CN204743869U

CN204743869U - A mill for food processor

Info

Publication number: CN204743869U
Application number: CN201420873618.4U
Authority: CN
Inventors: 吴明川; 陈炜杰; 李家勋; 黄乐卓; 尹坤任; 俞晓明
Original assignee: Midea Group Co Ltd; Guangdong Midea Consumer Electric Manufacturing Co Ltd
Current assignee: Midea Group Co Ltd; Guangdong Midea Consumer Electric Manufacturing Co Ltd; Guangdong Midea Life Electric Manufacturing Co Ltd
Priority date: 2014-12-31
Filing date: 2014-12-31
Publication date: 2015-11-11
Anticipated expiration: 2024-12-31

Abstract

The utility model discloses a mill for food processor, include: the vessel has the grinding chamber in, the vessel has roof, diapire and a side perisporium, grinds the chamber and has first material mouthful and second material mouthful, and the first material degree of lip -rounding becomes on the diapire, and the second material degree of lip -rounding becomes on the side perisporium or extends to the roof from the side perisporium, and first material mouth and second expect that in the mouth is the feed inlet, and first material mouth and second expect that in the mouth another is the discharge gate, and first material mouth is the 10 -150 millimeter at the ascending maximum size d in the footpath of vessel. According to the utility model discloses a mill for food processor, with the biggest size control of first material mouthful between the 10 -150 millimeter, can the effective control can pass in and out the size of the edibles material of vessel, assurance food processor's normal operating to can rationally control the feeding and the ejection of compact speed of vessel, thereby can go on fully crushingly to eating the material, guarantee to smash the effect.

Description

For the mill of food processor

Technical field

The utility model relates to food Treatment Technology field, particularly, relates to a kind of mill for food processor.

Background technology

Soy bean milk making machine, fruits and vegetables juicer etc. are conventional food processors.Such as, in correlation technique, soy bean milk making machine utilizes motor as power part, drives the crushed piece High Rotation Speed in ladle body, to realize the pulverizing to the food materials in ladle body.But operationally noise is comparatively large, effects on slurry making is poor, slurrying concentration is low, energy consumption is high for traditional soybean milk machine, the problem of not easy cleaning, and, be easily sticking in infusion, therefore there are the needs of improvement.

Utility model content

The application makes following problem and true consciousness and discovery based on inventor.

The food processor of such as soy bean milk making machine produces large noise when operating, reason is: crushed piece is as crushing knife High Rotation Speed and mutually collide with food materials, noise is produced while pulverizing food materials, and the crushed piece of High Rotation Speed drives food materials to rotate in ladle body, the inwall of food materials and ladle body clashes into generation noise mutually, thus the noise that soy bean milk making machine is operationally produced is very large.

In addition, because crushed piece pulverizes food materials (as bean or pea) in ladle body, the inner chamber of ladle body is large, and therefore, crush efficiency and the crushing effect of food materials are poor, and slurrying concentration is low, energy consumption is high.

In addition, in infusion process, slurries are easily sticking.And also there is the problem of not easy cleaning in the food processor in correlation technique.

Document 1-CN1613410A proposes a kind of Are Easy to Clean Multi-Soya-Bean Milk Machine, wherein on head lower cover, is fixed with kuppe, so that cleaning.But the soy bean milk making machine in document 1 is when operating, and the food materials rotated in ladle body and the kuppe be fixed on head collide, and increase the noise of soy bean milk making machine, and kuppe consume the kinetic energy of food materials, cause energy consumption high.Further, still there is the problem of crush efficiency and crushing effect difference.

Document 2-CN102018053 discloses a kind of soy bean milk making machine, and this soy bean milk making machine comprises flow-disturbing frame and limited block, and flow-disturbing frame is set on motor output shaft, and limited block is located on the position relative with flow-disturbing frame, to stop flow-disturbing frame.When soy bean milk making machine operates, limited block stops that flow-disturbing frame rotates relative to ladle body and head body with the food materials rotated in ladle body, and in other words, when food materials rotate in ladle body, flow-disturbing frame is static under the stop of limited block, thus stirs the food materials rotated.In document 2, due to flow-disturbing frame relative to ladle body and head body motionless, the same with document 1, in ladle body, the food materials of High Rotation Speed and flow-disturbing frame collide, and increase the noise of soy bean milk making machine, and the flow-disturbing frame static relative to ladle body consumes the kinetic energy of food materials, cause energy consumption high, and the pulverizing of food materials is still carried out in ladle body, crush efficiency and crushing effect poor, slurrying concentration is low.

Document 3-CN201467923 discloses a kind of soy bean milk making machine with streaming spinning grinding fluid director, wherein air deflector to be rotatably installed on rotating shaft and to comprise multiple blade, in use, under blade rotates the slurry stream motion effect caused, air deflector can have rotation, strengthen circulation, improve crushing effect, simultaneously froth breaking.But, in document 3, on the one hand, air deflector is installed on the rotary shaft, and because the rotating speed of rotating shaft is very high, the rotating speed of air deflector under the drive of slurry stream is low, therefore the speed discrepancy between air deflector and rotating shaft is large, thus causes the wearing and tearing of air deflector and rotating shaft large, reduces service life.On the other hand, air deflector comprises the form of the blade on water conservancy diversion body, and therefore, slurrying is still carried out in ladle body, is only play the effect of stirring to the process of slurrying, still there is noise large, effects on slurry making and the problem that pulping efficiency is poor, slurrying concentration is low.

Present inventor is on the basis of above-mentioned document, found by large quantifier elimination and recognize, still there are technical problems to be solved in this application in correlation technique, such as noise be large, effects on slurry making and the problem such as pulping efficiency is poor, slurrying concentration is low, energy consumption is high.For this reason, the application proposes a kind of mill, in this mill, there is grinding chamber, by mill is rotatably located in the ladle body of soy bean milk making machine relative to ladle body and the rotating shaft mounted thereto relative to crushed piece, namely when soy bean milk making machine is run, rotating shaft drives crushed piece to rotate, to pulverize food materials in ladle body and to drive food materials to rotate in ladle body, food materials simultaneously in ladle body drive mill to rotate (namely food materials drive mill to rotate relative to ladle body), simultaneously because the rotating speed of mill is lower than the rotating speed of rotating shaft, therefore mill also rotates relative to rotating shaft.

In other words, rotating shaft drives crushed piece High Rotation Speed, the crushed piece of High Rotation Speed drives food materials to rotate in ladle body, under the drive of food materials, mill absorb food materials part kinetic energy and with food materials rotating Vortex, due to mill rotating Vortex under the drive of food materials, the speed discrepancy of mill and food materials diminishes, the mill simultaneously rotated also can stir food materials stably, food materials being more evenly distributed in ladle body thus, the rotation of food materials is also more steady, the flow-disturbing effect of mill is then more remarkable, also reduce the noise that food materials and mill produce because speed discrepancy is comparatively large simultaneously, achieve the object to soy bean milk making machine noise reduction better.

In addition, under the drive of food materials, mill absorbs the part kinetic energy of food materials and with food materials rotating Vortex, food materials are under the effect of mill, kinetic energy diminishes, and rotating speed reduces, and the speed discrepancy of food materials and crushed piece becomes large, be equivalent to crushed piece cutting speed and become large, therefore, the effect of pulverizing can be better.

Present inventor studies discovery further, because mill has grinding chamber, when rotating shaft drives crushed piece to rotate, slurrying can be carried out in grinding chamber, improve crushing effect and efficiency, improve slurrying concentration, reduce noise, especially, when crushed piece is located in grinding chamber, negative pressure (pressure namely in grinding chamber is lower than the pressure in the ladle body of soy bean milk making machine) can be formed in grinding chamber, thus food materials are inhaled in grinding chamber, food materials are pulverized in grinding chamber, reduce further noise, improve crush efficiency and effect, slurrying concentration improves.

Volume due to grinding chamber is less than the volume of ladle body, therefore, in grinding chamber, the probability of crushed piece collision food materials increases, and then improve crush efficiency and the crushing effect of food materials, further increase slurrying concentration, simultaneously due to there are the food materials of mill in ladle body of grinding chamber drive under relatively with ladle body relative to rotating shaft (thus relative to crushed piece) to rotate, therefore, food materials are ground further in the grinding chamber of mill, further increase crushing effect and the efficiency of food materials, and slurrying concentration improves greatly, therefore, mill in the application has the double action of grinding and flow-disturbing.

In description below the application, be described for soy bean milk making machine, be understandable that, the food processor mentioned in the application is not limited to soy bean milk making machine, such as, can be juicer, food disintegrating apparatus etc.Correspondingly, in the description below the application, food materials can be bean or pea, such as soya bean, also the mixture of " bean or pea and water " can be referred to, such as, when describing pulverizing food materials, food materials can refer to bean or pea, when describing food materials and rotating in ladle body, food materials can refer to bean or pea, the bean or pea of pulverizing and the mixture of water, but the application is not limited thereto, such as food materials also can be other mixtures, the mixture of such as fruit or vegetables and water.Those skilled in the art can easy understand.

For this reason, a kind of mill for food processor of proposition of the present utility model, utilize this mill, food processor operationally noise is little, pulping efficiency and effects on slurry making is good, slurrying concentration is high, energy consumption is low, and is not easy to be sticking in infusion, easy cleaning.

According to the mill for food processor of the present utility model, comprise: vessel, in described vessel, there is grinding chamber, described vessel has roof, diapire and side perisporium, described grinding chamber has the first material mouth and the second material mouth, described first material interruption-forming is on described diapire, described second material interruption-forming extends to described roof on the perisporium of described side or from described side perisporium, one in described first material mouth and the second material mouth is charging aperture, another in described first material mouth and described second material mouth is discharging opening, the full-size d of described first material mouth in the radial direction of described vessel is 10-150 millimeter.

According to the mill for food processor of the present utility model, owing to there is grinding chamber in vessel, during use, can form negative pressure in grinding chamber, food materials can from the throat-fed the first material mouth and the second material mouth, after food materials are pulverized in grinding chamber, from discharge hole for discharge, process of lapping completes in grinding chamber, and operating noise is little, pulping efficiency and effects on slurry making is good, slurrying concentration is high, energy consumption is low; In addition, the full-size of the first material mouth is controlled between 10-150 millimeter, effectively can control the size of the food materials that can pass in and out vessel, ensure the normal operation of food processor, and can the charging of conservative control vessel and discharging speed, thus fully can pulverize food materials, ensure crushing effect.

In addition, according to the mill for food processor of the present utility model, following additional technical characteristic can also be had:

According to an embodiment of the present utility model, the full-size d of described first material mouth in the radial direction of described vessel is 30-60 millimeter.

According to an embodiment of the present utility model, the full-size d of described first material mouth in the radial direction of described vessel is 35-45 millimeter.

According to an embodiment of the present utility model, the gross area S0 of described charging aperture is 700-6400 square millimeter, and the gross area S1 of described discharging opening is 700-6400 square millimeter.

According to an embodiment of the present utility model, described vessel is revolving body, described first material mouth is for being formed in a circular open at the center of described diapire, described second material mouth is that multiple and along described vessel circumferential interval is arranged, described second material mouth is for being formed in the circular open on the perisporium of described side or the elongated hole for extending to described roof from described side perisporium.

According to an embodiment of the present utility model, the minimum point of described second material mouth is 5-60 millimeter to the distance h of the inner surface of described diapire.

According to an embodiment of the present utility model, the volume V0 of described grinding chamber is 24-165 milliliter.

According to an embodiment of the present utility model, the full-size D of described grinding chamber in the radial direction of described vessel is 12-200 millimeter.

According to an embodiment of the present utility model, the center at the top of described vessel is provided with axis hole.

According to an embodiment of the present utility model, the bottom of described vessel is provided with projection or blade, and described projection or the blade height h1 on the axial direction of described vessel is 0.5-20 millimeter and the quantity n1 of described projection or blade is 1-24.

Additional aspect of the present utility model and advantage will part provide in the following description, and part will become obvious from the following description, or be recognized by practice of the present utility model.

Accompanying drawing explanation

Above-mentioned and/or additional aspect of the present utility model and advantage will become obvious and easy understand from accompanying drawing below combining to the description of embodiment, wherein:

Fig. 1 and Fig. 2 is the structural representation of the mill for food processor according to the utility model embodiment;

Fig. 3 and Fig. 4 is the structural representation of the mill for food processor according to another embodiment of the utility model;

Fig. 5 and Fig. 6 is the sectional view of the mill for food processor according to the utility model two kinds of embodiments;

Fig. 7 and Fig. 8 is the structural representation of the mill for food processor according to another embodiment of the utility model;

Fig. 9 and Figure 10 is the structural representation of the mill for food processor according to another embodiment of the utility model;

Figure 11 to Figure 13 is the structural representation of the mill for food processor according to another embodiment of the utility model;

Figure 14 and Figure 15 is the structural representation of the mill for food processor according to the utility model embodiment;

Figure 16 to Figure 18 is the structural representation of the mill for food processor according to another embodiment of the utility model;

Figure 19 and Figure 20 is the structural representation of the mill for food processor according to another embodiment of the utility model;

Figure 21 and Figure 22 is the structural representation of the mill for food processor according to another embodiment of the utility model;

Figure 23 and Figure 24 is the structural representation of the mill for food processor according to another embodiment of the utility model;

Figure 25 is the sectional view of the shredder assemblies for food processor according to the utility model embodiment;

Figure 26 and Figure 27 is the structural representation of the shredder assemblies for food processor according to the utility model embodiment;

Figure 28 and Figure 29 is the structural representation of the shredder assemblies for food processor according to another embodiment of the utility model;

Figure 30 and Figure 31 is the structural representation of the shredder assemblies for food processor according to another embodiment of the utility model;

Figure 32 and Figure 33 is the structural representation of the shredder assemblies for food processor according to another embodiment of the utility model;

Figure 34 and Figure 35 is the structural representation of the shredder assemblies for food processor according to another embodiment of the utility model;

Figure 36 and Figure 37 is the structural representation of the shredder assemblies for food processor according to another embodiment of the utility model;

Figure 38 and Figure 39 is the structural representation of the shredder assemblies for food processor according to another embodiment of the utility model;

Figure 40 is the sectional view of the head of food processor according to the utility model embodiment;

Figure 41 is the sectional view of the head of food processor according to another embodiment of the utility model;

Figure 42 is the sectional view of the head of food processor according to another embodiment of the utility model;

Figure 43 is the sectional view of the head of food processor according to another embodiment of the utility model;

Figure 44 is the sectional view of the food processor according to the utility model embodiment;

Figure 45 is the sectional view of the food processor according to another embodiment of the utility model;

Figure 46 is the sectional view of the food processor according to another embodiment of the utility model;

Figure 47 is the sectional view of the food processor according to another embodiment of the utility model.

Reference numeral:

Mill 100; Shredder assemblies 200; Head 300; Food processor 400;

Vessel 10; Roof 101; Diapire 102; Side perisporium 103; Top shell 104; Drain pan 105; Prismatic structure 106; Protruding 107;

Grinding chamber 11; First material mouth 12; Second material mouth 13; Axis hole 14; Recess 15; Groove 16;

Rotating shaft 20; First end 21; Second end 22; Transmission coupler 23;

Crushed piece 30; Head body 40; Head lower cover 41; Motor 50; Motor shaft 51; Ladle body 60.

Detailed description of the invention

Be described below in detail embodiment of the present utility model, the example of described embodiment is shown in the drawings, and wherein same or similar label represents same or similar element or has element that is identical or similar functions from start to finish.Be exemplary below by the embodiment be described with reference to the drawings, be intended to for explaining the utility model, and can not be interpreted as restriction of the present utility model.

First the mill 100 for food processor according to the utility model embodiment is specifically described by reference to the accompanying drawings below.

As shown in Fig. 1 to Figure 24, the mill 100 for food processor according to the utility model embodiment comprises vessel 10, there is in vessel 10 grinding chamber 11, grinding chamber 11 has the first material mouth 12 and the second material mouth 13, one in first material mouth 12 and the second material mouth 13 is charging aperture, and another in the first material mouth 12 and the second material mouth 13 is discharging opening.

In other words, a vessel 10 is comprised according to the mill 100 of the utility model embodiment, grinding chamber 11 is limited with in vessel 10, vessel 10 is provided with the first material mouth 12 and the second material mouth 13 with grinding chamber 11 conducting, wherein the first material mouth 12 can be charging aperture, also can be discharging opening, the second material mouth 13 also both can be charging aperture, can be again discharging opening.

Particularly, when the first material mouth 12 is charging aperture, then the second material mouth 13 is discharging opening, and when the first material mouth 12 is discharging opening, then the second material mouth 13 is charging aperture.First material mouth 12 and the second material mouth 13 can be material mouth independently, also can be same material mouth, namely vessel 10 can be arranged respectively the first material mouth 12 and the second material mouth 13, also the first material mouth 12 and the second material mouth 13 can be set to same material mouth, namely this material mouth both can as charging aperture, also can as discharging opening.

Thus, according to the mill 100 for food processor of the utility model embodiment, owing to there is grinding chamber 11 in vessel 10, during use, in grinding chamber 11, negative pressure can be formed, food materials can from the throat-fed the first material mouth 12 and the second material mouth 13, after food materials are pulverized in grinding chamber 11, from discharge hole for discharge, process of lapping completes in grinding chamber 11, operating noise is little, pulping efficiency and effects on slurry making is good, slurrying concentration is high, energy consumption is low.

According to an embodiment of the present utility model, vessel 10 has roof 101, diapire 102 and side perisporium 103, first material mouth 12 and the second material mouth 13 are same opening, and opening is that it is single or multiple to be formed on diapire 102, and the gross area of opening is less than the area of diapire 102.

As depicted in figs. 1 and 2, vessel 10 is made up of roof 101, diapire 102 and side perisporium 103, and the first material mouth 12 and the second material mouth 13 are set to same material mouth, and this material mouth is located on diapire 102, both can as charging aperture, again can as discharging opening.

Opening can be made up of multiple aperture with grinding chamber 11 conducting, also can be made up of a macropore, the gross area of opening is less than the area of diapire 102, when opening is made up of a macropore, then on diapire 102, be formed as throat structure with the opening of grinding chamber 11 conducting, food materials enter grinding chamber 11 from this reducing and grind, and after having ground, then flow out from this reducing.

Mill 100 according to the utility model embodiment can be provided with axis hole 14 at the center at the top of vessel 10, the mill 100 of this structure in use, the rotating shaft of food processor can pass axis hole 14, crushed piece on rotating shaft stretches in grinding chamber 11, when rotating shaft drives crushed piece to rotate, slurrying can be carried out in grinding chamber 11.

When crushed piece is located in grinding chamber 11, crushed piece is rotated, negative pressure can be formed in grinding chamber 11, namely the pressure in grinding chamber 11 is lower than the pressure in the ladle body of food processor, thus food materials can be inhaled in grinding chamber 11 from the reducing of the below of vessel 10, food materials are pulverized in grinding chamber 11, reduce noise, improve crush efficiency and effect, slurrying concentration improves.

The throat structure of vessel 10 can make to limit a grinding chamber 11 relatively closed in vessel 10, the vessel 10 of this structure is when crushed piece is rotated, negative pressure can be formed better in grinding chamber 11, thus can better food materials be pulverized in grinding chamber 11.In addition, the food materials pulverized are discharged from throat structure again, can play certain flow-disturbing effect, also can improve crushing effect further in discharge process to the food materials entering reducing.

In other detailed description of the invention of the present utility model, vessel 10 has roof 101, diapire 102 and side perisporium 103, first material mouth 12 is formed on diapire 102 and the gross area of the first material mouth 12 is less than the area of diapire 102, and it is upper or extend to roof 101 from side perisporium 103 that the second material mouth 13 is formed in one of side perisporium 103 and roof 101.

As shown in Figures 3 to 8, in embodiment of the present utility model, first material mouth 12 and the second material mouth 13 are two perforates independently, wherein, first material mouth 12 is located on diapire 102, and is formed as throat structure equally, and the second 13, material mouth can be located on roof 101, also can be located on side perisporium 103, can also be located on side perisporium 103 and roof 101 simultaneously.

Wherein, the first material mouth 12 that the diapire 102 in the utility model embodiment is arranged is throat structure, and this throat structure both can as charging aperture, also can as discharging opening.Throat structure in this throat structure and above-described embodiment is similar, is therefore not described in detail.

Second material mouth 13 and the first material mouth 12 be mutually independently two expect mouth, second material mouth 13 is located at other positions on vessel 10 except arranging the diapire 102 of the first material mouth 12, namely both can be located on roof 101, also can be located on side perisporium 103, also can be located on both simultaneously.

Particularly, as shown in Figure 3 and Figure 4, in this embodiment, the second material mouth 13 comprises multiple, and multiple second material mouth 13 is spaced apart to be respectively located on roof 101.As shown in Figure 5 and Figure 6, in this embodiment, 13, the second material mouth is located on side perisporium 103.In the embodiment shown in Fig. 7 and Fig. 8, the second 13, material mouth extends on roof 101 from the side perisporium 103 of vessel 10.

According to the mill 100 of the utility model embodiment, when the first material mouth 12 is charging aperture, then the second material mouth 13 is discharging opening, when the first material mouth 12 is discharging opening, then the second material mouth 13 can as charging aperture, exchange between charging aperture and discharging opening can be regulated by the rotation direction of crushed piece on rotating shaft, and this regulative mode is appreciated that to those skilled in the art and easily realizes, and is therefore not described in detail.

The mill 100 of this structure in use, no matter the first material mouth 12 is as charging aperture or discharging opening, can make a distinction between the food materials entered from charging aperture and the food materials flowed out from discharging opening, charging aperture normally can enter food materials, discharging opening normally can flow out food materials, both can not disturb mutually, thus can improve repulping rate and the pulping efficiency of food processor.

As shown in Figure 5, according to an embodiment of the present utility model, the structure that the roof 101 of vessel 10, diapire 102 and side perisporium 103 can be formed as one, the i.e. structure that is formed as one of vessel 10, this vessel 10 structure is simple, convenient formation, and structural stability is strong, with low cost.

And as shown in Figure 6, in other detailed description of the invention of the present utility model, vessel 10 also can for the structure assembled, the drain pan 105 that vessel 10 can comprise top shell 104 and removably be connected with top shell 104, and top shell 104 and drain pan 105 can be threaded connection.

Wherein, drain pan 105 can be formed as the tubbiness of open upper end, first material mouth 12 can be located on the diapire of drain pan 105, top shell 104 can be formed as the tubbiness of open at its lower end, second material mouth 13 can be located on the perisporium of top shell 104, axis hole 14 is located on the roof of top shell 104, and drain pan 105 is threaded mutually with two open ends of top shell 104.

Thus, the vessel 10 of this structure can be formed by assembling, and top shell 104 and drain pan 105 can be dismantled after being used to complete, and is ensureing, on the basis that structure is simple and easy to assembly, to be convenient to vessel 10 to clean.

In other detailed description of the invention of the present utility model, vessel 10 has roof 101 and side perisporium 103, the bottom surface of vessel 10 is opened wide and is formed on one of side perisporium 103 and roof 101 to form the first material mouth 12, second material mouth 13 or extends to roof 101 from side perisporium 103.

In other words, as shown in Figure 14 to Figure 24, in the present embodiment, vessel 10 does not have diapire, only there is side perisporium 103 and roof 101, the open bottom end of vessel 10 forms the first material mouth 12, at least one of side perisporium 103 and roof 101 is arranged the second material mouth 13, and axis hole 14 is located on the roof 101 of vessel 10.

The vessel 10 of the present embodiment is for above-described embodiment, and the bottom-open of vessel 10 forms the first material mouth 12, at least one of side perisporium 103 and roof 101 is arranged the second material mouth 13, charging aperture and the separate setting of discharging opening.

First material mouth 12 size of the vessel 10 of this structure is larger, during as charging aperture or discharging opening, food materials turnover speed, charging aperture and discharging opening are independent mutually, food materials turnover can not produce interference, can improve repulping rate and the pulping efficiency of food processor to a certain extent.

Particularly, according to an embodiment of the present utility model, vessel 10 is bowl-shape, and the cross section of side perisporium 103 is regular polygon or is joined end to end the annular formed by multiple arcuate line segment.

As shown in Figure 14 and Figure 15, in this embodiment, vessel 10 is bowl-shape, and the open at its lower end of vessel 10 forms the first material mouth 12, first material mouth 12 and is formed as being joined end to end the substantial circular structure formed by multiple arcuate line segment.

That is, vessel 10 first material mouth 12 is not a regular circular configuration, the side perisporium 103 of vessel 10 is provided with multiple prismatic structure 106 caved inward, this prismatic structure 106 can play flow-disturbing effect when food processor uses to the food materials in grinding chamber 11, thus further increase crushing effect and the efficiency of food materials, and slurrying concentration improves greatly.

In addition, due to mill 100 rotating Vortex under the drive of food materials, mill 100 diminishes with the speed discrepancy of food materials, the mill 100 simultaneously rotated also can stir food materials stably, food materials being more evenly distributed in ladle body thus, the rotation of food materials is also more steady, and the flow-disturbing effect of mill 100 is then more remarkable, also reduce the noise that food materials and mill 100 produce because speed discrepancy is comparatively large simultaneously, achieve the object to food processor noise reduction better.

As shown in Figure 16 to Figure 18, in this embodiment, the cross section of vessel 10 is formed as regular polygon, the prismatic structure formed between any two adjacent faces of this regular polygon structure can play the effect to food materials flow-disturbing equally, thus crushing effect and the efficiency of food materials can be improved equally, its structure can effect be not described in detail.

In other detailed description of the invention of the present utility model, vessel 10 is hemispherical, the bottom surface of vessel 10 is opened wide to form the first material mouth 12, second material mouth 13 is formed on the wall of vessel 10, and the lower edge of vessel 10 has the isolated recess 15 of multiple circumference along vessel 10, the outside wall surface of vessel 10 has and extends along the vertical direction and the groove 16 inwardly concaved.

Particularly, as illustrated in figures 19 and 20, in this embodiment, vessel 10 is formed as hemispherical dome structure substantially, the open at its lower end of vessel 10 forms the first material mouth 12, the lower edge of this vessel 10 is provided with the isolated recess 15 of multiple circumference along vessel 10, and this recess 15 also can carry out charging or discharging as the second material mouth 13, and the wall of the vessel 10 between adjacent two recesses 15 is provided with the groove 16 be recessed to vessel 10.

Each groove 16 is recessed respectively to the grinding chamber 11 of vessel 10, the sidewall being then equivalent to vessel 10 is provided with multiple projection outstanding in grinding chamber 11, these projections can play flow-disturbing effect equally when food processor uses to the food materials in grinding chamber 11, thus also improve crushing effect and the efficiency of food materials, and slurrying concentration improves greatly.

According to an embodiment of the present utility model, vessel 10 is for having the straight-tube shape of roof 101 and side perisporium 103, the bottom surface of vessel 10 is opened wide and is formed on side perisporium 103 to form the first material mouth 12, second material mouth 13, and axis hole 14 can be located on roof 101.Further, the lower end of vessel 10 is horn-like.

As shown in figure 21 and figure, vessel 10 is formed as the straight-tube shape structure of open at its lower end substantially, the open end of vessel 10 is formed as the first material mouth 12, and the opening size of the first material mouth 12 is greater than the radial dimension of vessel 10, and the second 13, material mouth is located on side perisporium 103.

Thus, the first material mouth 12 of this structure has larger opening, when using as charging aperture, can suck food materials more easily, improves charging rate.

In addition, in detailed description of the invention more of the present utility model, the cross section of side perisporium can also to join end to end the annular formed for circular, oval, regular polygon or by multiple arcuate line segment.

Particularly, as shown in Figure 9 and Figure 10, in this embodiment, the first 12 of vessel 10 is throat structure, and the cross section of vessel 10 is formed as oval.In embodiment shown in Figure 11 to Figure 13, the first material mouth 12 of vessel 10 is similarly throat structure, and the cross section of vessel 10 is then regular polygon, and whole vessel 10 is formed as lantern-shaped.

In the embodiment shown in Figure 23 and Figure 24, the open at its lower end of vessel 10 forms the first material mouth 12, and the cross section of vessel 10 then forms ellipse.The vessel 10 of these structures can play the flow-disturbing effect to food materials to a certain extent, thus can play the effect improving pulping efficiency.

In an embodiment of the present utility model, mill 100 for food processor comprises vessel 10, there is in vessel 10 grinding chamber 11, vessel 10 has roof 101, diapire 102 and side perisporium 103, grinding chamber 11 has the first material mouth 12 and the second material mouth 13, first material mouth 12 is formed on diapire 102, second material mouth 13 is formed on side perisporium 103 or from side perisporium 103 and extends to roof 101, one in first material mouth 12 and the second material mouth 13 is charging aperture, another in first material mouth 12 and the second material mouth 13 is discharging opening, the full-size d of the first material mouth 12 in the radial direction of vessel 10 is 10-150 millimeter.

That is, as shown in Figure 5, in the present embodiment, the first material mouth 12 is located on diapire 102, and the first material mouth 12 can be one and be located at the center of diapire 102, also can be multiple, and is spaced apartly located on diapire 102.When the first material mouth 12 is one, and when being located at the center of diapire 102, then the full-size of the opening of the first material mouth 12 is between 10-150 millimeter.

When the first material mouth 12 is circular hole, then the first material mouth 12 full-size diametrically i.e. diameter of the first material mouth 12, the diameter d of the first material mouth 12 is between 10-150 millimeter.

The full-size of the first material mouth 12 is controlled between 10-150 millimeter, effectively can control the size of the food materials that can pass in and out vessel 10, ensure the normal operation of food processor, and can the charging of conservative control vessel 10 and discharging speed, fully can pulverize food materials, ensure crushing effect, thus ensure repulping rate and the pulping efficiency of food processor.

Alternatively, according to an embodiment of the present utility model, the full-size d of the first material mouth 12 in the radial direction of vessel 10 is 30-60 millimeter.Further, the full-size d of the first material mouth 12 in the radial direction of vessel 10 is 35-45 millimeter.

Thus, first material mouth 12 is preferably dimensioned to be 35-45 millimeter, both the size of the food materials entering vessel 10 can have been controlled more accurately, the size of the food materials flowed out from vessel 10 can be controlled again, while can ensureing that mill 1000 normally uses, the pulverizing of food materials can be controlled more accurately, thus ensure effects on slurry making.

In detailed description of the invention more of the present utility model, the gross area S0 of charging aperture is 700-6400 square millimeter, and the gross area S1 of discharging opening is 700-6400 square millimeter.

That is, the gross area of the first material mouth 12 is 700-6400 square millimeter, and the gross area of the second material mouth 13 is also 700-6400 square millimeter.Thus, the size of discharging opening is corresponding with the size of charging aperture, while guarantee charging rate, reasonably can control discharging speed, thus ensures that the integral grinding process of mill 100 can be carried out smoothly, improves pulping efficiency.

Particularly, according to an embodiment of the present utility model, vessel 10 is revolving body, first material mouth 12 can for being formed in a circular open at the center of diapire 101, second material mouth 13 is that multiple and along vessel 10 circumferential interval is arranged, second material mouth 13 is for being formed in circular open on side perisporium 103 or the elongated hole for extending to roof 101 from side perisporium 103, and the minimum point of the second material mouth 13 is 5-60 millimeter to the distance h of the inner surface of diapire 101.

As shown in Figure 3, in the embodiment shown in this figure, the second material mouth 13 is multiple circular opens be located on side perisporium 103, and in the embodiment shown in fig. 7, the second 13, material mouth is formed as the elongated hole extending to roof 101 from side perisporium 103.Wherein, no matter be the embodiment shown in Fig. 3, or the embodiment shown in Fig. 7, the minimum point of the second material mouth 13 is that the scope of h, h is between 5-60 millimeter to the distance definition of the inner surface of diapire 101.

Be circular hole for the second material mouth 13 and be located on side perisporium 103, as shown in Figure 5, the distance between the minimum point of the second material mouth 13 and the upper surface of diapire 101 is h, and the scope of this distance h is between 5-60 millimeter.First material mouth 12 is located on diapire 101, is also just equivalent to the difference in height of the first material mouth 12 and the second material mouth 13 in the vertical direction between 5-60 millimeter.

When the first material mouth 12 is charging aperture, then the second material mouth 13 is discharging opening, food materials enter grinding chamber 11 from the first material mouth 12 be positioned at bottom vessel 10, after crushed piece is pulverized, can flow out from the second material mouth 13 be positioned at side perisporium 103, distance between first material mouth 12 and the second material mouth 13 is arranged between 5-60 millimeter, can ensures that the food materials entered from the first material mouth 12 could be discharged from the second material mouth 13 after fully pulverizing, ensure that the crushing effect of food materials.

Thus, between first material mouth 12 and the second material mouth 13, the distance at interval is preferably 5-60 millimeter, food materials can be controlled better from the distance being fed to discharging, thus ensure the time that food materials grind in grinding chamber 11, while raising crushing effect, discharging and charging rate can also be ensured, thus improve overall repulping rate and the pulping efficiency of food processor.

In detailed description of the invention more of the present utility model, the volume V0 of grinding chamber 11 is 24-165 milliliter.That is, the volume V0 that can hold food materials in vessel 10 is 24-165 milliliter.

Thus, the volumetric void fraction of grinding chamber 11, between 24-165 milliliter, can control the amount of the food materials that can hold in vessel 10, thus fully can pulverize food materials, ensures crushing effect.The vessel 10 of this structure can with the ladle body physical fit of existing food processor, and the volume of grinding chamber 11 reduction compared with the volume of ladle body, improves crush efficiency and the crushing effect of food materials, further increases slurrying concentration.

Preferably, according to an embodiment of the present utility model, the full-size D of grinding chamber 11 in the radial direction of vessel 10 is 12-200 millimeter.

Particularly, as shown in Figure 5, vessel 10 can be formed as column structure substantially, limits grinding chamber 11 in vessel 10, then vessel 10 full-size is diametrically the diameter of vessel 10, and the size of the diameter D of vessel 10 is between 12-200 millimeter.

Thus, the vessel 10 of this structure can with the ladle body physical fit of existing food processor, and the volume of grinding chamber 11 reduction compared with the volume of ladle body, improves crush efficiency and the crushing effect of food materials, further increases slurrying concentration.

Further, according to an embodiment of the present utility model, the full-size d of the first material mouth 12 in the radial direction of vessel 10 is 10-150 millimeter.

When the first material mouth 12 is circular hole, then the first material mouth 12 full-size diametrically i.e. diameter of the first material mouth 12, the diameter d of the first material mouth 12 is between 10-150 millimeter.Thus, the size of the first material mouth 12 is arranged within this scope, the charging rate of food materials can be ensured, thus ensure repulping rate and the pulping efficiency of food processor.

In detailed description of the invention more of the present utility model, the bottom of vessel 10 is provided with protruding 107 or blade, and projection 107 or the height h1 of blade on the axial direction of vessel 10 are 0.5-20 millimeter and the quantity n1 of projection 107 or blade is 1-24.

Particularly, as depicted in figs. 1 and 2, the first material mouth 12 of vessel 10 is not formed by the bottom-open of vessel 10, but is formed as being located at the throat structure on diapire 102.The lower surface of diapire 102 is then provided with multiple projection 107 arranged spaced apart along the circumference of vessel 10 or blade construction.

Wherein, as shown in Figure 5, projection 107 or blade height are in the vertical direction 0.5-20 millimeter, and the number of projection 107 or blade is between 1-24.Thus, vessel 10 is when rotating, and the projection 107 on vessel 10 or blade construction then can drive food materials to stir, and improves flow-disturbing effect further.

In addition, rotating shaft drives crushed piece High Rotation Speed, the crushed piece of High Rotation Speed drives food materials to rotate in ladle body, under the drive of food materials, mill 100 absorbs the part kinetic energy of food materials and with food materials rotating Vortex, because vessel 10 is provided with protruding 107 or blade construction, the active force that mill 100 is subject under the drive of food materials is larger, the corresponding raising of rotating speed of mill 100, mill 100 diminishes with the speed discrepancy of food materials.

Simultaneously, the mill 100 rotated also can stir food materials stably, food materials being more evenly distributed in ladle body thus, the rotation of food materials is also more steady, the flow-disturbing effect of mill 100 is then more remarkable, also reduce the noise that food materials and mill 100 produce because speed discrepancy is comparatively large simultaneously, achieve the object to food processor noise reduction better.

Further, vessel 10 arranges protruding 107 or blade, under the drive of food materials, mill 100 can absorb the part kinetic energy of food materials more and with food materials rotating Vortex, food materials are under the effect of mill 100, kinetic energy diminishes, rotating speed reduces, and the speed discrepancy of food materials and crushed piece becomes greatly, is equivalent to crushed piece cutting speed and becomes large, therefore, the effect of pulverizing can be better.

The food processor 400 according to the utility model embodiment is specifically described below in conjunction with accompanying drawing.

As shown in Figure 44 to Figure 47, according to the head 300 that the food processor 400 of the utility model embodiment comprises ladle body 60 and is arranged on ladle body 60.

Specifically, head body 40, motor 50, mill 100, rotating shaft 20 and the crushed piece 30 for pulverizing the food materials in ladle body 60 is comprised according to the head 300 of the food processor of the utility model embodiment, wherein, mill 100 is the mill 100 according to the utility model above-described embodiment.

Particularly, rotating shaft 20 has first end 21 and the second end 22, and motor 50 is located in head body 10, and motor 50 is connected to drive rotating shaft 20 to rotate with the second end 22 of rotating shaft 20.It is interior and rotatable relative to ladle body 60, head body 40 and rotating shaft 20 that mill 100 is located at ladle body 60, mill 100 comprises vessel 10, vessel 10 be arranged in ladle body 60, head body 40 and rotating shaft 20 one upper and relative to head body 40 and rotating shaft 20 rotatable.

As shown in Fig. 1 to Figure 24, according to the utility model embodiment for there is grinding chamber 11 in the vessel 10 of food processor, grinding chamber 11 has the first material mouth 12 and the second material mouth 13, one in first material mouth 12 and the second material mouth 13 is charging aperture, and another in the first material mouth 12 and the second material mouth 13 is discharging opening.

The first end 21 of rotating shaft 20 stretches in grinding chamber 11, and the second end 22 of rotating shaft 20 stretches out grinding chamber 11 and is connected with motor 50, and crushed piece 30 is arranged on the first end 21 of rotating shaft 20 and is positioned at grinding chamber 11.

The first end 21 of rotating shaft 20 stretches in grinding chamber 11, and first end 21 is provided with crushed piece 30, and the second end 22 of rotating shaft 20 is connected with the motor 50 in head body 40 and is driven by motor 50.Rotating shaft 20 is rotatable relative to mill 100, thus crushed piece 30 can be driven to rotate in grinding chamber 11.Rotating shaft 20 drives crushed piece 30 High Rotation Speed, when crushed piece 30 is located in grinding chamber 11, negative pressure can be formed in grinding chamber 11, namely the pressure in grinding chamber 11 is lower than the pressure in the ladle body 60 of food processor 400, thus food materials are inhaled in grinding chamber 11, food materials are pulverized in grinding chamber 11, reduce noise, improve crush efficiency and effect, slurrying concentration improves.

In addition, the crushed piece 30 of High Rotation Speed drives food materials to rotate in ladle body, under the drive of food materials, mill 100 absorb food materials part kinetic energy and with food materials rotating Vortex, due to mill 100 rotating Vortex under the drive of food materials, mill 100 diminishes with the speed discrepancy of food materials, the mill 100 simultaneously rotated also can stir food materials stably, food materials being more evenly distributed in ladle body 60 thus, the rotation of food materials is also more steady, the flow-disturbing effect of mill 100 is then more remarkable, also reduce the noise that food materials and mill 100 produce because speed discrepancy is comparatively large simultaneously, achieve the object to food processor noise reduction better.

In addition, under the drive of food materials, mill 100 absorb food materials part kinetic energy and with food materials rotating Vortex, food materials are under the effect of mill 100, and kinetic energy diminishes, and rotating speed reduces, the speed discrepancy of food materials and crushed piece 30 becomes large, be equivalent to crushed piece 30 cutting speed and become large, therefore, the effect of pulverizing can be better.

Due to volume reduction compared with the volume of ladle body 60 of grinding chamber 11, improve crush efficiency and the crushing effect of food materials, further increase slurrying concentration, simultaneously due to there are the food materials of mill 100 in ladle body 60 of grinding chamber 11 drive under relatively with ladle body 60 relative to rotating shaft 20 (thus relative to crushed piece 30) to rotate, therefore, food materials are ground further in the grinding chamber of mill 100, further increase crushing effect and the efficiency of food materials, and slurrying concentration improves greatly, therefore, mill 100 in the application has the double action of grinding and flow-disturbing.

Thus, according to the food processor 400 of the utility model embodiment, motor 50 is provided with in head body 40, motor 50 can drive coupled rotating shaft 20 to rotate, owing to there is grinding chamber 11 in vessel 10, rotating shaft 20 first end 21 stretches in grinding chamber 11 and first end 11 is provided with the crushed piece 30 being positioned at grinding chamber 11, during use, motor 50 drives rotating shaft 20 to drive crushed piece 30 to rotate, negative pressure can be formed in grinding chamber 11, food materials can from the throat-fed the first material mouth 12 and the second material mouth 13, after food materials are pulverized in grinding chamber 11, from discharge hole for discharge, process of lapping completes in grinding chamber 11, operating noise is little, pulping efficiency and effects on slurry making good, slurrying concentration is high, energy consumption is low.

According to the mill 100 that the mill 100 in the food processor 400 of the utility model embodiment is according to above-described embodiment, because the mill 100 according to the utility model above-described embodiment has said structure and technique effect, therefore, shredder assemblies 200 according to the utility model embodiment also has corresponding structure and technique effect, is not described in detail at this.

Wherein, in an embodiment of the present utility model, vessel 10 have roof 101, diapire 102 and side perisporium 103, first material mouth 12 and the second material mouth 13 be same opening, opening is that it is single or multiple to be formed on diapire 102, and the gross area of opening is less than the area of diapire 102.

As shown in Figure 14 to 18, according to an embodiment of the present utility model, vessel 10 is bowl-shape or straight-tube shape, the cross section of the side perisporium 103 of bowl body 10 is regular polygon or is joined end to end the annular formed by multiple arcuate line segment, and the cross section of the side perisporium of straight-tube shape vessel 10 is circular, oval, regular polygon or is joined end to end the annular formed by multiple arcuate line segment.

According to an embodiment of the present utility model, rotating shaft 20 and the motor shaft 51 of motor 50 are same axle or are removably connected with the motor shaft 51 of motor 50 by transmission coupler 23.

Particularly, as shown in figure 42, rotating shaft 20 is the motor shaft 51 of motor 50, and the first end 21 of rotating shaft 20 stretches in grinding chamber 11, and the second end 22 of rotating shaft 20 stretches into motor 50 inside and driven by motor 50.Rotating shaft 20 and the motor 50 of this structure are structure as a whole, and structure is simple, easy to assembly.

In other detailed description of the invention of the present utility model, rotating shaft 20 and the motor shaft 51 of motor 50 are not one, but be connected by transmission coupler 23.As shown in figure 43, motor 50 has the motor shaft 51 of upper downward-extension, the lower end of motor shaft 51 is provided with transmission coupler 23, second end 22 of rotating shaft 20 is also provided with transmission coupler 23, the rotating shaft 20 of this structure can be dismantled with motor 50 easily, be convenient to integral demounting and the replacing of mill 100, convenient cleaning.

It should be noted that, vessel 10 can be arranged on in head body 40 and rotating shaft 20, as long as meet vessel 10 relative to head body 40 with rotating shaft 20 is rotatable requires.

Alternatively, according to an embodiment of the present utility model, the center at the top of vessel 10 is provided with axis hole 14, and the first end 21 of rotating shaft 20 stretches in grinding chamber 11 through axis hole 14, and the bottom of vessel 10 is provided with protruding 107 or blade.

Particularly, as shown in figure 41, the roof 101 of vessel 10 is provided with axis hole 14, the lower end of rotating shaft 20, namely first end 21 stretches in grinding chamber 11 through axis hole 14, and crushed piece 30 is located on first end 21, and vessel 10 is arranged on also can be rotatable relative to rotating shaft 20 on rotating shaft 20.

Vessel 10 and the rotating shaft 20 of this structure assemble simply, head body 40 structure without the need to changing, only need on rotating shaft 20 sheathed vessel 10, assemble simply.

As depicted in figs. 1 and 2, the first material mouth 12 of vessel 10 is not formed by the bottom-open of vessel 10, but is formed as being located at the throat structure on diapire 102.The lower surface of diapire 102 is then provided with multiple projection 107 arranged spaced apart along the circumference of vessel 10 or blade construction.

In other detailed description of the invention of the present utility model, vessel 10 is rotatably installed in head body 40.Particularly, as shown in figure 40, be provided with head lower cover 41 below head body 40, vessel 10 is rotatably installed on the head lower cover 41 of head body 40.

Wherein, the lower end of head lower cover 41 is provided with draw-in groove, and the upper end of vessel 10 is provided with axis hole 14, and the draw-in groove of head lower cover 41 can be connected in the axis hole 14 of vessel 10, thus vessel 10 can be rotated around head lower cover 41.

Due to rotating shaft 20 meeting High Rotation Speed under the drive of motor 50, vessel 10 is then driven by the food materials in the ladle body of food processor and forms rotation, very large speed discrepancy can be there is between vessel 10 and rotating shaft 20, thus cause the wearing and tearing of vessel 10 and rotating shaft 20.

And according to the head body 40 of the utility model embodiment, vessel 10 is arranged on head lower cover 41, can not directly contact and rub between rotating shaft 20 with vessel 10, the wearing and tearing of vessel 10 and rotating shaft 20 can be greatly reduced, increase the service life.

As shown in Figure 46 and Figure 47, in other detailed description of the invention of the present utility model, mill 100 can also be rotatably installed on the inwall of ladle body 60.

Particularly, as shown in figure 46, mill 100 can be rotatably installed on the diapire of ladle body 60 by bearing, and the area that the upper end of vessel 10 is provided with the first material mouth 12, first material mouth 12 is less than the area of the upper surface of vessel 10.The side perisporium of vessel 10 is provided with the second material mouth 13, and the first end 21 of rotating shaft 20 stretches in the first material mouth 12 from the top down, and first end 21 is provided with crushed piece 30, and crushed piece 30 is arranged in grinding chamber 11.

The food processor 400 of this structure in use, motor 50 drives crushed piece 30 to rotate by rotating shaft 20, negative pressure is formed in grinding chamber 11, food materials enter in grinding chamber 11 from the first material mouth 12 of the upper end of vessel 10, after grinding, discharge grinding chamber 11 from the second material mouth 13 being positioned at side perisporium.

The mill 100 of the food processor 400 of this structure is arranged on by bearing on the diapire of ladle body 60, and mill 100 can not produce with rotating shaft 20 or head body 40 and rub in rotation process, decreases the wearing and tearing of mill 100, extends service life.

As shown in figure 47, mill 100 can be rotatably installed on the diapire of ladle body 60 by bearing equally, in this embodiment, the upper end of vessel 10 is provided with axis hole 14, the first end 21 of rotating shaft 20 stretches in grinding chamber 11 through axis hole 14, first material mouth 12 is located on the lower surface of vessel 10, and the area of the first material mouth 12 is less than the area of the lower surface of vessel 10.

The present embodiment is compared with above-described embodiment, first material mouth 12 is located on the diapire of mill 100, the food processor 400 of this structure in use, food materials enter grinding chamber 11 from the bottom feed mouth of mill 100 and grind, the second material mouth 13 from side perisporium after having ground flows out mill 100, food materials flowing is more convenient, improves grinding efficiency.

Below in conjunction with specific embodiment, the food processor 400 according to the utility model embodiment is described.

As shown in figure 25, in embodiment of the present utility model, food processor 400 is soy bean milk making machine, and the first material mouth 12 is located on the diapire 101 of vessel 10, and the second material mouth 13 is located on the side perisporium 103 of vessel 103.

In specific embodiments more of the present utility model, the ratio of the gross area S0 of the first material mouth 12 of mill 100 and the gross area S1 of the second material mouth 13 is 0.02-55, the ratio of the volume V0 of grinding chamber 11 and the gross area S0 of the first material mouth 12 is 0.001-1.500, the ratio of the gross area S0 of the first material mouth 12 and the rotational speed omega 1 of vessel 10 is 0.04-11000, the ratio of the gross area S0 of the first material mouth 12 and the difference in height h between the first material mouth 12 and the second material mouth 13 is 2-11000, the ratio of the volume V0 of grinding chamber 11 and the gross area S1 of the second material mouth 13 is 0.001-1.500, the ratio of the gross area S1 of the second material mouth 13 and the rotational speed omega 1 of vessel 10 is 0.04-11000, the ratio of the gross area S1 of the second material mouth 13 and the difference in height h between the first material mouth 12 and the second material mouth 13 is 2-11000.

Ratio between the volume V0 of grinding chamber 11 and the rotational speed omega 1 of vessel 10 is 0.001-300, the ratio of the rotational speed omega 1 of vessel 10 and the maximum radial dimension d of the first material mouth 12 is 0.01-500, the ratio of the rotational speed omega 1 of vessel 10 and the difference in height h between the first material mouth 12 and the second material mouth 13 is 0.01-5000, the ratio of the rotational speed omega 1 of vessel 10 and the height dimension h1 of projection 107 or blade is 0.05-10000, the ratio of the rotational speed omega 1 of vessel 10 and the number n1 of projection 107 or blade is 0.04-5000, the ratio of the maximum inner diameter dimension D of vessel 10 and the maximum radial dimension d of the first material mouth 12 is 1.2-20.

The ratio of the height dimension h1 of heating power P and protruding 107 or blade is 0.5-4000, the ratio 0.417-2000 of the number n1 of heating power P and protruding 107 or blade, the rotational speed omega 1 of vessel 10 is 1.5-8000 with the ratio of the rotational speed omega 1 of vessel 10, the rotational speed omega 1 of vessel 10 is 0.167-2500 with the ratio of the blade number n2 of crushing knife, the rotational speed omega 1 of vessel 10 is 0.013-200 with the ratio of the diameter d 2 of crushing knife, the ratio of the specified slurrying capacity V1 of food processor 400 and the volume V0 of grinding chamber 11 is 1-333, the diameter d 2 of crushing knife and between crushing knife and the first material mouth 12 in the vertical direction the ratio of the distance h2 at interval be 0.31-160, the ratio of the maximum inner diameter dimension D of vessel 10 and the diameter d 2 of crushing knife is 1.2-8.

Can be specifically: the gross area S0 of the first material mouth 12 of mill 100 is 200-11000 square millimeter, the gross area S1 of the second material mouth 13 is 200-11000 square millimeter, difference in height h between first material mouth 12 and the second material mouth 13 is 1-100 millimeter, the maximum radial dimension d of the first material mouth 12 is 10-150 millimeter, and the maximum inner diameter dimension D of vessel 10 is 12-200 millimeter.The volume V0 of grinding chamber 11 is 6-300 milliliter, the rotational speed omega 1 of vessel 10 is 1-5000 rev/min, the projection 107 of the lower end of vessel 10 or the height dimension h1 of blade are 0.5-20 millimeter, the number n1 of projection 107 or blade is between 1-24, the heating power P of food processor 400 is 10-2000 watt, crushed piece 30 can be crushing knife, the rotational speed omega 2 of crushing knife is 1000-20000 rev/min, the blade number n2 of crushing knife is between 2-6, the diameter d 2 of crushing knife is 35-80 millimeter, the specified slurrying capacity V1 of food processor 400 is 150-2000 milliliter, between crushing knife and the first material mouth 12, the distance h2 at interval is 0.5-80 millimeter in the vertical direction.

Further, the utility model provides the specific embodiment of a soy bean milk making machine, as follows:

In specific embodiment of the utility model, the ratio of the gross area S0 of the first material mouth 12 of mill 100 and the gross area S1 of the second material mouth 13 is 0.11-9, the ratio of the volume V0 of grinding chamber 11 and the gross area S0 of the first material mouth 12 is 0.004-0.236, the ratio of the gross area S0 of the first material mouth 12 and the rotational speed omega 1 of vessel 10 is 0.7-640, the ratio of the gross area S0 of the first material mouth 12 and the difference in height h between the first material mouth 12 and the second material mouth 13 is 12-1280, the ratio of the volume V0 of grinding chamber 11 and the gross area S1 of the second material mouth 13 is 0.004-0.236, the ratio of the gross area S1 of the second material mouth 13 and the rotational speed omega 1 of vessel 10 is 0.70-640, the ratio of the gross area S1 of the second material mouth 13 and the difference in height h between the first material mouth 12 and the second material mouth 13 is 12-1280.

Ratio between the volume V0 of grinding chamber 11 and the rotational speed omega 1 of vessel 10 is 0.024-16.500, the ratio of the rotational speed omega 1 of vessel 10 and the maximum radial dimension d of the first material mouth 12 is 0.17-33, the ratio of the rotational speed omega 1 of vessel 10 and the difference in height h between the first material mouth 12 and the second material mouth 13 is 0.17-200, the ratio of the rotational speed omega 1 of vessel 10 and the height dimension h1 of projection 107 or blade is 1-1000, the ratio of the rotational speed omega 1 of vessel 10 and the number n1 of projection 107 or blade is 0.8-500, the ratio of the maximum inner diameter dimension D of vessel 10 and the maximum radial dimension d of the first material mouth 12 is 1.2-5.

The ratio of the height dimension h1 of heating power P and protruding 107 or blade is 10.0-1000, the ratio 8.333-500 of the number n1 of heating power P and protruding 107 or blade, the rotational speed omega 1 of vessel 10 is 2-1200 with the ratio of the rotational speed omega 1 of vessel 10, the rotational speed omega 1 of vessel 10 is 2-500 with the ratio of the blade number n2 of crushing knife, the rotational speed omega 1 of vessel 10 is 0.14-33 with the ratio of the diameter d 2 of crushing knife, the ratio of the specified slurrying capacity V1 of food processor 400 and the volume V0 of grinding chamber 11 is 3.6-71, the diameter d 2 of crushing knife and between crushing knife and the first material mouth 12 in the vertical direction the ratio of the distance h2 at interval be 0.75-35, the ratio of the maximum inner diameter dimension D of vessel 10 and the diameter d 2 of crushing knife is 1.5-2.3.

Can be specifically: the gross area S0 of the first material mouth 12 of mill 100 is 700-6400 square millimeter, the gross area S1 of the second material mouth 13 is 700-6400 square millimeter, difference in height h between first material mouth 12 and the second material mouth 13 is 5-60 millimeter, the maximum radial dimension d of the first material mouth 12 is 30-60 millimeter, and the maximum inner diameter dimension D of vessel 10 is 32-70 millimeter.The volume V0 of grinding chamber 11 is 24-165 milliliter, the rotational speed omega 1 of vessel 10 is 10-1000 rev/min, the projection 107 of the lower end of vessel 10 or the height dimension h1 of blade are 1-10 millimeter, the number n1 of projection 107 or blade is between 2-12, the heating power P of food processor 400 is 100-1000 watt, crushed piece 30 can be crushing knife, the rotational speed omega 2 of crushing knife is 1000-12000 rev/min, the blade number n2 of crushing knife is between 2-5, the diameter d 2 of crushing knife is 30-70 millimeter, the specified slurrying capacity V1 of food processor 400 is 600-1700 milliliter, between crushing knife and the first material mouth 12, the distance h2 at interval is 2-40 millimeter in the vertical direction.

Further, the utility model additionally provides the specific embodiment of a soy bean milk making machine, as follows:

In specific embodiment of the utility model, the ratio of the gross area S0 of the first material mouth 12 of mill 100 and the gross area S1 of the second material mouth 13 is 0.67-2, the ratio of the volume V0 of grinding chamber 11 and the gross area S0 of the first material mouth 12 is 0.031-0.078, the ratio of the gross area S0 of the first material mouth 12 and the rotational speed omega 1 of vessel 10 is 6-60, the ratio of the gross area S0 of the first material mouth 12 and the difference in height h between the first material mouth 12 and the second material mouth 13 is 40-180, the ratio of the volume V0 of grinding chamber 11 and the gross area S1 of the second material mouth 13 is 0.031-0.078, the ratio of the gross area S1 of the second material mouth 13 and the rotational speed omega 1 of vessel 10 is 6.00-60, the ratio of the gross area S1 of the second material mouth 13 and the difference in height h between the first material mouth 12 and the second material mouth 13 is 40-180.

Ratio between the volume V0 of grinding chamber 11 and the rotational speed omega 1 of vessel 10 is 0.280-3.133, the ratio of the rotational speed omega 1 of vessel 10 and the maximum radial dimension d of the first material mouth 12 is 0.67-6, the ratio of the rotational speed omega 1 of vessel 10 and the difference in height h between the first material mouth 12 and the second material mouth 13 is 1-20, the ratio of the rotational speed omega 1 of vessel 10 and the height dimension h1 of projection 107 or blade is 5-100, the ratio of the rotational speed omega 1 of vessel 10 and the number n1 of projection 107 or blade is 5-100, the ratio of the maximum inner diameter dimension D of vessel 10 and the maximum radial dimension d of the first material mouth 12 is 1.2-2.

The ratio of the height dimension h1 of heating power P and protruding 107 or blade is 33.3-400, the ratio 33.333-400 of the number n1 of heating power P and protruding 107 or blade, the rotational speed omega 1 of vessel 10 is 5-267 with the ratio of the rotational speed omega 1 of vessel 10, the rotational speed omega 1 of vessel 10 is 7.5-100 with the ratio of the blade number n2 of crushing knife, the rotational speed omega 1 of vessel 10 is 0.6-5.7 with the ratio of the diameter d 2 of crushing knife, the ratio of the specified slurrying capacity V1 of food processor 400 and the volume V0 of grinding chamber 11 is 8.5-27, the diameter d 2 of crushing knife and between crushing knife and the first material mouth 12 in the vertical direction the ratio of the distance h2 at interval be 1.75-25, the ratio of the maximum inner diameter dimension D of vessel 10 and the diameter d 2 of crushing knife is 1.5-2.

Can be specifically: the gross area S0 of the first material mouth 12 of mill 100 is 1200-1800 square millimeter, the gross area S1 of the second material mouth 13 is 1200-1800 square millimeter, difference in height h between first material mouth 12 and the second material mouth 13 is 10-30 millimeter, the maximum radial dimension d of the first material mouth 12 is 35-45 millimeter, and the maximum inner diameter dimension D of vessel 10 is 40-60 millimeter.The volume V0 of grinding chamber 11 is 56-94 milliliter, the rotational speed omega 1 of vessel 10 is 30-200 rev/min, the projection 107 of the lower end of vessel 10 or the height dimension h1 of blade are 2-6 millimeter, the number n1 of projection 107 or blade is between 2-6, the heating power P of food processor 400 is 200-800 watt, crushed piece 30 can be crushing knife, the rotational speed omega 2 of crushing knife is 1000-8000 rev/min, the blade number n2 of crushing knife is between 2-5, the diameter d 2 of crushing knife is 30-50 millimeter, the specified slurrying capacity V1 of food processor 400 is 800-1500 milliliter, between crushing knife and the first material mouth 12, the distance h2 at interval is 2-20 millimeter in the vertical direction.

Adopt the food processor 400 that the data of this embodiment are made, compared with the soy bean milk making machine in correlation technique, not only crushing effect is better, and anti-paste better effects if.Specific experiment data are as follows:

Single parameter value scope is as follows:

Multiple aspect ratio relation extents is as follows:

Crushing effect experimental result determinating reference is as follows:

Prevent being charred effect experimental result determinating reference as follows:

Single parameter experiment form is as follows:

Multiple parameters relationship test card is as follows:

Can be found out by above-mentioned test data, by arranging mill 100 on food processor 400, effectively can improve the crushing effect of food processor 400, and by arranging protruding 107 or blade construction on vessel 10, can effectively prevent food processor 400 from occurring being charred phenomenon in pulping process.

Thus, according to the food processor 400 of the utility model embodiment, because the crushed piece 30 of High Rotation Speed drives food materials to rotate in ladle body, under the drive of food materials, mill 100 absorb food materials part kinetic energy and with food materials rotating Vortex, due to mill 100 rotating Vortex under the drive of food materials, mill 100 diminishes with the speed discrepancy of food materials, the mill 100 simultaneously rotated also can stir food materials stably, food materials being more evenly distributed in ladle body 60 thus, the rotation of food materials is also more steady, the flow-disturbing effect of mill 100 is then more remarkable, also reduce the noise that food materials and mill 100 produce because speed discrepancy is comparatively large simultaneously, achieve the object to food processor noise reduction better.

In sum, according to the food processor 400 of the utility model embodiment, motor 50 is provided with in head body 40, motor 50 can drive coupled rotating shaft 20 to rotate, owing to there is grinding chamber 11 in vessel 10, rotating shaft 20 first end 21 stretches in grinding chamber 11 and first end 11 is provided with the crushed piece 30 being positioned at grinding chamber 11, during use, motor 50 drives rotating shaft 20 to drive crushed piece 30 to rotate, negative pressure can be formed in grinding chamber 11, food materials can from the throat-fed the first material mouth 12 and the second material mouth 13, after food materials are pulverized in grinding chamber 11, from discharge hole for discharge, process of lapping completes in grinding chamber 11, operating noise is little, pulping efficiency and effects on slurry making good, slurrying concentration is high, energy consumption is low.

According to the food processor 400 of the utility model embodiment other form and operation be all known for those of ordinary skills, be not described in detail here.

In description of the present utility model, it will be appreciated that, term " " center ", " longitudinal direction ", " transverse direction ", " length ", " width ", " thickness ", " on ", D score, " front ", " afterwards ", " left side ", " right side ", " vertically ", " level ", " top ", " end ", " interior ", " outward ", " clockwise ", orientation or the position relationship of the instruction such as " counterclockwise " are based on orientation shown in the drawings or position relationship, only the utility model and simplified characterization for convenience of description, instead of indicate or imply that the device of indication or element must have specific orientation, with specific azimuth configuration and operation, therefore can not be interpreted as restriction of the present utility model.

In addition, term " first ", " second " only for describing object, and can not be interpreted as instruction or hint relative importance or imply the quantity indicating indicated technical characteristic.Thus, be limited with " first ", the feature of " second " can express or impliedly comprise one or more these features.In description of the present utility model, the implication of " multiple " is two or more, unless otherwise expressly limited specifically.

In the utility model, unless otherwise clearly defined and limited, the term such as term " installation ", " being connected ", " connection ", " fixing " should be interpreted broadly, and such as, can be fixedly connected with, also can be removably connect, or connect integratedly; Can be mechanical connection, also can be electrical connection; Can be directly be connected, also indirectly can be connected by intermediary, can be the connection of two element internals.For the ordinary skill in the art, the concrete meaning of above-mentioned term in the utility model can be understood as the case may be.

In the utility model, unless otherwise clearly defined and limited, fisrt feature second feature it " on " or D score can comprise the first and second features and directly contact, also can comprise the first and second features and not be directly contact but by the other characterisation contact between them.And, fisrt feature second feature " on ", " top " and " above " comprise fisrt feature directly over second feature and oblique upper, or only represent that fisrt feature level height is higher than second feature.Fisrt feature second feature " under ", " below " and " below " comprise fisrt feature directly over second feature and oblique upper, or only represent that fisrt feature level height is less than second feature.

In the description of this description, specific features, structure, material or feature that the description of reference term " embodiment ", " some embodiments ", " example ", " concrete example " or " some examples " etc. means to describe in conjunction with this embodiment or example are contained at least one embodiment of the present utility model or example.In this manual, identical embodiment or example are not necessarily referred to the schematic representation of above-mentioned term.And the specific features of description, structure, material or feature can combine in an appropriate manner in any one or more embodiment or example.

Although illustrate and described embodiment of the present utility model above, be understandable that, above-described embodiment is exemplary, can not be interpreted as restriction of the present utility model, those of ordinary skill in the art can change above-described embodiment when not departing from principle of the present utility model and aim, revising, replacing and modification in scope of the present utility model.

Claims

1. the mill for food processor, it is characterized in that, comprise: vessel, in described vessel, there is grinding chamber, described vessel has roof, diapire and side perisporium, described grinding chamber has the first material mouth and the second material mouth, described first material interruption-forming is on described diapire, described second material interruption-forming extends to described roof on the perisporium of described side or from described side perisporium, one in described first material mouth and the second material mouth is charging aperture, another in described first material mouth and described second material mouth is discharging opening, the full-size d of described first material mouth in the radial direction of described vessel is 10-150 millimeter.

2. the mill for food processor according to claim 1, is characterized in that, the full-size d of described first material mouth in the radial direction of described vessel is 30-60 millimeter.

3. the mill for food processor according to claim 2, is characterized in that, the full-size d of described first material mouth in the radial direction of described vessel is 35-45 millimeter.

4. the mill for food processor according to claim 1, is characterized in that, the gross area S0 of described charging aperture is 700-6400 square millimeter, and the gross area S1 of described discharging opening is 700-6400 square millimeter.

5. the mill for food processor according to claim 1, it is characterized in that, described vessel is revolving body, described first material mouth is for being formed in a circular open at the center of described diapire, described second material mouth is that multiple and along described vessel circumferential interval is arranged, described second material mouth is for being formed in the circular open on the perisporium of described side or the elongated hole for extending to described roof from described side perisporium.

6. the mill for food processor according to claim 1, is characterized in that, the minimum point of described second material mouth is 5-60 millimeter to the distance h of the inner surface of described diapire.

7. the mill for food processor according to claim 1, is characterized in that, the volume V0 of described grinding chamber is 24-165 milliliter.

8. the mill for food processor according to claim 1, is characterized in that, the full-size D of described grinding chamber in the radial direction of described vessel is 12-200 millimeter.

9. the mill for food processor according to claim 1, is characterized in that, the center of described roof is provided with axis hole.

10. the mill for food processor according to any one of claim 1-9, it is characterized in that, the outer surface of described diapire is provided with projection or blade, and described projection or the blade height h1 on the axial direction of described vessel is 0.5-20 millimeter and the quantity n1 of described projection or blade is 1-24.