CN112545293B

CN112545293B - Juicing assembly for juicer

Info

Publication number: CN112545293B
Application number: CN202110133519.7A
Authority: CN
Inventors: 高迪
Original assignee: Ningbo Kangjiafen Electric Appliance Technology Co ltd
Current assignee: Ningbo Kangjiafen Electric Appliance Technology Co ltd
Priority date: 2021-02-01
Filing date: 2021-02-01
Publication date: 2021-08-31
Anticipated expiration: 2041-02-01
Also published as: CN112545293A

Abstract

The invention discloses a juicing component for a juicer, wherein the juicing component is arranged in a shell and comprises a first crushing gear, a second crushing gear, a crushing transmission belt and a tensioning component; a first rotating shaft and a second rotating shaft are arranged between the front side plate and the rear side plate of the shell; the first crushing gear is fixedly arranged on the first rotating shaft, and the second crushing gear is fixedly arranged on the second rotating shaft; the crushing transmission belt is arranged between the first crushing gear and the second crushing gear; a crushing area is formed between the inner rings of the crushing transmission belt in the machine shell; a material port communicated with the crushing area is formed in the front side plate of the shell; a plurality of filtering holes are formed between every two adjacent transmission teeth in the crushing transmission belt; the tensioning assembly is arranged in the machine shell and used for tensioning the crushing transmission belt; the juicing component for the juicer is simple in structure, and the juicing efficiency is high, so that the fresh juice quality is not influenced.

Description

Juicing assembly for juicer

Technical Field

The invention relates to the technical field of juicing equipment, in particular to a juicing assembly for a juicer.

Background

The juice extracting component for the juice extractor is used for squeezing the juice in the fruits and vegetables by squeezing and crushing and the like so as to be used for eating or using, and a typical structure of the juice extracting component for the existing fruit and vegetable crushing juice extractor is a spiral structure. The mechanism consists of a front support, a feed hopper, a spiral shaft, a filter screen, a juice container, a rear support, a slag discharging groove and the like, wherein the left end of the spiral main shaft is supported in a rolling bearing seat, the right end of the spiral main shaft is supported in a hand wheel bearing seat, a motor drives the spiral shaft to operate through a pair of belt pulleys, and the materials are crushed and juiced by utilizing the spiral propelling principle. But the spiral transmission clearance is definite, inconvenient adjustment, and the slag tapping is troublesome, especially because the material is extruded, impeld by the continuous in broken juicing process, and the fresh juice quality is influenced by the temperature rise of frictional heating.

Disclosure of Invention

The invention mainly aims to provide a juicing component for a juicer, which has a simple structure, and has high juicing efficiency without influencing the quality of fresh juice.

In order to achieve the above purposes, the technical scheme adopted by the invention is as follows: a juicing assembly for a juicer is arranged in a machine shell, and is characterized by comprising a first crushing gear, a second crushing gear, a crushing transmission belt and a tensioning assembly; a first rotating shaft is arranged between the front side plate and the rear side plate of the shell and close to the left side plate, a second rotating shaft is arranged between the front side plate and the rear side plate and close to the right side plate, and the axes of the first rotating shaft and the second rotating shaft are positioned in the same horizontal plane; the first crushing gear is fixedly arranged on the first rotating shaft, the second crushing gear is fixedly arranged on the second rotating shaft, the front end surfaces of the first crushing gear and the second crushing gear are both contacted with the front side plate, and the rear end surfaces of the first crushing gear and the second crushing gear are both contacted with the rear side plate; the crushing transmission belt is arranged between the first crushing gear and the second crushing gear; a crushing area is formed between the inner rings of the crushing transmission belt in the machine shell; a material port communicated with the crushing area is formed in the front side plate of the shell; a plurality of filtering holes are formed between every two adjacent transmission teeth in the crushing transmission belt; the tensioning assembly is arranged in the machine shell and used for tensioning the crushing transmission belt.

Through the technical scheme, when the juicing assembly for the juicer is used, the first rotating shaft is controlled to drive the first crushing gear to rotate clockwise, and the first crushing gear drives the crushing transmission belt between the first crushing gear and the second crushing gear to rotate; then, putting the primarily chopped materials into a crushing area from a material port, conveying the materials entering the crushing area to the meshing part of a first crushing gear and a crushing transmission belt through a crushing transmission belt, and starting to cut and crush the materials when the convex teeth of the first crushing gear and the transmission teeth of the crushing transmission belt are close to and meshed with each other and are relatively tangent; when entering the meshing area, the materials are continuously extruded and cut, and juice extraction is started; when the first crushing gear and the crushing transmission belt tend to be completely meshed, squeezing and juicing are carried out, and the squeezed juice flows out through the filtering holes; the juiced materials are conveyed into the crushing area again through the first crushing gear and the crushing driving belt for repeated squeezing and juicing, and the juiced materials are taken out from the material opening after juicing is finished; according to the invention, the material juicing is realized by adopting the meshing mode of the crushing transmission belt and the first crushing gear, compared with the meshing juicing mode between two gears, the angle of the meshing area of the crushing transmission belt and the first crushing gear is more than or equal to 180 degrees, namely the meshing area is longer, so that the material can be fully squeezed and juiced, and the material can be repeatedly squeezed and juiced; in addition, compared with a spiral extrusion mode, the fresh juice quality is not influenced by friction heating.

Furthermore, the tensioning assembly comprises a tensioning compression roller, a front vertical groove and a rear vertical groove which are opposite in position are arranged above the crushing transmission belt in a front side plate and a rear side plate of the shell, a shaft rod is arranged between the front vertical groove and the rear vertical groove, the tensioning compression roller is positioned between the front side plate and the rear side plate of the shell and is rotatably connected to the outer side of the shaft rod, and the tensioning compression roller is downwards compressed above the crushing transmission belt; the front end of the shaft lever extends out of the front vertical groove and is fixedly provided with a front pressing block, and the rear end of the shaft lever extends out of the rear vertical groove and is fixedly provided with a rear pressing block; a front convex plate positioned above the front pressing block extends from the front side of the upper cover plate, and a rear convex plate positioned above the rear pressing block extends from the rear side of the upper cover plate; a front sliding rod penetrating through the front convex plate is fixedly arranged above the front pressing block, and a rear sliding rod penetrating through the rear convex plate is fixedly arranged above the rear pressing block; the front slide bar is sleeved with a front spring positioned between the front convex plate and the front press block, the front spring is used for forcing the front press block to move downwards, the rear slide bar is sleeved with a rear spring positioned between the rear convex plate and the rear press block, and the rear spring is used for forcing the rear press block to move downwards; the circumference outside of tensioning compression roller is equipped with a plurality of thimbles that are used for inserting in the filter hole, when broken drive belt transmission, drives the rotation of tensioning compression roller, and the tensioning compression roller drives the thimble and inserts in the filter hole.

Through the technical scheme, the tensioning roller is arranged, so that the crushing transmission belt can be always pressed on the first crushing gear and the second crushing gear, and when a material enters between the first crushing gear and the crushing transmission belt, the pressing force received by the material is larger under the action of the tensioning roller; on the other hand, the tensioning compression roller drives the thimble to insert in the filter pore when rotating, and the material piece that will block up in the filter pore is ejecting to fall into broken district in, simultaneously because of the effort of tensioning compression roller for broken drive belt is inside side protrusion, and then makes two driving teeth that are in tensioning compression roller department open, and the material that is convenient for to be located between two driving teeth drops.

Further, the diameter of the first crushing gear is larger than that of the second crushing gear; this setting up makes the downside of broken drive belt decline downwards to the right on the one hand to the meshing zone of the first broken gear of material entering and broken drive belt of can being convenient for, on the other hand can increase the meshing zone of broken drive belt and first broken gear, makes the material by extrusion time long, it is more abundant to squeeze juice.

Further, radial sliding grooves are formed in the outer side of the first crushing gear along the radial direction between two adjacent convex teeth, a top block is connected to the inner portion of each radial sliding groove in a sliding mode along the radial direction, notches are formed in the end portions of the front end face and the rear end face of the first crushing gear and the end portion of each radial sliding groove, guide rods arranged along the radial direction are fixedly arranged in each notch, and protruding blocks which are located in the notches and connected to the guide rods in a sliding mode are fixedly arranged at the front end and the rear end of each top block; and a first spring is sleeved outside the guide rod in each groove opening and used for forcing the lug to drive the ejector block to extend out of the radial sliding groove.

Through the technical scheme, when the first crushing gear is combined with the crushing transmission belt, the transmission teeth on the crushing transmission belt push the ejector block to retract into the radial sliding groove, and at the moment, the ejector block compresses the first spring through the convex blocks on the two sides; when first broken gear and broken drive belt break away from the meshing, the kicking block stretches out radial spout under the first spring action in both sides to it is ejecting to be located the material between two dogteeth of first broken gear, thereby can prevent that the material of adhesion between two dogteeth from influencing the meshing of first broken gear and broken drive belt.

The invention has the advantages that:

1, the material juicing is realized by adopting a mode of meshing the crushing transmission belt with the first crushing gear, and compared with the meshing juicing between two gears, the material juicing can be fully extruded and juiced due to the fact that the angle of the meshing area of the crushing transmission belt and the first crushing gear is larger than or equal to 180 degrees, namely the meshing area is longer, and the material juicing can be repeatedly extruded and juiced; in addition, compared with a spiral extrusion mode, the fresh juice quality is not influenced by friction heating;

2, the tensioning compression roller is arranged, so that the crushing transmission belt can be always pressed on the first crushing gear and the second crushing gear, and when the material enters between the first crushing gear and the crushing transmission belt, the pressing force applied to the material is larger under the action of the tensioning compression roller; on the other hand, the tensioning compression roller drives the thimble to be inserted into the filter hole when rotating, so that material scraps blocked in the filter hole are ejected out, and meanwhile, due to the acting force of the tensioning compression roller, the crushing transmission belt protrudes inwards, so that the two transmission teeth at the tensioning compression roller are opened, and the material positioned between the two transmission teeth can fall off conveniently;

3, when the first crushing gear is combined with the crushing transmission belt, the transmission teeth on the crushing transmission belt push the top block to retract into the radial sliding chute, and at the moment, the top block compresses the first spring through the convex blocks on the two sides; when the first crushing gear is disengaged from the crushing transmission belt, the ejector block extends out of the radial sliding groove under the action of the first springs on the two sides, so that materials between the two convex teeth of the first crushing gear are ejected out, and the influence of the materials adhered between the two convex teeth on the engagement of the first crushing gear and the crushing transmission belt can be prevented;

4, the diameter of first broken gear is greater than the diameter of the broken gear of second, makes the downside of broken drive belt down-tilt right on the one hand to can be convenient for the material and get into the meshing area of first broken gear and broken drive belt, on the other hand can increase the meshing area of broken drive belt and first broken gear, make the material extruded time long, it is more abundant to press juice.

Drawings

FIG. 1 is a front cross-sectional view of the present invention;

FIG. 2 is a rear view of the present invention;

FIG. 3 is a cross-sectional view taken at A-A of FIG. 1;

FIG. 4 is a cross-sectional view taken at B-B of FIG. 1;

fig. 5 is an exploded view of the overall first crushing gear of the present invention.

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.

In the description of the present invention, it is to be understood that the terms "center", "upper", "lower", "front", "rear", "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, and do not indicate or imply that the devices or elements referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, are not to be construed as limiting the present invention.

In the description of the present invention, it should be noted that unless otherwise explicitly stated or limited, the terms "mounted," "connected," and "disposed" are to be construed broadly and can, for example, be fixedly connected, disposed, detachably connected, disposed, or integrally connected and disposed. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

As shown in fig. 1-5, a juicing assembly for a juicer is arranged in a casing 1, an upper cover plate 2 is fixedly mounted at an opening at the upper end of the casing 1, the juicing assembly comprises a first crushing gear 5, a second crushing gear 6, a crushing transmission belt 7 and a tensioning assembly, a first rotating shaft 3 is arranged between a front side plate 1b and a rear side plate 1c of the casing 1 at a position close to a left side plate 1d, a second rotating shaft 4 is arranged at a position close to a right side plate 1e, and the axes of the first rotating shaft 3 and the second rotating shaft 4 are in the same horizontal plane; the first crushing gear 5 is fixedly arranged on the first rotating shaft 3, the second crushing gear 6 is fixedly arranged on the second rotating shaft 4, the front end surfaces of the first crushing gear 5 and the second crushing gear 6 are both contacted with the front side plate 1b, and the rear end surfaces of the first crushing gear 5 and the second crushing gear 6 are both contacted with the rear side plate 1 c; the crushing transmission belt 7 is arranged between the first crushing gear 5 and the second crushing gear 6; the outer side of the front side plate 1b of the casing 1 is fixedly provided with a driving motor 8, an output shaft of the driving motor 8 is coaxial and fixedly connected with the front end of the first rotating shaft 3, and the driving motor 8 is used for driving the first rotating shaft 3 to rotate. A crushing zone 101 is formed in the machine shell 1 between the inner rings of the crushing transmission belt 7; a material inlet 1g communicated with the crushing area 101 is formed in the front side plate 1b of the shell 1, and a feed hopper is arranged at the position of the material inlet 1g in the front side plate 1b of the shell 1; a plurality of filtering holes 71 are arranged between two adjacent transmission teeth in the crushing transmission belt 7.

The tensioning assembly comprises a tensioning compression roller 12, a front vertical groove 1h and a rear vertical groove 1i which are opposite in position are arranged above the crushing transmission belt 7 in a front side plate 1b and a rear side plate 1c of the machine shell 1, a shaft lever 11 is arranged between the front vertical groove 1h and the rear vertical groove 1i, the tensioning compression roller 12 is positioned between the front side plate 1b and the rear side plate 1c of the machine shell 1 and is rotatably connected to the outer side of the shaft lever 11, and the tensioning compression roller 12 is pressed downwards above the crushing transmission belt 7; the front end of the shaft lever 11 extends out of the front vertical groove 1h and is fixedly provided with a front pressing block 13a, and the rear end of the shaft lever extends out of the rear vertical groove 1i and is fixedly provided with a rear pressing block 13 b; a front convex plate 2a positioned above the front pressing block 13a extends from the front side of the upper cover plate 2, and a rear convex plate 2b positioned above the rear pressing block 13b extends from the rear side; a front sliding rod 14a penetrating through the front convex plate 2a is fixedly arranged above the front pressing block 13a, and a rear sliding rod 14b penetrating through the rear convex plate 2b is fixedly arranged above the rear pressing block 13 b; the front sliding rod 14a is sleeved with a front spring 15a positioned between the front convex plate 2a and the front pressing block 13a, the front spring 15a is used for forcing the front pressing block 13a to move downwards, the rear sliding rod 14b is sleeved with a rear spring 15b positioned between the rear convex plate 2b and the rear pressing block 13b, and the rear spring 15b is used for forcing the rear pressing block 13b to move downwards; a plurality of ejector pins 12a for being inserted into the filter holes 71 are arranged on the outer side of the circumference of the tensioning pressing roller 12, when the crushing transmission belt 7 is used for transmission, the tensioning pressing roller 12 is driven to rotate, and the ejector pins 12a are driven by the tensioning pressing roller 12 to be inserted into the filter holes 71.

In the present embodiment, the diameter of the first crushing gear 5 is larger than the diameter of the second crushing gear 6; this setting makes the downside of broken drive belt 7 decline downwards to the right on the one hand to can be convenient for the material to get into the meshing area of first broken gear 5 and broken drive belt 7, on the other hand can increase the meshing area of broken drive belt 7 and first broken gear 5, make the material by the extrusion time long, it is more abundant to squeeze juice.

In this embodiment, radial sliding grooves 51 are radially formed between two adjacent convex teeth on the outer side of the first crushing gear 5, a top block 17 is radially and slidably connected in each radial sliding groove 51, notches 52 are formed in the front end face and the rear end face of the first crushing gear 5 at the end of each radial sliding groove 51, a guide rod 18 which is radially arranged is fixedly arranged in each notch 52, and protruding blocks 19 which are located in the notches 52 and slidably connected to the guide rod 18 are fixedly arranged at the front end and the rear end of each top block 17; inside each notch 52, a first spring 20 is attached outside the guide bar 18, said first spring 20 being used to force the projection 19 to bring the ejector pad 17 out of the radial slide slot 51.

When the juicing component for the juicer is used, the first rotating shaft 3 is controlled to drive the first crushing gear 5 to rotate clockwise, and the first crushing gear 5 drives the crushing transmission belt 7 positioned between the first crushing gear 5 and the second crushing gear 6 to rotate; then, the primarily chopped materials are put into the crushing area 101 through the material port 1g, and the materials entering the crushing area 101 are conveyed to the meshing part of the first crushing gear 5 and the crushing transmission belt 7 through the crushing transmission belt 7. When the convex teeth of the first crushing gear 5 and the transmission teeth of the crushing transmission belt 7 are close to and meshed with each other, the convex teeth and the transmission teeth are relatively tangent to each other, and the materials are cut and crushed; when the convex teeth of the first crushing gear 5 and the transmission teeth of the crushing transmission belt 7 enter the meshing area, the materials are continuously extruded and cut, and the juicing is started; when the first crushing gear 5 and the crushing transmission belt tend to be completely meshed, squeezing and juicing are carried out, and the squeezed juice flows out through the filtering holes 71; the materials after juicing are transmitted to the crushing area 101 again through the first crushing gear 5 and the crushing transmission belt 7, so that the materials are repeatedly squeezed and juiced, and the materials after juicing are taken out from the material port 1 g.

In the embodiment, when the crushing transmission belt 7 rotates, the tension compression roller 12 is driven to rotate, on one hand, the tension compression roller 12 is arranged to enable the crushing transmission belt 7 to be always pressed on the first crushing gear 5 and the second crushing gear 6, and when materials enter between the first crushing gear 5 and the crushing transmission belt 7, under the action of the tension compression roller 12, the pressing force received by the materials is larger; on the other hand, the tensioning compression roller 12 drives the thimble 12a to be inserted into the filtering hole 71 when rotating, and the material scraps blocked in the filtering hole 71 are ejected out and fall into the crushing area, and meanwhile, due to the acting force of the tensioning compression roller 12, the crushing transmission belt 7 protrudes inwards, so that the two transmission teeth at the tensioning compression roller 12 are opened, and the material between the two transmission teeth is convenient to fall off.

In addition, when the first crushing gear 5 is combined with the crushing transmission belt 7, the transmission teeth on the crushing transmission belt 7 push the top block 17 to retract into the radial sliding groove 51, and at the moment, the top block 17 compresses the first spring 20 through the convex blocks 19 on the two sides; when the first crushing gear 5 is disengaged from the crushing transmission belt 7, the ejector block 17 extends out of the radial sliding groove 51 under the action of the first springs 20 on the two sides, so that the material positioned between the two convex teeth of the first crushing gear 5 is ejected out, and the material adhered between the two convex teeth can be prevented from influencing the engagement of the first crushing gear 5 and the crushing transmission belt 7.

According to the invention, the material juicing is realized by adopting the meshing mode of the crushing transmission belt 7 and the first crushing gear 5, compared with the meshing juicing mode between two gears, the angle of the meshing area of the crushing transmission belt 7 and the first crushing gear 5 is more than or equal to 180 degrees, namely the meshing area is longer, so that the material can be fully squeezed and juiced; in addition, compared with a spiral extrusion mode, the fresh juice quality is not influenced by friction heating.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims

1. A juicing assembly for a juicer is arranged in a machine shell, and is characterized by comprising a first crushing gear, a second crushing gear, a crushing transmission belt and a tensioning assembly; a first rotating shaft is arranged between the front side plate and the rear side plate of the shell and close to the left side plate, a second rotating shaft is arranged between the front side plate and the rear side plate and close to the right side plate, and the axes of the first rotating shaft and the second rotating shaft are positioned in the same horizontal plane; the first crushing gear is fixedly arranged on the first rotating shaft, the second crushing gear is fixedly arranged on the second rotating shaft, the front end surfaces of the first crushing gear and the second crushing gear are both contacted with the front side plate, and the rear end surfaces of the first crushing gear and the second crushing gear are both contacted with the rear side plate; the crushing transmission belt is arranged between the first crushing gear and the second crushing gear; a crushing area is formed between the inner rings of the crushing transmission belt in the machine shell; a material port communicated with the crushing area is formed in the front side plate of the shell; a plurality of filtering holes are formed between every two adjacent transmission teeth in the crushing transmission belt; the tensioning assembly is arranged in the machine shell and used for tensioning the crushing transmission belt.

2. The juice extraction assembly for a juice extractor according to claim 1, wherein: the tensioning assembly comprises a tensioning compression roller, a front vertical groove and a rear vertical groove which are opposite in position are arranged above the crushing transmission belt in a front side plate and a rear side plate of the shell, a shaft rod is arranged between the front vertical groove and the rear vertical groove, the tensioning compression roller is positioned between the front side plate and the rear side plate of the shell and is rotatably connected to the outer side of the shaft rod, and the tensioning compression roller is downwards compressed above the crushing transmission belt; the front end of the shaft lever extends out of the front vertical groove and is fixedly provided with a front pressing block, and the rear end of the shaft lever extends out of the rear vertical groove and is fixedly provided with a rear pressing block; a front convex plate positioned above the front pressing block extends from the front side of the upper cover plate, and a rear convex plate positioned above the rear pressing block extends from the rear side of the upper cover plate; a front sliding rod penetrating through the front convex plate is fixedly arranged above the front pressing block, and a rear sliding rod penetrating through the rear convex plate is fixedly arranged above the rear pressing block; the front slide bar is sleeved with a front spring positioned between the front convex plate and the front press block, the front spring is used for forcing the front press block to move downwards, the rear slide bar is sleeved with a rear spring positioned between the rear convex plate and the rear press block, and the rear spring is used for forcing the rear press block to move downwards; the circumference outside of tensioning compression roller is equipped with a plurality of thimbles that are used for inserting in the filter hole, when broken drive belt transmission, drives the rotation of tensioning compression roller, and the tensioning compression roller drives the thimble and inserts in the filter hole.

3. The juice extraction assembly for a juice extractor according to claim 1, wherein: the diameter of the first crushing gear is larger than that of the second crushing gear.

4. The juice extraction assembly for a juice extractor according to claim 1, wherein: radial sliding grooves are formed in the outer side of the first crushing gear along the radial direction between two adjacent convex teeth, a top block is connected in each radial sliding groove in a sliding mode along the radial direction, notches are formed in the end portions of the front end face and the rear end face of the first crushing gear and the end portion of each radial sliding groove, guide rods arranged along the radial direction are fixedly arranged in each notch, and protruding blocks which are located in the notches and connected to the guide rods in a sliding mode are fixedly arranged at the front end and the rear end of each top block; and a first spring is sleeved outside the guide rod in each groove opening and used for forcing the lug to drive the ejector block to extend out of the radial sliding groove.