CN111904248B - Bidirectional rotary juicer - Google Patents

Abstract

The invention discloses a bidirectional rotary juicer which comprises a main cylinder type shell. The invention utilizes the coaxial technology, can convert the rotation in one direction into the rotation in two opposite directions, so that the direction for the rotation of the blade is opposite to the direction for the rotating plate at the bottom, the relative rotation is generated, the fruit juice which is internally stirred and juiced is driven to rotate in two directions, the fruit can be cut by the rotary drive of the blade, the internal fruit juice is discharged, under the influence of gravity, fruit particles falling on the surface of the rotating plate can play a role of rapid friction under the action of the reverse rotation, then the fruit particles move towards the edge under the action of centrifugal force, the large particles move towards the right upper part of the blade under the action of a curved structure, and fall on the blade part again under the action of the gravity to be cut, and the quality of a finished product is improved.

Description

Bidirectional rotary juicer

Technical Field

The invention relates to the technical field of juicers, in particular to a bidirectional rotary juicer.

Background

At present, when the existing juicer is used for juicing, because the corner at the bottom is a dead angle, the fruit moving to the corner cannot be further stirred and juiced, and the effect is poor.

Disclosure of Invention

The present invention is directed to a bidirectional rotary juicer to solve the above problems.

In order to achieve the purpose, the invention provides the following technical scheme: a bidirectional rotary juicer comprises a main cylindrical shell, wherein a plurality of supporting legs are arranged at the bottom edge of the main cylindrical shell, a bottom supporting plate is arranged at the inner side of the bottom ends of the supporting legs, a cover-free juicing space is arranged at the center of the main cylindrical shell, a sealing space is arranged at the inner side of the top of the juicing space, a sealing cover is arranged in the sealing space, a rotating plate is arranged at the top of the sealing cover, a driving motor mounting shell is arranged at the center of the upper surface of the bottom supporting plate, a driving motor is arranged in the driving motor mounting shell, the shaft body end part of the driving motor is connected with a gear type coaxial turnover mechanism through a main connecting plate, the side surface of the gear type coaxial turnover mechanism is fixed on a structure in the middle of the supporting legs through a main connecting rod, the bottom of the main cylindrical shell is penetrated through by a main rotating shaft, and a sealing ring and a bearing are arranged between the main rotating shaft and the main rotating shaft, the main rotating shaft is positioned at the bottom of the main cylinder type shell and is provided with a bottom rotating plate, a main groove structure is arranged at the center of the bottom rotating plate, a plurality of curved structures are arranged on the side surface of the main groove structure of the bottom rotating plate, shaft holes are formed in the center parts of the bottom rotating plate and the main rotating shaft, an auxiliary rotating shaft is arranged in each shaft hole through a sealing ring and a bearing, a cutting blade is arranged at one end, positioned in the main groove structure, of each auxiliary rotating shaft, and the bottom ends of the auxiliary rotating shafts and the bottom ends of the main rotating shafts are fixedly connected with two rotating shafts of the gear type coaxial turnover mechanism respectively.

Further, a plurality of the curved structures are arranged in an annular array, and the number of the curved structures is even.

Further, the curved structure (20) is a linear structure which is inclined upwards, and in operation, particles move towards the right upper part of the cutting blade under the action of the curved structure.

Further, the gear type coaxial turnover mechanism includes a hollow housing for the gear type coaxial turnover mechanism, a component mounting space for the gear type coaxial turnover mechanism, a first rotation shaft for the gear type coaxial turnover mechanism, a second rotation shaft for the gear type coaxial turnover mechanism, a connecting plate for the gear type coaxial turnover mechanism, a hollow structure for the gear type coaxial turnover mechanism, a first gear for the gear type coaxial turnover mechanism, a second gear for the gear type coaxial turnover mechanism, a through hole for the gear type coaxial turnover mechanism, and a third gear for the gear type coaxial turnover mechanism.

Further, a gear type coaxial turnover mechanism component mounting space is provided in the center inside the hollow housing for the gear type coaxial turnover mechanism, a gear type coaxial turnover mechanism first rotation shaft is mounted on one side of the hollow housing for the gear type coaxial turnover mechanism through a bearing, a gear type coaxial turnover mechanism connecting plate is mounted on one end of the first rotation shaft outside, a gear type coaxial turnover mechanism first gear is mounted on a shaft body inside the gear type coaxial turnover mechanism component mounting space through the first rotation shaft, a gear type coaxial turnover mechanism second rotation shaft is mounted on the other side of the hollow housing for the gear type coaxial turnover mechanism through a bearing, a gear type coaxial turnover mechanism hollow structure is provided in the center inside the second rotation shaft, the gear type coaxial turnover mechanism is characterized in that one end of the second rotating shaft positioned inside the gear type coaxial turnover mechanism is provided with a second gear for the gear type coaxial turnover mechanism, the gear type coaxial turnover mechanism is provided with a through hole for the gear type coaxial turnover mechanism at the center of a second gear, the gear type coaxial turnover mechanism is inserted into the hollow structure for the gear type coaxial turnover mechanism and the through hole for the gear type coaxial turnover mechanism by using the shaft body of the first rotating shaft, the other two opposite side surfaces of the hollow shell of the gear type coaxial turnover mechanism are respectively provided with a rotating shaft through a bearing, and the opposite ends of the two rotating shafts are respectively provided with a gear type coaxial turnover mechanism third gear, and the opposite parts of the gear type coaxial turnover mechanism third gear are respectively meshed with the gear structures in the gear type coaxial turnover mechanism first gear and the gear type coaxial turnover mechanism second gear through the gear structures.

Furthermore, the gear type coaxial turnover mechanism is fixedly connected with the main connecting plate through a connecting plate.

Furthermore, the connecting end parts of the first rotating shaft for the gear type coaxial turnover mechanism and the second rotating shaft for the gear type coaxial turnover mechanism are respectively and fixedly connected with the end parts of the main rotating shaft and the auxiliary rotating shaft.

Compared with the prior art, the invention has the beneficial effects that: the invention utilizes the coaxial technology, can convert the rotation in one direction into the rotation in two opposite directions, so that the direction for the rotation of the blade is opposite to the direction for the rotating plate at the bottom, the relative rotation is generated, the fruit juice which is internally stirred and juiced is driven to rotate in two directions, the fruit can be cut by the rotary drive of the blade, the internal fruit juice is discharged, under the influence of gravity, fruit particles falling on the surface of the rotating plate can play a role of rapid friction under the action of the reverse rotation, then the fruit particles move towards the edge under the action of centrifugal force, the large particles move towards the right upper part of the blade under the action of a curved structure, and fall on the blade part again under the action of the gravity to be cut, and the quality of a finished product is improved.

Drawings

FIG. 1 is a schematic view of a bi-directional rotary juicer according to the present invention in full section;

FIG. 2 is a schematic top view of a bottom rotating plate in a bi-directional rotary juicer of the present invention;

FIG. 3 is a schematic structural view of a gear type coaxial turnover mechanism in the bidirectional rotary juicer of the invention;

in the figure: 1, a main cylindrical housing, 2, a juicing space, 3, a sealed space, 4, a sealing cap, 5, a rotary plate, 6, a bottom support plate, 7, a drive motor mounting housing, 8, a drive motor, 9, a main connecting plate, 10, a main connecting rod, 11, a gear-type coaxial tilting mechanism, 111, a hollow housing for a gear-type coaxial tilting mechanism, 112, a component mounting space for a gear-type coaxial tilting mechanism, 113, a first rotating shaft for a gear-type coaxial tilting mechanism, 114, a second rotating shaft for a gear-type coaxial tilting mechanism, 115, a connecting plate for a gear-type coaxial tilting mechanism, 116, a hollow structure for a gear-type coaxial tilting mechanism, 117, a first gear for a gear-type coaxial tilting mechanism, 118, a second gear for a gear-type coaxial tilting mechanism, 119, a through hole for a gear-type coaxial tilting mechanism, 1110, a third gear for a gear-type coaxial tilting mechanism, a third gear, a sealing cap, 5, a sealing cap, a rotating plate, 6, 7, a sealing cap, a sealing the bottom of a sealing cap, a sealing the housing, a sealing cap, a sealing the housing, a sealing cap, a cap, 12, a main rotating shaft, 13, shaft holes, 14, an auxiliary rotating shaft, 15, bottom rotating plates, 16, sealing rings, 17, a main groove structure, 19, cutting blades, 20 and a curved structure.

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.

Referring to fig. 1-2, an embodiment of the present invention is shown: the juicer comprises a main cylinder type shell 1, wherein a plurality of supporting legs are arranged at the bottom edge of the main cylinder type shell 1, a bottom supporting plate 6 is arranged at the inner side of the bottom end of the plurality of supporting legs, a cover-free juicing space 2 is arranged at the center of the main cylinder type shell 1, a sealed space 3 is arranged at the inner side of the top of the juicing space 2, a sealed cover 4 is arranged in the sealed space 3, a rotating plate 5 is arranged at the top of the sealed cover 4, a driving motor mounting shell 7 is arranged at the center of the upper surface of the bottom supporting plate 6, a driving motor 8 is arranged in the driving motor mounting shell 7, the shaft body end part of the driving motor 8 is connected with a gear type coaxial turnover mechanism 11 through a main connecting plate 9, the side surface of the gear type coaxial turnover mechanism 11 is fixed on the structure in the middle part of the supporting legs through a main connecting rod 10, and the bottom of the main cylinder type shell 1 is penetrated through a main rotating shaft 12, a sealing ring 16 and a bearing are arranged between the two parts which penetrate through the main rotary shaft 12, a bottom rotary plate 15 is arranged at the bottom of the main cylinder type shell 1 on the main rotary shaft 12, a main groove structure 17 is arranged at the center of the bottom rotary plate 15, a plurality of curved structures 20 are arranged on the side surface of the main groove structure 17 on the bottom rotary plate 15, shaft holes 13 are arranged at the center parts of the bottom rotary plate 15 and the main rotary shaft 12, an auxiliary rotary shaft 14 is arranged in the shaft holes 13 through the sealing ring 16 and the bearing, a cutting blade 19 is arranged at one end of the auxiliary rotary shaft 14 in the main groove structure 17, and the bottom ends of the auxiliary rotary shaft 14 and the main rotary shaft 12 are respectively fixedly connected with two rotary shafts of the gear type coaxial turnover mechanism 11; a plurality of said curved structures 20, arranged in an annular array and in an even number; the curved formation 20 is an upwardly inclined line formation and in operation, particles are moved directly above the cutting blade 19 by the action of the curved formation 20.

Referring to fig. 1 to 3, the gear-type coaxial turnover mechanism 11 includes a hollow housing 111 for the gear-type coaxial turnover mechanism, a component mounting space 112 for the gear-type coaxial turnover mechanism, a first rotating shaft 113 for the gear-type coaxial turnover mechanism, a second rotating shaft 114 for the gear-type coaxial turnover mechanism, a connecting plate 115 for the gear-type coaxial turnover mechanism, a hollow structure 116 for the gear-type coaxial turnover mechanism, a first gear 117 for the gear-type coaxial turnover mechanism, a second gear 118 for the gear-type coaxial turnover mechanism, a through hole 119 for the gear-type coaxial turnover mechanism, and a third gear 1110 for the gear-type coaxial turnover mechanism; a gear type coaxial turnover mechanism component mounting space 112 is provided at the center inside the gear type coaxial turnover mechanism hollow housing 111, a gear type coaxial turnover mechanism first rotating shaft 113 is mounted on one side of the gear type coaxial turnover mechanism hollow housing 111 through a bearing, a gear type coaxial turnover mechanism connecting plate 115 is mounted on the outside end of the gear type coaxial turnover mechanism first rotating shaft 113, a gear type coaxial turnover mechanism first gear 117 is mounted on the shaft body inside the gear type coaxial turnover mechanism component mounting space 112 through the gear type coaxial turnover mechanism hollow housing 111, a gear type coaxial turnover mechanism second rotating shaft 114 is mounted on the other side of the gear type coaxial turnover mechanism hollow housing 111 through a bearing, a gear type coaxial turnover mechanism hollow structure 116 is provided at the center inside the gear type coaxial turnover mechanism second rotating shaft 114, the second rotating shaft 114 for the gear type coaxial turnover mechanism is provided with a second gear 118 for the gear type coaxial turnover mechanism at one end located inside, the gear type coaxial turnover mechanism is provided with a through hole 119 for the gear type coaxial turnover mechanism at the center of a second gear 118, the gear type coaxial turnover mechanism is inserted with the shaft body of the first rotating shaft 113 into the hollow structure 116 for the gear type coaxial turnover mechanism and the through hole 119 for the gear type coaxial turnover mechanism, the other two opposite side surfaces of the hollow shell 111 for the gear type coaxial turnover mechanism are respectively provided with a rotating shaft through a bearing, the opposite ends of the two rotating shafts are respectively provided with a third gear 1110 for the gear type coaxial turnover mechanism, and the opposite parts of the third gear 1110 for the two gear type coaxial turnover mechanisms are respectively meshed with the gear structures in the first gear 117 for the gear type coaxial turnover mechanism and the second gear 118 for the gear type coaxial turnover mechanism through the gear structures; the gear type coaxial turnover mechanism is fixedly connected with the main connecting plate 9 through a connecting plate 115; the connection end portions of the first rotating shaft 113 for the gear-type coaxial turnover mechanism and the second rotating shaft 114 for the gear-type coaxial turnover mechanism are fixedly connected to the end portions of the main rotating shaft 12 and the sub rotating shaft 13, respectively.

The specific use mode is as follows: in the invention, the sealing cover 4 is opened, the juice to be extracted is put into the extracting space 2, then the driving motor 8 is opened, the gear type coaxial turnover mechanism 11 works under the action of the motor to enable the motor to generate rotation in two directions, the main rotating shaft 12 and the auxiliary rotating shaft 14 are respectively driven to do reverse rotation movement, the cutting blade 19 and the bottom rotating plate 15 reversely rotate under the linkage action, the rotation driving of the cutting blade 19 can enable the fruit to be cut, the juice in the fruit is discharged, under the influence of gravity, fruit particles falling on the surface of the bottom rotating plate 15 can play a role of rapid friction under the reverse rotation action, then under the action of centrifugal force, the fruit particles move to the edge, under the action of the curved structure 20, the fruit particles move to the position right above the cutting blade 19, under the action of gravity, the fruit particles fall to the position of the cutting blade 19 again, and (5) cutting, and pouring out a finished product after the work is finished.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims (3)

1. A bi-directional rotary juicer comprising a main cartridge-type housing (1), characterized in that: the juicing machine is characterized in that a plurality of supporting legs are installed at the bottom edge of the main cylindrical shell (1), a bottom supporting plate (6) is installed at the inner side of the bottom end of each supporting leg, a cover-free juicing space (2) is arranged at the center of the main cylindrical shell (1), a sealed space (3) is arranged at the inner side of the top of the juicing space (2), a sealed cover (4) is arranged in the sealed space (3), a rotating plate (5) is installed at the top of the sealed cover (4), a driving motor installing shell (7) is installed at the center of the upper surface of the bottom supporting plate (6), a driving motor (8) is installed in the driving motor installing shell (7), the shaft body end of the driving motor (8) is connected with a gear type coaxial turnover mechanism (11) through a main connecting plate (9), and the side surface of the gear type coaxial turnover mechanism (11) is fixed on the structure at the middle part of the supporting legs through a main connecting rod (10), the bottom of the main cylinder type shell (1) is penetrated through by a main rotating shaft (12), a sealing ring (16) and a bearing are arranged between the penetrating parts of the main cylinder type shell and the main rotating shaft (1), a bottom rotating plate (15) is arranged at the bottom of the main cylinder type shell (1) on the main rotating shaft (12), a main groove structure (17) is arranged at the center of the bottom rotating plate (15), a plurality of curved structures (20) are arranged on the side surface of the main groove structure (17) of the bottom rotating plate (15), shaft holes (13) are arranged at the center parts of the bottom rotating plate (15) and the main rotating shaft (12), an auxiliary rotating shaft (14) is arranged in the shaft holes (13) through the sealing ring (16) and the bearing, a cutting blade (19) is arranged at one end in the main groove structure (17), and the bottom ends of the auxiliary rotating shaft (14) and the main rotating shaft (12) are respectively fixed with two rotating shafts of the gear type coaxial turnover mechanism (11) The gear type coaxial turnover mechanism (11) comprises a gear type coaxial turnover mechanism hollow shell (111), a gear type coaxial turnover mechanism component mounting space (112), a gear type coaxial turnover mechanism first rotating shaft (113), a gear type coaxial turnover mechanism second rotating shaft (114), a gear type coaxial turnover mechanism connecting plate (115), a gear type coaxial turnover mechanism hollow structure (116), a gear type coaxial turnover mechanism first gear (117), a gear type coaxial turnover mechanism second gear (118), a gear type coaxial turnover mechanism through hole (119) and a gear type coaxial turnover mechanism third gear (1110), the gear type coaxial turnover mechanism hollow shell (111) inner center is provided with the gear type coaxial turnover mechanism component mounting space (112), one side of the gear type coaxial turnover mechanism hollow shell (111) is provided with the gear type coaxial turnover mechanism first rotating shaft through a bearing (113) A first rotating shaft (113) for the gear type coaxial turnover mechanism is provided with a connecting plate (115) for the gear type coaxial turnover mechanism at one end positioned outside, the first rotating shaft (113) for the gear type coaxial turnover mechanism is provided with a first gear (117) for the gear type coaxial turnover mechanism on a shaft body positioned inside a component mounting space (112) for the gear type coaxial turnover mechanism, the other side surface of a hollow shell (111) for the gear type coaxial turnover mechanism is provided with a second rotating shaft (114) for the gear type coaxial turnover mechanism through a bearing, the center inside the second rotating shaft (114) for the gear type coaxial turnover mechanism is provided with a hollow structure (116) for the gear type coaxial turnover mechanism, the second rotating shaft (114) for the gear type coaxial turnover mechanism is provided with a second gear (118) for the gear type coaxial turnover mechanism at one end positioned inside, a through hole (119) for the gear type coaxial turnover mechanism is arranged at the center of a second gear (118) for the gear type coaxial turnover mechanism, the shaft body of a first rotating shaft (113) for the gear type coaxial turnover mechanism is inserted into the hollow structure (116) for the gear type coaxial turnover mechanism and the through hole (119) for the gear type coaxial turnover mechanism, the other two opposite side surfaces of a hollow shell (111) for the gear type coaxial turnover mechanism are respectively provided with a rotating shaft through a bearing, the opposite ends of the two rotating shafts are respectively provided with a third gear (1110) for the gear type coaxial turnover mechanism, the opposite parts of the third gear (1110) for the gear type coaxial turnover mechanism are respectively engaged with the gear structures in the first gear (117) for the gear type coaxial turnover mechanism and the second gear (118) for the gear type coaxial turnover mechanism through the gear structures, and the connecting plate (115) for the gear type coaxial turnover mechanism is fixedly connected with a main connecting plate (9), the connecting end parts of the first rotating shaft (113) and the second rotating shaft (114) for the gear type coaxial turnover mechanism are fixedly connected with the end parts of the main rotating shaft (12) and the auxiliary rotating shaft (13) respectively.

2. The bi-directional rotary juicer of claim 1, wherein: a plurality of said curved structures (20) is arranged in an annular array, the number being even.

3. A bi-directional rotary juicer according to claim 2 wherein: the curved structure (20) is an upward inclined linear structure, and during operation, particles move towards the right upper part of the cutting blade (19) under the action of the curved structure (20).

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