CN214341920U - Food processor's hank cuts subassembly mounting structure - Google Patents

Abstract

The utility model relates to a food processor's strand cutting subassembly mounting structure, including the base of strand cutting subassembly and installation strand cutting subassembly, be equipped with the installation position on the base, be provided with drive structure in the base, and to it has the output shaft of this drive structure to extend in the installation position, be equipped with on the strand cutting subassembly with this output shaft complex transmission hole, installation position and strand cutting subassembly are formed with around its output shaft and transmission hole and rotate spacing and peg graft spacingly, and install strand cutting subassembly detachably on the base through this rotation spacing and the spacing cooperation of pegging graft. The present application is directed to a novel installation structure of a chopping assembly of a food processor, so that the chopping assembly is detachable and replaceable.

Description

Food processor's hank cuts subassembly mounting structure

Technical Field

The utility model relates to a food processing equipment field, especially a food processor's strand cutting subassembly mounting structure.

Background

The food processor is a common kitchen tool, can improve the vegetable cutting efficiency, has various structures, and comprises a food processor adopting a roller cutter, wherein the roller processor generally adopts hand cranking as power, the roller processor adopts a hand cranking structure as the power, and a handle of the hand cranking structure is generally taken as a detachable handle, so that the roller cutter is convenient to replace, and the food materials with different shapes are cut; the vegetable cutting structure of the food processor with the structure is generally not replaceable, and can not be replaced by other cutting components, such as a meat grinding component, so that the food processor with the meat grinding function is formed.

Disclosure of Invention

An object of the utility model is to solve the above technical problem, provide a novel food processor's hank and cut subassembly mounting structure, make the hank cuts the subassembly and for dismantling removable ground.

In order to achieve the above purpose, the technical scheme of the utility model has:

the utility model provides a food processor's strand cut subassembly mounting structure, includes the base of strand cut subassembly and installation strand cut subassembly, be equipped with the installation position on the base, be provided with drive structure in the base, and to it has this drive structure's output shaft to extend in the installation position, be equipped with on the strand cut subassembly with this output shaft complex transmission hole, installation position and strand cut subassembly are formed with around its output shaft and transmission hole and rotate spacing and peg graft spacing, and through this rotate spacing and peg graft spacing cooperation with strand cut subassembly detachably install on the base.

According to the food processor twisting component mounting structure, the twisting component is detachably arranged, so that different twisting components can be replaced or all cutters of different twisting components can be replaced by the food processor; food processor traditional relatively, can handle the edible material of more various types to the material of eating of different shapes is cut out in the hank, and is concrete, has set up the base of installation hank and has cut the subassembly, has set up the output shaft on the installation position of base, through the transmission hole cooperation transmission in output shaft and the hank subassembly, makes the hank cut the subassembly and can handle and eat the material, and it is spacing to be formed with to rotate and peg graft around transmission structure, makes the hank cut subassembly detachably to install on the base through two limit structure cooperations.

Further, the mincing component is a vegetable chopping component or a meat mincing component. The subassembly of cutting the dish is for being used for the subassembly that shreds food section, and the minced steak subassembly is for stirring the subassembly of meat food, because the structure of the subassembly of cutting the dish and minced steak subassembly is different, can not general each other, and the base structure through this application can be convenient will cut the dish subassembly and minced steak subassembly install on the base, form the function of cutting the dish and minced steak.

And the rotation limit comprises a sliding block arranged on the twisting and cutting assembly and a sliding groove arranged on the installation position, the twisting and cutting assembly is rotated to enable the sliding block to slide into the sliding groove, the sliding groove is at least provided with an axial limit baffle plate along the axial direction of the output shaft, and the axial limit of the pair twisting and cutting assembly is formed by matching the axial limit baffle plate and the sliding block. This scheme provides a rotate spacing embodiment, and it is spacing to form the axial when strand cutting subassembly installation through above-mentioned structure.

Preferably, a circumferential limit baffle is further arranged in the sliding groove. The rotation angle of the twisting component during rotation can be limited through the circumferential limiting baffle.

And the splicing limit comprises a splicing hole formed in the twisting component and a splicing column arranged on the mounting position, and the twisting component rotates to enable the splicing hole to be spliced with the splicing column relatively to form circumferential limit of the pair twisting component. This scheme provides the spacing embodiment of grafting, and it is spacing to form the circumference when strand cutting subassembly installation through above-mentioned structure.

Furthermore, the base is also provided with an installation frame and a spring for installing the insertion column, and the insertion column can elastically stretch relative to the base through the spring and the installation frame; the twisting component is arranged beside the plug hole and is provided with a first inclined plane matched with the plug column, and the plug column slides into the plug hole through the inclined plane. Through the cooperation of first inclined plane and the flexible grafting post, can be when rotating this hank of installation and cutting the subassembly, can form automatically circumference is spacing.

Still further, the mounting bracket still to the surface extension of base has the slip button, and this slip button is used for removing this hank cuts the subassembly circumferential spacing. The sliding key can conveniently draw the splicing column out of the splicing hole from the outer side of the base, and the circumferential limit of the stranding and cutting assembly is removed.

Still further, the output shaft is a polygonal shaft, and the transmission hole is a multi-variable hole matched with the output shaft in shape. The polygonal shaft and the polygonal hole can be conveniently inserted into and transmit power with an output shaft of a power source, and the output shaft and the transmission hole are preferably arranged to be regular hexagons.

Furthermore, the vegetable cutting assembly comprises a cutter assembly, a containing shell and a transmission buckle, wherein one end of the transmission buckle is a first buckle, two sides of the first buckle along the mounting and dismounting direction of the cutter assembly are respectively provided with a second inclined surface, the other end of the transmission buckle is a limiting sleeve ring, the containing shell is provided with a through hole, the limiting sleeve ring is sleeved on the through hole, and the middle part of the transmission buckle is provided with the transmission hole; the tool assembly comprises a tool assembly body and is characterized by further comprising a push block, wherein a mounting groove for mounting the push block is formed in the accommodating shell, the push block is mounted in the mounting groove and faces the tool assembly, the push block can move towards the tool assembly in the mounting groove, and the moving distance of the push block in the mounting groove is enough to push the tool assembly to be detached from the transmission buckle. The ejector pad is used for promoting the cutter unit, makes it can break away from the spacing of transmission knot to convenient taking out the cutter unit from accommodating the casing, can convenience of customers change the cutter unit of different shapes, with the edible material of cutting out different shapes.

Still further, the ejector pad includes the main block body and by second clip and the push rod that the main block body extends out, the main block body holding is in the mounting groove, the push rod runs through the bottom surface of mounting groove for promote the cutter subassembly, be equipped with the spacing groove on the bottom surface of mounting groove, the second clip passes spacing groove clip in the outer wall of mounting groove, through main block body and second clip restriction the displacement of ejector pad. The scheme provides a specific implementation mode of the push block.

Drawings

Fig. 1 is a perspective view of a food processor of the present invention;

FIG. 2 is a perspective view of the meat grinder assembly of the present invention;

FIG. 3 is a perspective view of the cutting assembly of the present invention;

FIG. 4 is an exploded view of the food processor of the present invention;

FIG. 5 is a cross-sectional view of the food processor of the present invention;

fig. 6 is a cross-sectional view of the cutting assembly of the present invention;

fig. 7 is a perspective view of the accommodating case of the present invention;

fig. 8 is a perspective view of the driving buckle of the present invention;

fig. 9 is a perspective view of the push block of the present invention.

Detailed Description

The installation structure of the twisting and cutting assembly of the food processor of the present invention will be described with reference to fig. 1 to 9.

As shown in fig. 1 to 9, a cutting assembly mounting structure of a food processor comprises a cutting assembly and a base 1 for mounting the cutting assembly, as shown in fig. 2 and 3, the cutting assembly is a cutting assembly 3 or a meat grinding assembly 2. The subassembly of cutting the dish 3 for being used for slicing food into shreds, minced steak subassembly 2 is for stirring the garrulous subassembly of meat food, because the structure of cutting the dish subassembly 3 and minced steak subassembly 2 is different, can not general each other, and the subassembly 3 and the minced steak subassembly 2 of will cutting the dish that can be convenient through the 1 structure of base of this application install on base 1, form the function of cutting the dish and minced steak. In order to make the subassembly 3 of cutting the dish and minced steak subassembly 2 homoenergetic install and use on same base 1, all set up the same rotation spacing and the spacing structure of grafting on subassembly 3 of cutting the dish and minced steak subassembly 2.

The base 1 is provided with a mounting position 11, a driving structure is arranged in the base 1, an output shaft 111 of the driving structure extends into the mounting position 11, a transmission hole 6 matched with the output shaft 111 is formed in the twisting component, the mounting position 11 and the twisting component are provided with a rotation limit and an insertion limit around the output shaft 111 and the transmission hole 6, and the twisting component is detachably mounted on the base 1 through the rotation limit and the insertion limit.

As shown in fig. 4, the rotation limiting device includes a sliding block 4 disposed on the twisting and cutting assembly and a sliding groove 15 disposed on the mounting position 11, the twisting and cutting assembly is rotated to slide the sliding block 4 into the sliding groove 15, the sliding groove 15 is at least formed with an axial limiting baffle 151 along the axial direction of the output shaft 111, and the axial limiting baffle 151 is matched with the sliding block 4 to form axial limiting of the pair twisting and cutting assembly. This scheme provides a rotate spacing embodiment, and it is spacing to form the axial when strand cutting subassembly installation through above-mentioned structure.

A circumferential limit baffle 152 is also arranged in the sliding groove 15. The rotation angle of the twisting component during rotation can be limited by the circumferential limiting baffle 152, and the rotation transition of the sliding block 4 is avoided.

As shown in fig. 4 and 5, the insertion limit comprises an insertion hole 5 formed in the twisting component and an insertion column 12 formed in the installation position 11, and the twisting component rotates to enable the insertion hole 5 to be inserted into the insertion column 12, so that circumferential limit of the pair twisting component is formed. This scheme provides the spacing embodiment of grafting, and it is spacing to form the circumference when strand cutting subassembly installation through above-mentioned structure.

And the circumferential limit baffle 152 can also be matched with the structures of the plug-in column 12 and the plug-in hole 5, so as to further limit the circumferential direction between the pair twist-cut assembly and the base 1.

The base 1 is also provided with a mounting frame 13 and a spring 14 for mounting the plug column 12, and the plug column 12 can elastically stretch relative to the base 1 through the spring 14 and the mounting frame 13; the reaming assembly is provided with a first inclined surface 51 matched with the plug-in post 12 beside the plug-in hole 5, and the plug-in post 12 slides into the plug-in hole 5 through the inclined surface. Through the cooperation of the first inclined plane 51 and the elastically telescopic insertion column 12, the circumferential limit can be automatically formed when the twisting and cutting assembly is rotatably installed.

The mounting frame 13 further extends to the outer surface of the base 1 to form a sliding key 131, and the sliding key 131 is used for releasing the circumferential limit of the reaming assembly. The sliding key 131 can conveniently draw the splicing column 12 out of the splicing hole 5 from the outer side of the base 1, and the circumferential limit of the reaming assembly is released.

As shown in fig. 2 to 4, the output shaft 111 is a polygonal shaft, and the transmission hole 6 is a multi-variable hole that is matched with the output shaft 111 in shape. Polygonal shafts and holes can be conveniently inserted into the output shaft 111 of the power source and transmit power, and the output shaft 111 and the transmission holes 6 are preferably arranged in a regular hexagon.

According to the food processor twisting component mounting structure, the twisting component is detachably arranged, so that different twisting components can be replaced or all cutters of different twisting components can be replaced by the food processor; relatively traditional food processor, can handle the edible material of more various types, and the edible material of different shapes of hank-out, and it is concrete, set up the base 1 of installation hank-out subassembly, set up output shaft 111 on base 1's installation position 11, through the transmission of the 6 cooperations of output shaft 111 and the transmission hole in the hank-out subassembly, make hank-out subassembly can handle edible material, and be formed with around transmission structure and rotate spacing and peg graft spacing, make hank-out subassembly detachably install on base 1 through the cooperation of two limit structure.

As shown in fig. 6 to 9, the vegetable cutting assembly 3 includes a cutter assembly 32, a receiving housing 31 and a transmission buckle 7, one end of the transmission buckle 7 is a first hook 71, two sides of the first hook 71 along the mounting and dismounting direction of the cutter assembly 32 are both provided with a second inclined surface 711, the other end of the transmission buckle 7 is a limiting collar 72, the receiving housing 31 is provided with a through hole 311, the limiting collar 72 is sleeved on the through hole 311, and the middle of the transmission buckle 7 is provided with the transmission hole 6; the tool assembly further comprises a pushing block 8, a mounting groove 312 for mounting the pushing block 8 is formed in the accommodating shell 31, the pushing block 8 is mounted in the mounting groove 312 so that the pushing block 8 faces the tool assembly 32, the pushing block 8 can move towards the tool assembly 32 in the mounting groove 312, and the moving distance of the pushing block 8 in the mounting groove 312 is enough to push the tool assembly 32 to be detached from the drive buckle 7. The pushing block 8 is used for pushing the cutter assembly 32 to enable the cutter assembly 32 to be separated from the limit of the transmission buckle 7, so that the cutter assembly 32 can be conveniently taken out of the accommodating shell 31, users can conveniently replace the cutter assemblies 32 with different shapes, and the food materials with different shapes can be cut out. An elastic groove 73 is further formed in the first clasp 71, and the elastic groove 73 is used for increasing the elasticity of the first clasp 71 and facilitating deformation of the first clasp 71.

The scheme provides a specific implementation manner of the push block 8, the push block 8 includes a main block 81, and a second clasp 82 and a push rod 83 which extend from the main block 81, the main block 81 is accommodated in an installation groove 312, a through hole 313 is provided on the bottom surface of the installation groove 312, the push rod 83 is provided to penetrate through the bottom surface of the installation groove 312 through the through hole 313, the push rod is used for pushing the cutter assembly 32, a limit groove 314 is provided on the bottom surface of the installation groove 312, the second clasp 82 penetrates through the outer wall of the mounting groove 312 where the limit groove 314 clasp is fastened, and the main block 81 and the second clasp 82 limit the moving distance of the push block 8.

Variations and modifications to the above-described embodiments may occur to those skilled in the art, in light of the above teachings and teachings. Therefore, the present invention is not limited to the specific embodiments disclosed and described above, and some modifications and changes to the present invention should fall within the protection scope of the claims of the present invention. Furthermore, although specific terms are employed herein, they are used in a generic and descriptive sense only and not for purposes of limitation.

Claims (10)

1. The utility model provides a food processor's strand cut subassembly mounting structure, includes the base of strand cut subassembly and installation strand cut subassembly, its characterized in that, be equipped with the installation position on the base, be provided with drive structure in the base, and to it has the output shaft of this drive structure to extend in the installation position, be equipped with on the strand cut subassembly with this output shaft complex transmission hole, installation position and strand cut subassembly are formed with around its output shaft and transmission hole and rotate spacing and peg graft spacing, and through this rotate spacing and peg graft spacing cooperation with strand cut subassembly detachably install on the base.

2. The food processor cutting assembly mounting structure of claim 1, wherein the cutting assembly is a cutting assembly or a mincing assembly.

3. The structure of claim 1 or 2, wherein the rotation limiting means comprises a sliding block disposed on the cutting assembly and a sliding groove disposed on the mounting position, the cutting assembly is rotated to slide the sliding block into the sliding groove, and the sliding groove is at least formed with an axial limiting baffle along the axial direction of the output shaft, and the axial limiting baffle cooperates with the sliding block to form axial limiting of the cutting assembly.

4. The assembly mounting structure of claim 3, wherein a circumferential limit stop is further provided in the chute.

5. The structure of claim 1 or 2, wherein the engaging means comprises an engaging hole formed on the engaging means and an engaging post formed on the mounting portion, and the engaging means is rotated to engage the engaging hole with the engaging post to form a circumferential engaging means for the pair of engaging means.

6. The wringing and cutting component mounting structure of claim 5, wherein the base further comprises a mounting bracket and a spring for mounting the peg, the peg being elastically extendable and retractable relative to the base by the spring and the mounting bracket; the twisting component is arranged beside the plug hole and is provided with a first inclined plane matched with the plug column, and the plug column slides into the plug hole through the inclined plane.

7. The assembly of claim 6, wherein the mounting bracket further includes a slide tab extending toward an outer surface of the base for releasing the circumferential limit of the assembly.

8. The assembly mounting structure of claim 2 wherein the output shaft is a polygonal shaft and the drive aperture is a polygonal aperture that is a positive fit with the output shaft.

9. The structure for mounting a chopping assembly of a food processor according to claim 2, wherein the chopping assembly comprises a cutter assembly, a containing shell and a transmission buckle, one end of the transmission buckle is a first buckle, two sides of the first buckle along the mounting and dismounting direction of the cutter assembly are both provided with second inclined surfaces, the other end of the transmission buckle is a limiting sleeve ring, the containing shell is provided with a through hole, the limiting sleeve ring is sleeved on the through hole, and the middle part of the transmission buckle is provided with the transmission hole; the tool assembly comprises a tool assembly body and is characterized by further comprising a push block, wherein a mounting groove for mounting the push block is formed in the accommodating shell, the push block is mounted in the mounting groove and faces the tool assembly, the push block can move towards the tool assembly in the mounting groove, and the moving distance of the push block in the mounting groove is enough to push the tool assembly to be detached from the transmission buckle.

10. The assembly mounting structure of claim 9, wherein the pushing block includes a main block and a second hook and a pushing rod extending from the main block, the main block is received in a mounting groove, the pushing rod penetrates through a bottom surface of the mounting groove for pushing the cutter assembly, a limiting groove is disposed on the bottom surface of the mounting groove, the second hook penetrates through an outer wall of the mounting groove, and a moving distance of the pushing block is limited by the main block and the second hook.

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