the axial dimensions of drive shaft, and then can guarantee the stability in the middle of the rotating head course of work.

The inner side and the outer side of the space between the inner wall of the mounting hole and the outer wall of the lock cylinder mounting body are both based on the central axis of the mounting hole, the side close to the central axis is the inner side, and the side far away from the central axis is the outer side.

In the second situation, the first magnetic member 10 is fixed in the installation hole at the opening, and the lock cylinder installation body 2 and the first magnetic member 10 are sequentially arranged along the extension direction of the central axis of the installation hole. Referring to fig. 1, the first magnetic member 10 is fixed in the mounting hole and disposed below the key cylinder mounting body 2. In this case, since the size of the first magnetic member 10 only needs to be adapted to the mounting sleeve 1, and does not need to be adapted to the key cylinder mounting body 2, the selection of the first magnetic member 10 is more flexible.

In the third case, an installation groove is provided on the end surface of the installation sleeve corresponding to the opening. Referring to fig. 1, that is, an installation groove may be formed on the bottom end surface of the installation sleeve, so that the first magnetic member 10 is fixed in the installation groove. In this case, too, the first magnetic member 10 is provided without increasing the size of the spin head in the central axis direction of the mounting hole. When installing this kind of rotating head to the drive epaxial, also can not increase the axial dimensions of drive shaft, and then can guarantee the stability in the middle of the rotating head course of work.

The mounting groove can be an annular groove arranged on the outer edge of the opening of the mounting sleeve 1, and can also be any non-annular groove distributed along the outer edge of the opening. The structure and the number of the first magnetic members 10 are matched with those of the mounting grooves, so that the first magnetic members 10 can be fixed in the mounting grooves.

In the fourth situation, the first magnetic member 10 is sleeved outside the mounting sleeve 1 corresponding to the opening. Referring to fig. 1, the first magnetic member 10 is sleeved outside the mounting sleeve 1 and fixed to a bottom end of the mounting sleeve 1. In this case, too, the first magnetic member 10 is provided without increasing the size of the spin head in the central axis direction of the mounting hole. When installing this kind of rotating head to the drive epaxial, also can not increase the axial dimensions of drive shaft, and then can guarantee the stability in the middle of the rotating head course of work.

It should be noted that, in the above-mentioned installation situation of the first magnetic element 10, it is not required that the end surface of the first magnetic element 10 and the end surface of the installation sleeve 1 are necessarily flush, and the end surface of the first magnetic element 10 may be protruded or recessed relative to the end surface of the installation sleeve 1. In addition, the first magnetic part 10 and the mounting sleeve 1, and the first magnetic part 10 and the lock cylinder mounting body 2 can be fixed in an interference fit manner, and can also be fixed in a bonding, welding or clamping manner.

In one embodiment, the first magnetic member has a ring-shaped cross-section. The first magnetic member 10 with this structure can be sufficiently exposed to the magnetic field, so as to ensure the magnetic attraction of the magnetic member to the rotary head. Of course, the structural form of the first magnetic member 10 is not limited by the examples herein, and may be any shape as long as it can be installed to the end of the rotary head and used for attracting the corresponding magnetic member on the driving shaft. Furthermore, a penetrating hole is formed in the first magnetic part 10, and the first magnetic part can be sleeved outside the mounting sleeve through the penetrating hole; or, through setting up the dress hole of wearing, when first magnetic part set up inside the installation cover, drive shaft 4 can get into in the installation hole through wearing the dress hole.

Referring to fig. 3 and 4, in one embodiment, the moving channel 201 includes a transition surface 204, the transition surface 204 includes a locking end and an unlocking end, and the distance between the transition surface 204 and the central axis of the mounting hole gradually increases from the locking end to the unlocking end. Since the transition surface 204 includes a locking end and an unlocking end, it is known that the transition surface 204 actually functions to cooperate with the lock cylinder 11 to achieve locking or unlocking. It follows that the transition surface 204 is formed in the wall surface of the displacement channel facing the central axis of the mounting hole.

During installation, the driving shaft 4 drives the lock cylinder 11 to move in a forward direction, so that the lock cylinder 11 moves to the locking end. After the end of the rotation process, the lock cylinder 11 is moved back in the opposite direction by the external force to the unlocking end or to the vicinity of the unlocking end.

In the embodiment, the number of the moving channels 201, the transition surfaces 204 and the lock cylinder 11 is generally one-to-one. Of course, no special requirements are made on the distribution and specific number of the moving channels 201, the transition surfaces 204 and the lock cylinders 11 in the mounting holes, and it is only required that the lock cylinder mounting body 2 at least comprises one moving channel 201, and then at least one lock cylinder 11 can lock the driving shaft 4 when the driving shaft 4 rotates. Also, the shape of the key cylinder mounting body 2 is not particularly required, as long as the moving passage 201 can be formed in the key cylinder mounting body 2.

Here, a plurality of moving channels 201 may be formed in one key cylinder mounting body 2, or only one moving channel 201 may be formed in one key cylinder mounting body 2. When only one moving channel 201 is formed on one lock cylinder mounting body 2 and the number of the moving channels 201 is multiple, a plurality of lock cylinder mounting bodies 2 are distributed in the mounting hole.

In one embodiment, the key cylinder mounting body 2 is provided with a reset device 12, and the reset device 12 maintains the initial position of the key cylinder 11 at the unlocking end. Through the setting of reset part 12 for under the rotating head initial condition, lock core 11 is located the unblock end, and then makes things convenient for drive shaft 4 to get into the mounting hole. If the reset part 12 is not provided, the lock cylinder 11 may be located at the locking end at the beginning, and the rotary head is mounted on the driving shaft 4, so that the driving shaft 4 can enter the corresponding position of the mounting hole, an external force needs to be additionally applied to the lock cylinder 11 to move the lock cylinder 11 to the unlocking end.

Wherein, restoring element 12 may be a magnetic element or an elastic element. When restoring member 12 is a magnetic member: if the magnetic component and the lock cylinder 11 repel each other, the magnetic component is arranged at or near the locking end; when the magnetic member and the locking member are attracted to each other, the magnetic member is disposed at or near the unlocking end.

When the reset component 12 is an elastic component, a first end of the elastic component is fixed on the lock cylinder mounting body 2, a second end of the elastic component is connected with the lock cylinder 11, and the lock cylinder 11 is positioned at an unlocking end when the elastic component is in a free state. The term "the elastic member is in a free state" refers to a state in which the elastic member is not subjected to an external force, and the gravity of the elastic member can be ignored. Wherein, the reset piece can be a reset spring.

In one embodiment, referring to fig. 5-7, the travel path includes a circumferential surface, and the lock cylinder 11 is rotationally locked in a forward direction and rotationally unlocked in a reverse direction. Here, the lock cylinder 11 is rotated in the forward direction, which corresponds to the above-mentioned forward movement of the lock cylinder 11; the lock cylinder 11 is rotated in the reverse direction, i.e. in the reverse direction in correspondence with the above-mentioned lock cylinder 11. And the circumferential surface of the moving passage is coaxial with the drive shaft 4 to be assembled.

In one embodiment, the lock cylinder mounting body 2 includes an outer race 202 and a cage, and the lock cylinder 11 includes rolling bodies. The retainer is annular and is adapted to the outer ring 202, and is coaxially disposed in the outer ring 202, and a plurality of moving channels 201 are formed between the retainer and the outer ring 202. The rolling bodies are provided in one-to-one correspondence with the moving passages 201. When the rolling bodies move along the moving channel 201, the rolling body portions are exposed to the moving channel 201. When the driving shaft 4 is inserted into the mounting hole, the rolling bodies exposed to the moving passage 201 contact the driving shaft 4.

It is worth mentioning that when the lock cylinder mounting body 2 includes the outer race 202 and the retainer, and the lock cylinder 11 includes the rolling bodies, the lock cylinder mounting body 2 and the lock cylinder 11 can be regarded as a one-way bearing at this time. That is, a one-way bearing is provided inside the mounting sleeve 1. When the drive shaft 4 enters the mounting hole and enters the fitting hole of the one-way bearing, the rolling elements of the one-way bearing are in the unlocked state at this time. When the driving shaft 4 rotates towards the set direction, circumferential locking between the driving shaft 4 and the one-way bearing can be realized, and then the driving shaft 4 can drive the one-way bearing to rotate. In this case, the one-way bearing is equivalent to a one-way lock, and is locked with the drive shaft 4 only when the drive shaft 4 rotates in the set direction; instead, the one-way bearing is unlocked from the drive shaft 4.

When the drive shaft 4 drives the rotating head to rotate, the faster the rotating speed, the larger the centripetal force that the rolling element received, and then the locking force that the drive shaft 4 received is bigger, and it is more reliable to guarantee the rotating head installation. When the rotation speed of the driving shaft 4 is relatively low, although the locking force of the driving shaft 4 to the rotary head is relatively small, the locking force can also ensure the installation reliability of the rotary head due to the slow rotation speed of the driving shaft 4.

After the unidirectional bearing is assembled, the rolling bodies are exposed in the assembly holes of the unidirectional bearing. When the drive shaft 4 is inserted directly into the adapter bore, the rolling bodies come into contact with the side faces of the drive shaft 4, ensuring that there is no clearance between the drive shaft 4 and the assembly bore. Of course, a protective sleeve or other protective member may be provided around the drive shaft 4, and in this case, when the drive shaft 4 is inserted into the mounting hole, the rolling elements and the drive shaft 4 may not be in direct contact with each other. However, no matter what part is sleeved outside the driving shaft 4, the driving shaft 4 rotates along the set direction, the rolling bodies can be driven to move in the forward direction and be locked, the rolling bodies are tightly held on the periphery of the driving shaft 4, one-way locking of the one-way bearing is achieved, and therefore the rotating head is driven to rotate synchronously. When the drive shaft 4 drives the rolling bodies to move reversely, the one-way bearing is in an unlocked state, and the rotating head cannot rotate along with the drive shaft 4.

Taking the cylinder mounting body formed with the transition surface 204 as an example, when the driving shaft 4 drives the lock cylinder 11 to lock in the forward direction (i.e. rolling towards the lock end of the transition surface 204), the rolling bodies are held tightly around the outer circumference of the driving shaft 4. When the drive shaft 4 drives the rolling bodies to move reversely (i.e. roll towards the unlocking end of the transition surface 204) to unlock, the one-way bearing is in an unlocked state, and the rotating head cannot rotate along with the drive shaft 4.

The rolling bodies can be needle rollers, rolling shafts, rolling balls or wedge-shaped blocks and the like, and the types of the corresponding rolling bodies are selected according to the use occasions.

In fig. 5 to 7, the rolling elements are wedge shaped blocks. And, the specific structural form of the wedge block is not limited by the examples herein, for example, the wedge block may also be in the structural form in fig. 8 and 9.

Besides certain strength, the material of the retainer is preferably good in heat conductivity, small in friction factor, good in wear resistance, strong in impact toughness and close to a rolling body in linear expansion coefficient. The material of the retainer can be selected according to the specific application. For example, the cage is a low carbon steel/stainless steel cage, a bakelite/plastic cage, a brass/bronze/aluminum alloy cage, or the like.

When the reset device 12 is an elastic member and the key cylinder mounting body 2 includes the outer ring 202 and the retainer, the key cylinder mounting body 2 further includes a mounting bracket 203 for facilitating the mounting of the elastic member, and the mounting bracket 203 is fixed to the retainer and/or the outer ring 202. The mounting bracket 203 may be integrally formed with the outer ring 202 or may be integrally formed with the cage. Of course, the mounting bracket 203 may also be a separate component, and may be connected with the outer ring 202 and/or the holder by other connection methods such as plugging, clipping, and adhering. Moreover, the mounting bracket 203 may be in the form of a sheet, a block, a rod, etc., and the specific shape is not required as long as the elastic member can be conveniently mounted. In fig. 3 and 4, the mounting bracket 203 is arranged near the unlocking end of the transition surface 204 and is connected with one end of the elastic member, and the initial position of the rolling body is ensured at the unlocking end by the elasticity of the elastic member.

It should be noted that, in order to facilitate the movement of the lock cylinder 11, the transition surface 204 is generally a smooth transition surface, and the "smooth" in the "smooth transition surface" is a definition of the shape of the transition surface 204, but not a definition of the friction coefficient of the transition surface 204. And the smooth transition surface can be a plane or a cambered surface. Furthermore, when the lock cylinder 11 is a rolling member rather than a sliding member, the friction coefficient of the smooth transition surface should not be too low; conversely, when the lock cylinder 11 is a sliding member rather than a rolling member, the friction coefficient of the smooth transition surface should not be too high.

It should be noted that the transition surface 204 may also be directly formed on the inner wall of the mounting hole, in this case, the key cylinder mounting body 2 may be integrally formed with the mounting sleeve 1, and further, a moving passage 201 of the key cylinder 11 is formed inside the mounting sleeve 1.

Wherein the cross section of the mounting hole and the cross section of the drive shaft 4 may be of any shape. In order to ensure that the drive shaft 4 and the mounting hole are coaxial, the number of the lock cylinders 11 is preferably plural and evenly distributed between the drive shaft 4 and the mounting hole. Under this kind of circumstances, drive shaft 4 atress is balanced, can guarantee the stability in drive shaft 4 and the rotating head course of working. Of course, the distribution of the key cylinders 11 is determined by the key cylinder mounting body 2 formed with the moving passage 201.

When the cross section of the driving shaft 4 is circular, and the components of the lock cylinder installation body 2 and the lock cylinder 11 adopt the structural form of the one-way bearing, 360-degree omnibearing assembly can be realized by the driving shaft 4 and the rotating head at the moment, the installation angle does not need to be adjusted in the assembly process, and the rotating head is convenient to install.

It is worth mentioning that the mounting hole can be closed at one end and open at the other end, or both ends can be open.

When one end of the mounting hole is closed and the other end is opened, the rotating head further comprises a mounting shaft 6, the mounting shaft 6 is coaxial with the mounting sleeve 1, and a first limit step 13 is formed between the mounting shaft 6 and the mounting sleeve 1. It is clear that the end of the mounting sleeve 1 corresponding to the opening of the mounting hole is required for assembly with the drive shaft 4, and therefore the mounting shaft 6 cannot be fixed to this end. Thereby, the mounting shaft 6 is necessarily fixed to the closed end of the mounting sleeve 1 corresponding to the opening, and the first limit step 13 is formed between the mounting shaft 6 and the end face of the closed end of the mounting sleeve.

Wherein, the mounting shaft 6 and the mounting sleeve 1 can be integrally formed.

Referring to fig. 2 and 11, the rotation executing member 3 is fitted around the mounting shaft 6 and abuts against the first limit step 13. By the arrangement of the mounting shaft 6, and the formation of the first limit step 13, the mounting position of the rotation actuator 3 can be determined.

When the mounting shaft 6 is provided, the rotation actuator 3 is not directly fixed to the mounting sleeve 1, but is indirectly fixed to the outside of the mounting sleeve 1 via the mounting shaft 6. In addition, the present invention is intended to cover both the case of directly fixing the rotation actuator 3 to the outside of the mounting sleeve 1 and the case of indirectly fixing the rotation actuator to the outside of the mounting sleeve 1.

Wherein the outside of the mounting sleeve 1 corresponds to the inside of the mounting sleeve 1, and the mounting holes belong to the inside of the mounting sleeve 1.

In order to ensure that the mounting sleeve 1 rotates and the mounting shaft 6 drives the rotation executing component 3 to rotate, the matching parts of the mounting shaft 6 and the rotation executing component 3 are all provided with non-rotating parts so as to avoid the rotation of the rotation executing component 3 relative to the mounting shaft 6.

For example, the cross sections of the fitting parts of the mounting shaft 6 and the rotary actuator 3 may be polygonal, elliptical, irregular, etc.

Of course, when the fitting portions of the mounting shaft 6 and the rotation executing component 3 are all provided as rotating portions, the circumferential locking of the mounting shaft 6 and the rotation executing component 3 can also be realized by additionally using a locking member or a fastening connection manner, so as to prevent the rotation executing component 3 from rotating relative to the mounting shaft 6.

In order to prevent the axial play of the rotary actuator 3 along the mounting shaft 6, a first stop 7 may be additionally provided. Specifically, the first stopper 7 is fixed on the mounting shaft 6 and abuts the rotation executing member 3 to the first limit step 13.

The first stopper 7 may be an elastic stop collar having a certain elasticity. In the installation process, the rotation executing component 3 can be firstly arranged at the first limit step 13, and then the elastic limit sleeve is fixed on the installation shaft 6, so that the end part of the elastic limit sleeve contacts the rotation executing component 3 to prevent the rotation executing component 3 from axially moving along the installation shaft 6. Or, the rotation executing component 3 and the elastic limiting sleeve may be mounted on the mounting shaft 6 first, and then the elastic limiting sleeve is moved toward the first limiting step 13 until the rotation executing component 3 abuts against the first limiting step 13 and the elastic limiting sleeve abuts against the rotation executing component 3.

The first stop 7 may also be a threaded sleeve. At this time, the mounting shaft 6 is formed with an external thread matching the internal thread of the threaded sleeve. Further, the threaded sleeve is rotated to move the threaded sleeve on the mounting shaft 6, and finally the purpose of locking the rotation actuator 3 is achieved.

Wherein, elasticity stop collar and threaded sleeve all can be formed with handheld portion at the tip to make things convenient for its dismouting of installing axle 6 relatively. And, through the setting of handheld portion, contact rotatory executive component 3 in the time of can avoiding dismouting first stop part 7, and then guarantee safety in utilization to avoid rotatory executive component 3 to be collided with.

Of course, the first stopper 7 is not a necessary component. For example, the rotary actuator 3 may be welded to the mounting shaft 6. Alternatively, the rotary actuator 3 may be formed with an opening that is an interference fit with the mounting shaft 6.

Further, the mounting shaft 6 is a stepped shaft, comprising a first shaft section 601 and a second shaft section 602. Wherein the rotation executing part 3 is mounted on the first shaft section 601 and the first stopper 7 is mounted on the second shaft section 602. The rationality of the arrangement of the rotation performing part 3 and the first stopper 7 can be further ensured by using a stepped shaft.

When the lock cylinder installation body 2 and the mounting hole shape phase-match, can be formed with the spacing step of second (not shown in the middle of the attached drawing) in the mounting hole this moment, 2 terminal surfaces of the lock cylinder installation body butt the spacing step of second, and then still have certain clearance between 2 terminal surfaces of the lock cylinder installation body and the 1 terminal surface of installation cover. When the driving shaft 4 enters the installation sleeve 1, the driving shaft can completely pass through the lock cylinder installation body 2 and enter the gap, and therefore the lock cylinder installation body 2 and the driving shaft 4 are fully matched.

Wherein, the 'shape matching of the lock cylinder mounting body 2 and the mounting hole' refers to: when the mounting hole is a cylindrical hole, the external profile of the lock cylinder mounting body 2 is also in a corresponding cylindrical shape; when the mounting hole is a rectangular column hole, the external profile of the lock cylinder mounting body 2 is also in a corresponding rectangular column shape; when the mounting hole is a special-shaped column hole, the external profile of the lock cylinder mounting body 2 is also in a corresponding special-shaped column shape. When the mounting hole is the cylinder hole, and the external profile of the lock cylinder mounting body 2 is also corresponding cylindricly, adopt interference fit between lock cylinder mounting body 2 and the mounting hole this moment preferentially to avoid the lock cylinder mounting body 2 and the mounting hole to take place relative rotation.

In addition, a third limit step 15 can be formed in the mounting hole, and the end face of the first magnetic part 10 abuts against the third limit step 15. Further, the mounting position of the first magnetic member may be defined by the third limit step 15.

The above-mentioned rotation executing component 3 may be one or more of a rotating knife, a rotating hook, a rotating claw, a rotating rod, or a rotating paddle, and is not limited by examples herein. For example, for products such as a soybean milk machine, a wall breaking machine, a juice extractor and the like, the rotary executing component 3 generally adopts a rotary knife; the rotary executing component 3 of the products such as a flour-mixing machine, a pretreatment system of crop fermentation raw materials, a powder coating mixing machine and the like generally adopts a rotary hook; for products such as a superhard abrasive material rotating machine, an eggbeater, a food processer, a biological fertilizer rotating machine and the like, the rotating execution part 3 generally adopts a rotating claw; in addition, a rotary rod and a rotary blade are often used as the rotary actuator 3 in blenders, reaction vessels, and blenders.

In one embodiment, the invention provides a rotating assembly comprising a drive shaft 4 and a rotary head as described above, the drive shaft 4 entering the mounting hole of the rotary head being locked by a lock cylinder 11, and the drive shaft 4 and the rotary head being quickly detachable from each other.

To this kind of rotating assembly, the rotating head is established on drive shaft 4 with pluggable ground cover, makes things convenient for the rotating head to dismantle and install, and the rotating head of being convenient for washs safe in utilization. And the rotating head can tightly hold the driving shaft 4 under the action of centripetal force in the rotating process, so that the use is safe.

Wherein, in order to provide magnetic attraction force to the rotary head, so that the rotary head is attracted to the driving shaft 4 by the magnetic attraction force, a second magnetic member 8 is disposed on the driving shaft 4, please refer to fig. 10. The second magnetic member 8 is configured to: after the rotary head is mounted on the driving shaft 4, the second magnetic member 8 is disposed opposite to the first magnetic member 10 and attracted to each other. That is, when the driving shaft 4 and the rotary head are mounted, the second magnetic member 8 and the first magnetic member 10 generate a magnetic attraction force attracting each other by a magnetic field, see fig. 11.

Referring further to fig. 11, a certain gap may exist between the first magnetic member 10 and the second magnetic member 8, so as to prevent the first magnetic member 10 and the second magnetic member 8 from generating a frictional force when they are directly contacted with each other. Moreover, a certain gap is reserved between the first magnetic element 10 and the second magnetic element 8, and a sealing member, such as a sealing gasket, located between the first magnetic element 10 and the second magnetic element 8 can be additionally provided. Further, a gap between the first magnetic member 10 and the second magnetic member 8 is not necessarily present.

The specific material of the first magnetic member 10 and the second magnetic member 8 is not limited. In one embodiment, the first magnetic member 10 is made of mild steel, the second magnetic member 8 is made of a magnet, and the first magnetic member 10 and the magnet made of mild steel generate an attractive force.

In one embodiment, the rotation assembly further comprises a second stop 9, see fig. 10 and 11. The second stopper 9 is fixed to the drive shaft 4 on a side of the second magnetic member 8 away from the first magnetic member 10, that is, in fig. 10 and 11, the second stopper 9 is located on a lower side of the second magnetic member 8. By the arrangement of the second stopper 9, the mounting position of the second magnetic member 8 on the driving shaft 4, and thus the relative position of the first magnetic member 10 and the second magnetic member 8, can be ensured.

The second stopper 9 may be any structure protruding from the surface of the driving shaft 4, such as a circlip, a stopper step, a stopper protrusion, or the like mounted on the driving shaft 4. Of course, the second stopper 9 may also be a friction portion, such as a corresponding pattern formed on the surface of the driving shaft 4 by an embossing process or a knurling process, so that the pattern provides a friction force to the second magnetic member to prevent the second magnetic member from falling off from the driving shaft 4. When the second stop member is an elastic check ring, a clamping groove is formed in the corresponding position of the driving shaft 4, and the elastic check ring is fixed in the clamping groove.

In one embodiment, there is provided an assembly process of the above-described rotating assembly, including:

the lock core mounting body 2 and the first magnetic part 10 are pressed into the mounting holes in sequence; mounting the rotation executing component 3 on the mounting shaft 6, and fixing the rotation executing component on the mounting shaft 6 through a first stop member 7 to obtain an assembled rotating head;

mounting the second stopper 9 on the driving shaft 4, sleeving the second magnetic member 8 on the driving shaft 4, and applying a force to the second magnetic member 8 along the axial direction of the driving shaft 4, so that the end of the second magnetic member 8 abuts against the second stopper 9;

the rotating head is installed on the driving shaft 4, so that the driving shaft 4 enters the installation hole, the driving shaft 4 rotates along the set direction to drive the lock cylinder to move to the locking end, one-way locking is achieved between the driving shaft 4 and the lock cylinder installation body 2, and a rotating assembly which is assembled is obtained.

The above resulting rotating assembly may be applied to a range of speeds from low to high of 1 RPM (acronym for Revoltations Per Minute, i.e., RPM) to 40000 RPM.

In one embodiment, a container is provided, comprising a container body and the above-mentioned rotating assembly, and the rotating assembly is mounted on the container body.

It is worth mentioning that one container can be provided with a plurality of rotating heads which can be replaced quickly, since the rotating heads and the driving shaft 4 are easy to disassemble and assemble. Specifically, the rotary actuator 3 of the rotary head is different for different machining functions. And through above-mentioned quick change rotating head, can realize that the processing of rotating equipment is diversified, satisfy different users' multiple processing demand.

For example, the same product may be simultaneously provided with the first rotating head for soymilk making, the second rotating head for juicing, the third rotating head for wall breaking, and the fourth rotating head … … for dough making, so that the functions of the product can be rapidly switched among different functions such as soymilk making, juicing, wall breaking, dough making, and the like by rapidly replacing the first rotating head, the second rotating head, the third rotating head, and the fourth rotating head … ….

In one embodiment, one end of the drive shaft 4 is mounted to the bottom of the container body and the other end of the drive shaft 4 enters the cylinder mounting body 2. Furthermore, the obtained rotating assembly extends upwards to the space of the container body from the bottom of the container body so as to rotate and process the materials in the container body.

This kind of container, through set up drive shaft 4 in the container body and with the 4 detachable rotating heads of drive shaft, the rotating head is convenient for dismantle the washing with the rotating head, also is convenient for the rotating head to dismantle the bottom of back washing container, avoids the residue to gather around the bottom of container especially is close to drive shaft 4 to can thoroughly wash the container, do not wash the dead angle, solve user's pain point.

It is worth mentioning that when the rotating assembly extends upwards from the bottom of the container body to the space of the container body, and the rotating head includes the first magnetic member 10, the second magnetic member 8 is mounted on the driving shaft 4: the container is tilted, and the first magnetic member 10 and the second magnetic member 8 are magnetically attracted to each other, so that the rotating head is prevented from slipping off.

Of course, the driving shaft 4 is not necessarily installed at the bottom of the container body. For example, for many rotating devices, the rotating assembly is often extended downward from the top of the container body, such that one end of the drive shaft 4 is mounted on the top of the container body, and the other end of the drive shaft 4 enters the container body and is connected to the rotating head. Similarly, the end of the driving shaft 4 may be mounted on the sidewall of the container body to meet different use requirements.

In one embodiment, a food processor is provided comprising the above-mentioned container. The food processor can be a soymilk maker, a wall breaking machine, a juice extractor, an eggbeater, a flour mixer, a food stirrer, an air fryer, a chopper, a shredder, a self-cooking pot, a frying pot, a soup maker or a self-frying pot. Of course, the variety of food processor is not limited by the examples herein, but may also be any other product disclosed in the prior art and including a container.

The container may be applied to rotary apparatuses in various fields such as medical fields, chemical fields, municipal engineering fields, and the like, in addition to food processors.

To above-mentioned food processor, adopt above-mentioned container, can realize the rotating head convenient dismantlement equally, be convenient for pull down the washing with the rotating head, also be convenient for the rotating head pull down the bottom of back washing food processor to can realize thoroughly cleaning food processor, not rinse the dead angle, safe in utilization moreover can not cut user's finger, promoted the ability of the price overflow of user's satisfaction and product.

The above embodiments are merely illustrative of the present invention and are not to be construed as limiting the invention. Although the present invention has been described in detail with reference to the embodiments, it should be understood by those skilled in the art that various combinations, modifications or equivalents may be made to the technical solution of the present invention without departing from the spirit and scope of the technical solution of the present invention, and the technical solution of the present invention is covered by the claims of the present invention.

Claims (21)

1. A rotary head, comprising:

the mounting sleeve is internally provided with a mounting hole, and at least one end of the mounting hole is provided with an opening;

a rotation executing component fixed outside the mounting sleeve;

a lock cylinder mounting body fixed in the mounting hole, and formed with a moving passage having an extension along a rotation circumference of the rotary actuator;

the lock cylinder is movably arranged in the moving channel, part of the lock cylinder is exposed out of the moving channel, the lock cylinder moves in the positive direction of the moving channel to be locked, and the lock cylinder moves in the reverse direction of the moving channel to be unlocked;

the first magnetic piece is fixed at the end part of the mounting sleeve corresponding to the opening.

2. The rotary head according to claim 1, wherein the first magnetic member is fixed at the opening, and the first magnetic member is fixed between an inner wall of the mounting hole and an outer wall of the lock cylinder mounting body.

3. The rotary head according to claim 1, wherein the first magnetic member is fixed to the opening, and the key cylinder mounting body and the first magnetic member are disposed in sequence along a direction of extension of a central axis of the mounting hole.

4. The rotary head according to claim 1, wherein a mounting groove is formed on an end surface of the mounting sleeve corresponding to the opening, and the first magnetic member is fixed in the mounting groove.

5. The rotating head according to claim 1, wherein the first magnetic member has a ring-shaped cross section and has a through hole.

6. The rotary head according to claim 1, wherein the moving channel comprises a transition surface comprising a locking end and an unlocking end, a distance between the transition surface and a central axis of the mounting hole gradually increasing in a direction from the locking end to the unlocking end; the lock cylinder is locked by moving towards the locking end, and the lock cylinder is unlocked by moving towards the unlocking end.

7. The rotary head according to claim 6, wherein a reset member is provided on the key cylinder mounting body, the reset member maintaining an initial position of the key cylinder at the unlocking end.

8. The rotary head according to claim 7, wherein the restoring member is an elastic member, a first end of the elastic member is fixed to the key cylinder mounting body, a second end of the elastic member is connected to the key cylinder, and the key cylinder is located at the unlocking end when the elastic member is in a free state.

9. The rotary head of claim 1, wherein the translation channel comprises a circumferential surface, and the lock cylinder is rotationally locked in a forward direction and rotationally unlocked in a reverse direction.

10. The rotary head according to any one of claims 1 to 9, wherein the key cylinder mounting body comprises:

an outer ring;

the retainer is annular and matched with the outer ring, is coaxially arranged in the outer ring, and forms the moving channel between the retainer and the outer ring;

the lock core comprises rolling bodies which are arranged in one-to-one correspondence with the moving channels.

11. The rotary head of claim 10, wherein the rolling elements are needles, rollers, balls, or wedges.

12. The rotary head according to any one of claims 1 to 9, wherein the mounting hole is closed at one end and open at the other end;

the rotary head further comprises:

the installation axle is fixed in the blind end of installation cover and with the installation cover is coaxial the installation axle with form first spacing step between the installation cover, rotatory executive component suit is in install epaxial and butt first spacing step.

13. The rotary head of claim 12, wherein the engagement of the mounting shaft with the rotary actuator is non-return.

14. The rotary head according to claim 12, further comprising:

and the first stop piece is fixed on the mounting shaft and abuts the rotation executing component to the first limit step.

15. The rotary head according to claim 14, wherein the first stop is an elastic stop collar or a threaded sleeve having a hand grip formed at an end thereof.

16. The rotating head according to any one of claims 1 to 9, wherein the rotation performing part comprises one or any more of a rotating knife, a rotating hook, a rotating claw, a rotating stick, or a rotating blade.

17. A rotating assembly comprising a drive shaft and a rotating head, wherein the rotating head is according to any of claims 1 to 16, the drive shaft and rotating head being configured to:

the lock cylinder is in an unlocking state, the driving shaft enters the mounting hole, and the driving shaft rotates to drive the lock cylinder to move to a locking state;

the rotating assembly further comprises:

and the second magnetic part is fixed on the driving shaft, is opposite to the first magnetic part and is mutually attracted.

18. The rotating assembly of claim 17, further comprising:

and the second stop piece is fixed on the driving shaft and is positioned on one side of the second magnetic piece, which is far away from the first magnetic piece.

19. The rotating assembly of claim 18, wherein the second stop is a circlip, a stop step, a stop protrusion, or a friction portion.

20. A container comprising a container body and a spinner assembly, wherein the spinner assembly is as claimed in any one of claims 17 to 19, and the drive shaft is mounted at one end to the bottom of the container body and at the other end into the cylinder mounting body.

21. A food processor comprising the container of claim 20; the food processor is a soybean milk machine, a wall breaking machine, a juice extractor, an egg beater, a flour mixer, a food stirrer, an air fryer, a chopper, a shredder, a self-cooking pot, a frying pan, a soup making machine or a self-frying pan.

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