CN219500874U - Novel efficient and mute wall breaking machine structure - Google Patents

Abstract

The utility model discloses a novel efficient and mute wall breaking machine structure, which comprises a machine base and a material cup arranged on the machine base, wherein a first stirring cutter and a second stirring cutter are arranged in the material cup, a driving motor is arranged in the machine base, the driving motor is in transmission connection with a transmission component, the transmission component is provided with a first output end and a second output end, the first output end is in transmission connection with the first stirring cutter, the second output end is in transmission connection with the second stirring cutter, the first stirring cutter and the second stirring cutter rotate in the same direction, the first stirring cutter consists of a longitudinal cutter shaft and a cutter blade arranged on the longitudinal cutter shaft, the longitudinal cutter shaft is longitudinally arranged in the material cup, and the longitudinal cutter shaft extends to the upper part of the material cup from the bottom of the material cup. The utility model adopts the same-direction rotation to realize the advantages of reducing noise, avoiding overflow and enlarging the stirring range by adopting the longitudinal cutter shaft.

Description

Novel efficient and mute wall breaking machine structure

Technical Field

The utility model relates to a novel efficient and silent wall breaking machine structure.

Background

The wall breaking machine is an electric device for cutting, squeezing juice, mixing, cutting (cutting) or pulverizing foods such as fruits, vegetables, grains, etc.

The prior double-blade wall breaking machine structure, such as the Chinese patent application publication No. CN114192016A, discloses a stirrer with a bidirectional rotary blade, comprising: a blade assembly including a main blade shaft configured to integrally rotate the first blade and the first main coupling in a forward direction, and a counter-rotating blade shaft configured to integrally rotate the second blade and the first counter-rotating coupling in a counter direction; and a gear case assembly including a main gear shaft provided to rotate the second main coupling and the main gear in a forward direction, at least one sub gear engaged with the main gear to rotate in a reverse direction, a ring gear inscribed in the sub gear to be engaged, and a second reverse rotation coupling integrally rotated in a reverse direction with the ring gear and transmitting the reverse rotation to the first reverse rotation coupling.

Based on the above, in the prior art, the first blade and the second blade are adopted to perform rotary processing in a mutually inverted manner, and the processing mode can effectively improve the efficiency. However, the two blades rotate in opposite directions, so that the two rotational flows collide to generate larger noise and the possibility of overflowing exists.

Moreover, the bottom that current first blade and second blade all lie in the cup, and this kind of tool bit structure sets up when beating leaf form food such as vegetables, and it can not form the backward flow, and the range of beating is located the bottom all the time, has great limitation, can't stir the problem of leaf form vegetables garrulous, and the whipping efficiency is very low.

Disclosure of Invention

The present utility model aims to solve at least one of the technical problems existing in the prior art. Therefore, the utility model provides a novel efficient and silent wall breaking machine structure.

According to this purpose design a novel high-efficient and silence broken wall machine structure, be in including frame and setting material cup on the frame, be equipped with first stirring sword and second stirring sword in the material cup be equipped with driving motor in the frame, the driving motor transmission is connected with the derailleur subassembly, the derailleur subassembly has first output and second output, first output with first stirring sword transmission is connected, the second output with the second stirring sword transmission is connected, first stirring sword with the mutual same direction rotation of second stirring sword, first stirring sword comprises vertical arbor and the blade that sets up on the vertical arbor, vertical arbor vertically sets up in the material cup, vertical arbor extends to by the bottom of material cup the upper portion of material cup.

Preferably, a positioning piece is further arranged at the top end of the longitudinal cutter shaft, and extends upwards to be matched with the cup cover in a positioning way.

Preferably, the second stirring knife is arranged in a material cup below the longitudinal knife shaft.

Preferably, the second stirring blade and the first stirring blade rotate at a differential speed.

Preferably, the transmission assembly is composed of a first speed changing component and a second speed changing component, wherein the input end of the first speed changing component is in transmission connection with a motor shaft of the driving motor, the output end of the first speed changing component is in transmission connection with the input end of the second speed changing component and the first stirring blade, and the output end of the second speed changing component is in transmission connection with the second stirring blade.

Preferably, the first speed changing component comprises a first speed changing base, a first gear ring is arranged on the first speed changing base, a first planet carrier capable of rotating relative to the first speed changing base is arranged on the first speed changing base, a plurality of first planet gears are arranged on the first planet carrier along the circumference of the first planet carrier in a arrayed mode, the first planet gears are meshed with the first gear ring in an intermeshing mode, a motor shaft of the driving motor extends to the center of the first planet carrier, a first sun gear is mounted on the motor shaft of the driving motor, the first sun gear is meshed with the plurality of first planet gears respectively, and a first power output shaft is connected to the first planet carrier in a transmission mode and connected with the first stirring cutter;

the second speed change part comprises a second speed change base, the second speed change base is fixedly installed with the first planet carrier, a second gear ring is arranged on the second speed change base, a second planet carrier capable of rotating relative to the second speed change base is arranged in the second speed change base, a plurality of second planet gears are arranged in the second planet carrier along the circumference of the second planet carrier, the second planet gears are rotatably arranged on the second planet carrier and meshed with the second gear ring, a first power output coupler is rotatably arranged on the second planet carrier, the lower end of the first power output coupler is fixedly connected with a second sun gear, the second sun gear is meshed with the second planet gears, and the first power output coupler is connected with the second stirring cutter in a transmission mode.

Compared with the prior art, the stirring device has the advantages that the stirring device can realize the same-direction rotation to reduce noise and avoid overflowing, and the longitudinal cutter shaft is adopted to enlarge the stirring range, and compared with the prior art, the stirring device can realize the same-direction rotation of the first stirring cutter and the second stirring cutter, so that two strands of same-direction rotational flow can be generated during stirring, the noise generated by rotational flow collision is reduced, meanwhile, the two strands of same-direction rotational flow can avoid overflowing caused by liquid collision, the first stirring cutter consists of the longitudinal cutter shaft and the blades arranged on the longitudinal cutter shaft, the longitudinal cutter shaft is longitudinally arranged in the material cup, and the longitudinal cutter shaft extends from the bottom of the material cup to the upper part of the material cup. The stirring range of the longitudinal cutter shaft can be enlarged by extending from the bottom of the material cup to the upper part of the material cup, so that the stirring efficiency is improved.

Drawings

FIG. 1 is a schematic perspective view of the present utility model;

FIG. 2 is a second perspective view of the present utility model;

FIG. 3 is a schematic cross-sectional view of the present utility model;

FIG. 4 is a schematic cross-sectional view of a transmission assembly according to the present utility model;

FIG. 5 is a second schematic cross-sectional view of the present utility model;

fig. 6 is a schematic perspective view of a first stirring blade according to the present utility model.

Detailed Description

The utility model is further described below with reference to the drawings and examples.

Referring to fig. 1-6, a novel efficient and silent wall breaking machine structure comprises a machine base 10 and a material cup 20 arranged on the machine base 10, wherein a first stirring blade 30 and a second stirring blade 40 are arranged in the material cup 20, a driving motor 50 is arranged in the machine base 10, the driving motor 50 is in transmission connection with a transmission assembly 60, the transmission assembly 60 is provided with a first output end and a second output end, the first output end is in transmission connection with the first stirring blade 30, the second output end is in transmission connection with the second stirring blade 40, the first stirring blade 30 and the second stirring blade 40 are in mutual same-direction rotation, the same-direction rotation can generate two-direction rotational flows during stirring, noise generated by rotational flow collision is reduced, meanwhile, the same-direction rotational flows can avoid liquid collision to cause overflow, the first stirring blade 30 is composed of a longitudinal cutter shaft 300 and a blade 302 arranged on the longitudinal cutter shaft 300, the longitudinal cutter shaft 300 is longitudinally arranged in the material cup 20, and the longitudinal cutter shaft 300 extends from the bottom of the material cup 20 to the material cup 20. The stirring range of the longitudinal cutter shaft can be enlarged by extending from the bottom of the material cup to the upper part of the material cup, so that the stirring efficiency is improved.

The utility model adopts the longitudinal cutter shafts which extend in the same direction and in the axial direction, and can solve the problems of high noise, easy overflow and small beating range in the prior art.

Referring to fig. 1 and 6, a positioning piece 301 is further provided at the top end of the longitudinal cutter shaft 300, and the positioning piece 301 extends upwards to be matched with the cup cover 200 in a positioning manner. The positioning member 301 can effectively provide stability support for the longitudinally extending arbor 300, and avoid the problems of eccentricity, wobble, etc. during rotation.

Referring to fig. 1 to 3, the second agitating blade 40 is disposed in the cup 20 below the longitudinal cutter shaft 300.

In the present utility model, the second stirring blade 40 and the first stirring blade 30 rotate at different speeds

Preferably, the rotation speed of the second stirring blade 40 is greater than the rotation speed of the first stirring blade 30.

The high speed rotation of the second stirring blade 40 is responsible for larger at the bottom of the cup, while the low speed rotation of the first stirring blade 30 is mainly used for enlarging a larger range and making the stirring more sufficient.

Referring to fig. 3 to 5, the transmission assembly 60 is composed of a first transmission member 610 and a second transmission member 620, wherein an input end of the first transmission member 610 is in transmission connection with the motor shaft 510 of the driving motor 50, an output end of the first transmission member 610 is in transmission connection with an input end of the second transmission member 620 and the first stirring blade 30, and an output end of the second transmission member 620 is in transmission connection with the second stirring blade 40.

Referring to fig. 3 to 5, the first transmission member 610 includes a first transmission base 611, a first ring gear 612 is provided on the first transmission base 611, a first planet carrier 614 capable of rotating relative to the first transmission base 611 is provided on the first transmission base 611, a plurality of first planet gears 615 are arranged on the first planet carrier 614 along the circumference of the first planet carrier 614, the first planet gears 615 are rotatably provided on the first planet carrier 614, the first planet gears 615 are meshed with the first ring gear 612, a motor shaft 510 of the driving motor 50 extends to the center of the first planet carrier 614, a first sun gear 613 is mounted on the motor shaft 510 of the driving motor 50, the first sun gear 613 is meshed with the plurality of first planet gears 615, a first power output shaft 616 is connected to the first planet carrier 614, and the first power output shaft 616 is in driving connection with the first stirring blade 30;

the second speed changing component 620 includes a second speed changing base 621, the second speed changing base 621 is fixedly mounted with the first planet carrier 614, a second gear ring 622 is provided on the second speed changing base 621, a second planet carrier 624 capable of rotating relative to the second speed changing base 621 is provided in the second speed changing base 621, a plurality of second planet gears 623 are arranged in the second planet carrier 624 along the circumference thereof, the second planet gears 623 are rotatably provided on the second planet carrier 624, the second planet gears 623 are meshed with the second gear ring 622, a first power output coupler 625 is rotatably provided on the second planet carrier 624, a second sun gear 626 is fixedly connected to the lower end of the first power output coupler 625, the second sun gear 626 is meshed with the plurality of second planet gears 623, and the first power output coupler 625 is in transmission connection with the second stirring blade 40.

Referring to fig. 3 and 4, the second stirring blade 40 is fixedly connected with a first power input coupler 410, and the first power output coupler 625 is in coupling transmission with the first power output coupler 625.

Referring to fig. 3 and 4, the first power output shaft 616 is fixedly connected with a second power output coupler 320, the lower end of the first stirring blade 30 is connected with a transmission shaft 310, and the lower end of the transmission shaft 310 is fixedly connected with a second power input coupler 330 that is coupled with the second power output coupler 320.

Transmission principle of the transmission assembly 60 of the present utility model: the driving motor 50 drives the first sun gear 613 to rotate, which can drive all the first planet gears 615 to rotate along the first gear ring 612 to perform circular motion, so as to drive the first planet carrier 614 to rotate, and in the process of rotating the first planet carrier 614, the driving motor can drive the first power output shaft 616 and the second variable speed base 621 to rotate at the same time, and the first power output shaft 616 can directly drive the first stirring blade 30 to rotate. And the second speed changing base 621 rotates, which can drive the second planet gear 623 to rotate through the rotation of the second gear ring 622, and when the second planet gear 623 rotates, it can drive the second sun gear 626 to rotate, thereby driving the first power output coupler 625 to rotate, and the first power output coupler 625 directly drives the first power input coupler 410 to drive the second stirring blade 40 to rotate.

What is not described in detail in this specification is prior art known to those skilled in the art.

In the description of the present utility model, it should be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings are merely for convenience in describing the present utility model and simplifying the description, and do not indicate or imply that the device or element being referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present utility model, and the terms "first", "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implying the number of technical features being indicated.

The foregoing has shown and described the basic principles and main features of the present utility model and the advantages of the present utility model. It will be understood by those skilled in the art that the present utility model is not limited to the embodiments described above, and that the above embodiments and descriptions are merely illustrative of the principles of the present utility model, and various changes and modifications may be made without departing from the spirit and scope of the utility model, which is defined in the appended claims. The scope of the utility model is defined by the appended claims and equivalents thereof.

Claims (6)

1. Novel efficient and mute wall breaking machine structure comprises a machine base (10) and a material cup (20) arranged on the machine base (10), wherein a first stirring cutter (30) and a second stirring cutter (40) are arranged in the material cup (20), a driving motor (50) is arranged in the machine base (10), a transmission assembly (60) is connected with the driving motor (50) in a transmission mode, the transmission assembly (60) is provided with a first output end and a second output end, the first output end is in transmission connection with the first stirring cutter (30), and the second output end is in transmission connection with the second stirring cutter (40), and the wall breaking machine structure is characterized in that: the first stirring blade (30) and the second stirring blade (40) rotate in the same direction, the first stirring blade (30) is composed of a longitudinal cutter shaft (300) and a blade (302) arranged on the longitudinal cutter shaft (300), the longitudinal cutter shaft (300) is longitudinally arranged in the material cup (20), and the longitudinal cutter shaft (300) extends from the bottom of the material cup (20) to the upper portion of the material cup (20).

2. The novel efficient and silent wall breaking machine structure according to claim 1, wherein: the top end of the longitudinal cutter shaft (300) is also provided with a positioning piece (301), and the positioning piece (301) extends upwards to be matched with the cup cover (200) in a positioning way.

3. The novel efficient and silent wall breaking machine structure according to claim 1, wherein: the second stirring knife (40) is arranged in the material cup (20) below the longitudinal knife shaft (300).

4. The novel efficient and silent wall breaking machine structure according to claim 1, wherein: the second stirring blade (40) and the first stirring blade (30) rotate at different speeds.

5. The novel efficient and silent wall breaking machine structure according to any one of claims 1 to 4, characterized in that: the speed changer assembly (60) is composed of a first speed change part (610) and a second speed change part (620), wherein the input end of the first speed change part (610) is in transmission connection with a motor shaft (510) of the driving motor (50), the output end of the first speed change part (610) is in transmission connection with the input end of the second speed change part (620) and the first stirring blade (30), and the output end of the second speed change part (620) is in transmission connection with the second stirring blade (40).

6. The novel efficient and silent wall breaking machine structure according to claim 5, wherein: the first speed changing component (610) comprises a first speed changing base (611), a first gear ring (612) is arranged on the first speed changing base (611), a first planet carrier (614) capable of rotating relative to the first speed changing base (611) is arranged on the first speed changing base (611), a plurality of first planet gears (615) are arranged on the first planet carrier (614) along the circumference of the first planet carrier (614), the first planet gears (615) are rotatably arranged on the first planet carrier (614), the first planet gears (615) are meshed with the first gear ring (612) mutually, a motor shaft (510) of the driving motor (50) extends to the center of the first planet carrier (614), a first sun gear (613) is arranged on the motor shaft (510) of the driving motor (50), the first sun gear (613) is meshed with the plurality of first planet gears (615) respectively, a first power output shaft (616) is connected to the first planet carrier (614), and the first power output shaft (616) is connected with the first stirring blade (30);

the second speed changing component (620) comprises a second speed changing base (621), the second speed changing base (621) is fixedly installed with the first planet carrier (614), a second gear ring (622) is arranged on the second speed changing base (621), a second planet carrier (624) capable of rotating relative to the second speed changing base (621) is arranged in the second speed changing base (621), a plurality of second planet gears (623) are arranged in the second planet carrier (624) along the circumference of the second planet carrier, the second planet gears (623) are rotatably arranged on the second planet carrier (624), the second planet gears (623) are meshed with the second gear ring (622), a first power output coupler (625) is rotatably arranged on the second planet carrier (624), the lower end of the first power output coupler (625) is fixedly connected with a second sun gear (626), the second sun gear (626) is meshed with the second planet gears (623) respectively, and the first power output coupler (625) is connected with the second stirring knife (40).