阅读说明：本技术 一种自动切片装置 (Automatic slicing device ) 是由 王佳乐 于 2021-08-27 设计创作，主要内容包括：本发明一种自动切片装置包括机体(101),其与底板(106)固定；放置台(104),其上下两侧配置有第一刀片(102)和第二刀片(103),并且其开设多个进刀口(107)；驱动部,其通过电机(201)驱动滑动机构(200)使第一刀片(102)和第二刀片(103)切割食品(105)。本发明通过电机(201)驱动切滑块机构(200使第一刀片(102)向下运动切割食品(105)和第二刀片(103)向上运动切割食品(105),通过两个刀片提高了切割的效率,代替了人工,节省人力成本。(The invention relates to an automatic slicing device, which comprises a machine body (101) fixed with a bottom plate (106); a placing table (104) which is provided with a first blade (102) and a second blade (103) at the upper and lower sides thereof and is provided with a plurality of knife inlets (107); and a drive unit which drives the slide mechanism (200) by means of a motor (201) so that the first blade (102) and the second blade (103) cut the food (105). According to the food cutting machine, the motor (201) drives the cutting slide block mechanism (200) to enable the first blade (102) to move downwards to cut food (105) and the second blade (103) to move upwards to cut the food (105), so that the cutting efficiency is improved through the two blades, the manual work is replaced, and the labor cost is saved.)

1. An automatic slicing device which is characterized in that: comprises that

A body (101) fixed to the base plate (106);

a placing table (104) which is provided with a first blade (102) and a second blade (103) at the upper and lower sides thereof and is provided with a plurality of knife inlets (107);

and a drive unit which drives the slide mechanism (200) by means of a motor (201) so that the first blade (102) and the second blade (103) cut the food (105).

2. An automatic slicing apparatus as defined in claim 1, wherein: the sliding mechanism (200) comprises a motor (201), a motor output shaft (202), a first rotating shaft (203), a disc (204), a first supporting plate (205), a second supporting plate (207), a square hole (206), a first guide rail (208), a first connecting rod (209), a second connecting rod (210), a third connecting rod (211) and a third supporting plate (212);

the motor (201) is fixedly connected with the machine body (101), the motor output shaft (202) is in driving connection with the first rotating shaft (203), the first rotating shaft (203) is non-coaxially fixed with the disc (204), the disc (204) is installed on the first supporting plate (205) through a bearing and rotates along the first supporting plate, the first supporting plate (205) moves along the square hole (206), the square hole (206) is formed in the second supporting plate (207), the second supporting plate (207) moves along the first guide rail (208), the first guide rail (208) is fixedly connected with the machine body (101), the upper portion of the second supporting plate (207) is hinged with one end of the first connecting rod (209), the other end of the first connecting rod (209) is hinged with one end of the second connecting rod (210), and the middle portion of the second connecting rod (210) is hinged with the machine body (101), the other end of the second connecting rod (210) is hinged with one end of a third connecting rod (211), the other end of the third connecting rod (211) is hinged with a third supporting plate (212), the third supporting plate (212) is fixedly connected with a second blade (103), and the lower part of the second supporting plate (207) is fixedly connected with the first blade (102);

and the structural body consisting of the two groups of first guide rails (208), the first connecting rods (209), the second connecting rods (210), the third connecting rods (211) and the third supporting plate (212) is symmetrically arranged around the center of the second supporting plate (207).

3. An automatic slicing apparatus as defined in claim 1, wherein: the sliding mechanism (200) comprises a motor (201), a motor output shaft (202), a first rotating shaft (203), a disc (204), a first supporting plate (205), a second supporting plate (207), a square hole (206), a first guide rail (208), a first connecting rod (209), a second connecting rod (210), a third connecting rod (211), a third supporting plate (212), a top plate (213), a cutter feeding port (107), a cross rod (108) and a longitudinal guide rail (109);

the motor (201) is fixedly connected with the machine body (101), the motor output shaft (202) is in driving connection with the first rotating shaft (203), the first rotating shaft (203) is non-coaxially fixed with the disc (204), the disc (204) is installed on the first supporting plate (205) through a bearing and rotates along the first supporting plate, the first supporting plate (205) moves along the square hole (206), the square hole (206) is arranged on the second supporting plate (207), the second supporting plate (207) moves along the first guide rail (208), the first guide rail (208) is fixedly connected with the machine body (101), the upper portion of the second supporting plate (207) is hinged with one end of the first connecting rod (209), the other end of the first connecting rod (209) is hinged with one end of the second connecting rod (210), and the middle portion of the second connecting rod (210) is hinged with the machine body (101), the other end of the second connecting rod (210) is hinged with one end of a third connecting rod (211), the other end of the third connecting rod (211) is hinged with a third supporting plate (212), the third supporting plate (212) is fixedly connected with a top plate (213), the top plate (213) can be attached to a second blade (103), the second blades (103) are arranged in and move along the knife inlet (107), the knife inlet (107) is uniformly arranged on the placing table (104), the second blade (103) is fixedly connected with the cross rod (108), the cross rod (108) moves along a longitudinal guide rail (109), and the longitudinal guide rail (109) is fixedly connected with the placing plate (104);

and the structural body consisting of the two groups of first guide rails (208), the first connecting rods (209), the second connecting rods (210), the third connecting rods (211) and the third supporting plate (212) is symmetrically arranged around the center of the second supporting plate (207).

4. An automatic slicing apparatus as defined in claim 2 or 3, wherein: the automatic slicing device further comprises an intermittent mechanism (300), wherein the intermittent mechanism (300) comprises a crank (301), a fourth connecting rod (303), a first groove (304), a pin shaft (305), an intermittent rod (306), a first guide sleeve (307), a second rotating shaft (308), a first gear (309), a first rack (311) and a second guide rail (310).

The motor output shaft (201) is fixedly connected with one end of the crank (301), the other end of the crank (301) is hinged with one end of the fourth connecting rod (303), the other end of the fourth connecting rod (303) moves along the first guide sleeve (307), the end surface of the fourth connecting rod (303) is provided with the first groove (304) along the length direction thereof, at least six uniformly distributed ends of the pin shaft (305) moving along the first groove (304) are configured in the first groove, the other end of the pin shaft (305) is fixedly connected with at least six uniformly distributed intermittent rods (306), at least six intermittent rods (306) are distributed along the circumferential direction of the second rotating shaft (308) and fixed with the second rotating shaft, the second rotating shaft (308) is in bearing connection with the first guide sleeve (307), one end of the second rotating shaft (308) is mounted on the machine body (101) through a bearing, the other end of the second rotating shaft (308) is coaxially fixed with the first gear (309), the first gear (309) is meshed with the first rack (311), the first rack (311) is fixedly connected with the inner surface of the placing table (104), the placing table (105) moves along the second guide rail (310), and the second guide rail (310) is connected with the machine body (101).

5. An automatic slicing apparatus as defined in claim 4, wherein: the automatic slicing device further comprises a reciprocating mechanism (400), wherein the reciprocating mechanism (400) comprises a first fixing rod (401), a fifth connecting rod (402), a sixth connecting rod (403), a pin shaft (404), a long hole (405), a spring (420), a second fixing rod (405), a first blind hole (406), a fourth guide rail (408), a second gear (409), a third rotating shaft (410), a second rack (411), a first belt pulley (412), a first belt (413) and a second belt pulley (414);

the placing table (104) is fixedly connected with one end of the first fixing rod (401), the other end of the first fixing rod (401) can be overlapped with one end of the fifth connecting rod (402), the middle part of the fifth connecting rod (402) is hinged with the machine body (101), the other end of the fifth connecting rod (402) is fixedly connected with one end of the pin shaft (404), the other end of the pin shaft (404) is arranged in the long hole (405) and moves along the long hole, the long hole (405) is arranged on the sixth connecting rod (403), one end of the sixth connecting rod (403) is fixedly connected with one end of the spring (420), the other end of the spring (420) is fixedly connected with the machine body (101), the other end of the sixth connecting rod (403) is fixedly connected with the second fixing rod (405), and the other end of the second fixing rod (405) is sleeved in the first blind hole (406) and moves along the first blind hole, the first through hole (406) is formed in the end face of the second guide rail (310), the second guide rail (310) moves along the fourth guide rail (408), and the fourth guide rail (408) is fixedly connected with the machine body (101);

the inner surface of the placing table (104) opposite to the first rack (311) is fixed with the second rack (411) in fixed connection, the second rack (411) can be meshed with the second gear (409) to be connected, the second gear (409) is coaxially fixed with the third rotating shaft (410), the third rotating shaft (410) is mounted on the machine body (101) through a bearing, the third rotating shaft (410) is coaxially fixed with the first belt pulley (412), the first belt pulley (412) is in belt transmission connection with the second belt pulley (414) through a first belt (415), and the second belt pulley (414) is coaxially fixed with the motor output shaft (201).

And the structure body consisting of two groups of the first fixing rods (401), the fifth connecting rods (402), the sixth connecting rods (403), the springs (420), the second fixing rods (404), the first through holes (406), the third fixing rods (405) and the third guide rails (407) is symmetrically arranged relative to the placing table (104).

6. An automatic slicing apparatus as defined in claim 5, wherein: the motor output shaft (202) is in driving connection with the first rotating shaft (203) through a gear mechanism (500), and the gear mechanism (500) comprises a first helical gear (501), a second helical gear (520), a fifth rotating shaft (502), a third helical gear (503), a fourth helical gear (504), a fifth fixing rod (505), a sixth fixing rod (506), a fifth helical gear (508), a sixth rotating shaft (509), a third belt pulley (510), a second belt (511) and a fourth belt pulley (512);

the motor output shaft (202) is coaxially fixed with the first bevel gear (501), the first bevel gear (501) is engaged with the second bevel gear (520), the second bevel gear (520) is coaxially fixed with the fifth rotating shaft (502), the fifth rotating shaft (502) is mounted on the machine body (101) through a bearing, the fifth rotating shaft (502) is coaxially fixed with the third bevel gear (503), the third bevel gear (503) can be engaged with the fourth bevel gear (504), the fourth bevel gear (504) is mounted on a fifth fixing rod (505) through a bearing, the fifth fixing rod (505) is fixedly connected with the sixth fixing rod (506), the sixth fixing rod (506) is fixedly connected with the second guide rail (310), and the fourth bevel gear (504) and the fifth bevel gear (508) can be engaged with each other, the fifth bevel gear (508) and the sixth rotating shaft (509) are coaxially fixed, the sixth rotating shaft (509) is mounted on the machine body (101) through a bearing, the sixth rotating shaft (509) and the third belt pulley (510) are coaxially fixed, the third belt pulley (510) and the fourth belt pulley (512) are in belt transmission connection through a second belt (511), and the fourth belt pulley (512) and the first rotating shaft (203) are coaxially fixed.

7. An automatic slicing apparatus as defined in claim 6, wherein: the automatic slicing device further comprises a control mechanism, wherein the control mechanism comprises a second motor (424), a second motor output shaft (425), a second crank (426), an eighth connecting rod (427), a third guide sleeve (428), a second stop lever (429) and a third clamping pin (430);

the second motor (424) is fixedly connected with the machine body (101), the output shaft (425) of the second motor is fixedly connected with one end of the second crank (426), the other end of the second crank (426) is hinged with one end of the eighth connecting rod (427), the other end of the eighth connecting rod (427) is hinged with the second stop lever (429), the second stop lever (429) moves along the third guide sleeve (428), the third guide sleeve (428) is fixed with the machine body (101), the second stop lever (429) can be overlapped with the third clamping pin (430), and the third clamping pins (430) are uniformly distributed along the circumferential direction of the first gear (309).

According to the invention, the second crank 426 is driven by the second motor (424) to rotate, so that the second stop rod 429 moves left and right, when the intermittent rod 306 drives the first gear 309 to rotate, the second stop plate 429 moves right and is not overlapped with the third clamping pin, and when the intermittent rod 306 does not drive the first gear 309 to rotate, the second stop plate 429 moves left and is overlapped with the third clamping pin 430, so that the first gear 309 is prevented from being reversed, and the rotation of the intermittent rod 306 is ensured.

8. An automatic slicing apparatus as defined in claim 7, wherein: the side surface of the second supporting plate (207) is provided with a dovetail block, and the first guide rail (208) is provided with a dovetail groove.

Technical Field

The invention relates to the field of food processing, in particular to a device for automatically slicing.

Background

In the food processing field, there are a lot of products to cut into slices and handle, and convenient follow-up bagging-off or vanning are with transportation and selling, if with artifical cutting, waste time and energy, can not mass production, need urgently now one kind can replace the manpower and improve the automatic slicing device of cutting efficiency.

Disclosure of Invention

The invention aims to provide an automatic slicing device which can replace manpower and improve cutting efficiency.

The invention relates to an automatic slicing device, which comprises a machine body, a slicing mechanism and a slicing mechanism, wherein the machine body is fixed with a bottom plate;

the placing table is provided with a first blade and a second blade on the upper side and the lower side, and is provided with a plurality of knife inlets;

and a driving part which drives the sliding mechanism through the motor to enable the first blade and the second blade to cut the food.

The invention relates to an automatic slicing device, wherein a sliding mechanism motor, a motor output shaft, a first rotating shaft, a disc, a first supporting plate, a second supporting plate, a square hole, a first guide rail, a first connecting rod, a second connecting rod, a third connecting rod and a third supporting plate are arranged on a rack;

the motor is fixedly connected with the machine body, the output shaft of the motor is in driving connection with the first rotating shaft, the first rotating shaft is non-coaxially fixed with the disc, the disc is installed on the first supporting plate through a bearing and rotates along the first supporting plate, the first supporting plate moves along the square hole, the square hole is formed in the second supporting plate, the second supporting plate moves along the first guide rail, the first guide rail is fixedly connected with the machine body, the upper portion of the second supporting plate is hinged with one end of the first connecting rod, the other end of the first connecting rod is hinged with one end of the second connecting rod, the middle portion of the second connecting rod is hinged with the machine body, the other end of the second connecting rod is hinged with one end of the third connecting rod, the other end of the third connecting rod is hinged with the third supporting plate, and the third supporting plate is fixedly connected with the second blade, the lower part of the second supporting plate is fixedly connected with the first blade;

and the structural body consisting of the two groups of the first guide rails, the first connecting rods, the second connecting rods, the third connecting rods and the third supporting plate is arranged symmetrically relative to the center of the second supporting plate.

The invention relates to an automatic slicing device, wherein a sliding mechanism motor, a motor output shaft, a first rotating shaft, a disc, a first supporting plate, a second supporting plate, a square hole, a first guide rail, a first connecting rod, a second connecting rod, a third supporting plate, a top plate, a knife inlet, a cross rod and a longitudinal guide rail are arranged on the sliding mechanism motor;

the motor is fixedly connected with the machine body, the output shaft of the motor is in driving connection with the first rotating shaft, the first rotating shaft is non-coaxially fixed with the disc, the disc is installed on the first supporting plate through a bearing and rotates along the first supporting plate, the first supporting plate moves along the square hole, the square hole is formed in the second supporting plate, the second supporting plate moves along the first guide rail, the first guide rail is fixedly connected with the machine body, the upper part of the second supporting plate is hinged with one end of the first connecting rod, the other end of the first connecting rod is hinged with one end of the second connecting rod, the middle part of the second connecting rod is hinged with the machine body, the other end of the second connecting rod is hinged with one end of the third connecting rod, the other end of the third connecting rod is hinged with the third supporting plate, and the third supporting plate is fixedly connected with the top plate, the top plate can be attached to a second blade, the second blades are arranged in the cutter inlets and move along the cutter inlets, the cutter inlets are uniformly formed in the placing table, the second blade is fixedly connected with the transverse rod, the transverse rod moves along a longitudinal guide rail, and the longitudinal guide rail is fixedly connected with the placing plate;

and the structural body consisting of the two groups of the first guide rails, the first connecting rods, the second connecting rods, the third connecting rods and the third supporting plate is arranged symmetrically relative to the center of the second supporting plate.

The invention relates to an automatic slicing device, which further comprises an intermittent mechanism, wherein the intermittent mechanism comprises a crank, a fourth connecting rod, a first groove, a pin shaft, an intermittent rod, a first guide sleeve, a second rotating shaft, a first gear, a first rack and a second guide rail;

the motor output shaft is fixedly connected with one end of the crank, the other end of the crank is hinged with one end of the fourth connecting rod, the other end of the fourth connecting rod moves along the first guide sleeve, the end face of the fourth connecting rod is provided with the first groove along the length direction of the fourth connecting rod, one end of the pin shaft which moves along the first groove is arranged in the first groove and is uniformly distributed at least six, the other end of the pin shaft is fixedly connected with the intermittent rods which are uniformly distributed at least six, the intermittent rods are distributed along the circumferential direction of the second rotating shaft and are fixed with the second rotating shaft, the second rotating shaft is connected with the first guide sleeve bearing, one end of the second rotating shaft is arranged on the machine body through a bearing, the other end of the second rotating shaft is coaxially fixed with the first gear, the first gear is meshed with the first rack, and the first rack is fixedly connected with the inner surface of the placing table, the placing table moves along the second guide rail, and the second guide rail is connected with the machine body.

The invention relates to an automatic slicing device, which further comprises a reciprocating mechanism, wherein the reciprocating mechanism comprises a first fixed rod, a fifth connecting rod, a sixth connecting rod, a pin shaft, a long hole, a spring second fixed rod, a first blind hole, a fourth guide rail, a second gear, a third rotating shaft, a second rack, a first belt pulley, a first belt and a second belt pulley;

the placing table is fixedly connected with one end of the first fixing rod, the other end of the first fixing rod can be lapped with one end of the fifth connecting rod, the middle part of the fifth connecting rod is hinged with the machine body, the other end of the fifth connecting rod is fixedly connected with one end of the pin shaft, the other end of the pin shaft is arranged in the long strip hole and moves along the long strip hole, the long strip hole is arranged on the sixth connecting rod, one end of the sixth connecting rod is fixedly connected with one end of the spring, the other end of the spring is fixedly connected with the machine body, the other end of the sixth connecting rod is fixedly connected with the second fixed rod, the other end of the second fixed rod is sleeved in the first blind hole and moves along the first blind hole, the first through hole is formed in the end face of the second guide rail, the second guide rail moves along the fourth guide rail, and the fourth guide rail is fixedly connected with the machine body;

the placing table is fixedly connected with the inner surface, opposite to the first rack, of the first rack, the second rack can be connected with the second gear in a meshed mode, the second gear is coaxially fixed with the third rotating shaft, the third rotating shaft is installed on the machine body through a bearing, the third rotating shaft is coaxially fixed with the first belt pulley, the first belt pulley is in transmission connection with the second belt pulley through the first belt, and the second belt pulley is coaxially fixed with the motor output shaft.

And the structure body consisting of the two groups of the first fixing rods, the fifth connecting rods, the sixth connecting rods, the spring second fixing rods, the first through holes, the third fixing rods and the third guide rails is symmetrically arranged relative to the placing table.

The invention relates to an automatic slicing device, wherein an output shaft of a motor is in driving connection with a first rotating shaft through a gear mechanism, and the gear mechanism comprises a first helical gear, a second helical gear, a fifth rotating shaft, a third helical gear, a fourth helical gear, a fifth fixing rod, a sixth fixing rod, a fifth helical gear, a sixth rotating shaft, a third belt pulley, a second belt and a fourth belt pulley;

the motor output shaft is coaxially fixed with the first helical gear, the first helical gear is meshed with the second helical gear, the second helical gear is coaxially fixed with the fifth rotating shaft, the fifth rotating shaft is installed on the machine body through a bearing, the fifth rotating shaft is coaxially fixed with the third helical gear, the third helical gear can be meshed with the fourth helical gear, the fourth helical gear is installed on a fifth fixing rod through a bearing, the fifth fixing rod is fixedly connected with a sixth fixing rod, the sixth fixing rod is fixedly connected with a second guide rail, the fourth helical gear can be meshed with the fifth helical gear, the fifth helical gear is coaxially fixed with the sixth rotating shaft, the sixth rotating shaft is installed on the machine body through a bearing, and the sixth rotating shaft is coaxially fixed with the third belt pulley, the third belt pulley with the fourth belt pulley passes through second belt drive and is connected, the fourth belt pulley is coaxial fixed with first axis of rotation.

The invention relates to an automatic slicing device, which further comprises a control mechanism, wherein the control mechanism comprises a second motor, a second motor output shaft, a second crank, an eighth connecting rod, a third guide sleeve, a second stop lever and a third clamping pin;

the second motor is fixedly connected with the machine body, an output shaft of the second motor is fixedly connected with one end of the second crank, the other end of the second crank is hinged with one end of the eighth connecting rod, the other end of the eighth connecting rod is hinged with the second stop lever, the second stop lever moves along the third guide sleeve, the third guide sleeve is fixed with the machine body, the second stop lever can be in lap joint with the third stop pin, and the third stop pins are uniformly distributed along the circumferential direction of the first gear.

The invention relates to an automatic slicing device, wherein a dovetail block is arranged on the side surface of a second supporting plate, and a dovetail groove is formed in a first guide rail.

The automatic slicing device is different from the prior art in that the motor drives the sliding block cutting mechanism (200) to enable the first blade to move downwards to cut food and the second blade to move upwards to cut food, the cutting efficiency is improved through the two blades, manual work is replaced, and labor cost is saved.

An automatic slicing apparatus according to the present invention will be further described with reference to the accompanying drawings.

Drawings

FIG. 1 is a front view of an automatic slicing apparatus;

FIG. 2 is a top view of an automatic slicing apparatus shown in FIG. 1;

FIG. 3 is a cross-sectional view taken along line B-B of FIG. 2;

FIG. 4 is a side view of FIG. 1;

FIG. 5 is a cross-sectional view taken along A-A of FIG. 1;

FIG. 6 is an isometric view of FIG. 1;

FIG. 7 is an enlarged view of a portion of FIG. 2;

FIG. 8 is a partial enlarged view of FIG. 4;

FIG. 9 is an enlarged partial view of FIG. 5;

FIG. 10 is an enlarged view of a portion of FIG. 5;

fig. 11 is a modified enlarged view of fig. 2.

Detailed Description

Referring to fig. 1 to 11, and to fig. 1, 3 and 6, an automatic slicing apparatus includes a body 101 fixed to a base plate 106;

a placing table 104, on which a first blade 102 and a second blade 103 are arranged on the upper and lower sides and which is provided with a plurality of knife-entering edges 107;

a driving part which drives the sliding mechanism 200 through the motor 201 to make the first blade 102 and the second blade 103 cut the food 105.

According to the food cutting machine, the motor 201 drives the sliding block cutting mechanism 200 to enable the first blade 102 to move downwards to cut the food 105 and the second blade 103 to move upwards to cut the food 105, the cutting efficiency is improved through the two blades, manpower is replaced, and the labor cost is saved.

The placing table 104 is provided with a groove and then is in a shape of a Chinese character 'hui', a first blade 102 is arranged on the upper side of the placing table, and a second blade 103 is arranged on the lower side of the placing table.

Wherein the shape of the knife-in edge 107 and the first blade 102 and the second blade 103 cooperate to enable the first blade 102 and the second blade 103 to cut the food product 105.

The first blade 102 and the second blade 103 are arranged at intervals to ensure that the food 105 is cut twice by the lower knife once.

The power module of the motor 201 comprises a battery, an electric control module and a wireless communication module, and the wireless communication module is in wireless connection with the user terminal.

According to the invention, through the wireless communication module, a user can directly control the rotation direction and the rotation speed of the motor 201, so that the cutting frequency can be adjusted.

As a further explanation of this example, referring to fig. 3, the sliding mechanism 200 includes a motor 201, a motor output shaft 202, a first rotating shaft 203, a disk 204, a first support plate 205, a second support plate 207, a square hole 206, a first guide rail 208, a first link 209, a second link 210, a third link 211, a third support plate 212;

the motor 201 is fixedly connected with the machine body 101, the motor output shaft 202 is in driving connection with the first rotating shaft 203, the first rotating shaft 203 is non-coaxially fixed with the disc 204, the disc 204 is mounted on the first supporting plate 205 through a bearing and rotates along the first supporting plate 205, the first supporting plate 205 moves along the square hole 206, the square hole 206 is arranged on the second supporting plate 207, the second supporting plate 207 moves along the first guide rail 208, the first guide rail 208 is fixedly connected with the machine body 101, the upper part of the second supporting plate 207 is hinged with one end of the first connecting rod 209, the other end of the first connecting rod 209 is hinged with one end of the second connecting rod 210, the middle part of the second connecting rod 210 is hinged with the machine body 101, the other end of the second connecting rod 210 is hinged with one end of the third connecting rod 211, and the other end of the third connecting rod 211 is hinged with the third supporting plate 212, the third supporting plate 212 is fixedly connected with the second blade 103, and the lower part of the second supporting plate 207 is fixedly connected with the first blade 102;

a structural body composed of two sets of the first guide rail 208, the first link 209, the second link 210, the third link 211, and the third support plate 212 is symmetrically disposed about the center of the second support plate 207.

According to the invention, the disc 204 is driven to rotate by the motor 201, so that the second supporting plate 207 moves up and down, and on one hand, the first blade 102 is driven to cut the food 105; on the other hand, the first connecting rod 209 is driven to move, so that the second connecting rod 210 drives the third connecting rod 211 to move up and down, the second blade 103 is driven to move up and down, the food 105 is cut, and the cutting efficiency is improved through the matching of the first blade 102 and the second blade 103.

Because the first blade 102 and the second blade 103 are arranged at intervals in a staggered manner, the second blade 103 needs to penetrate through a feed opening 107 formed in the placing table 104, and the length of the second blade 103 in the vertical direction needs to be larger than the thickness of the food 105 than that of the first blade 102, so that the cutting is ensured to be completely penetrated; of course, the first blade 102 and the second blade 103 are provided at the end of the placing table 104, so that the cutting can be directly performed without being separated by a mistake, and thus, the placing table 104 is not provided with the cutting edge 107.

Wherein the horizontal length of the square hole 206 is more than 2 times the diameter of the circular disc 204.

The side surface of the second supporting plate 207 is provided with a dovetail block, the first guide rail 208 is provided with a dovetail groove, and the dovetail block and the first guide rail are matched to enable the second supporting plate 207 to move up and down without disengaging from the groove.

The first rotating shaft 203 is non-coaxially and fixedly connected with the disc 204, so that the second supporting plate 207 can move up and down.

The other end of the third link 211 passes through a groove formed in the first guide rail 208 and is hinged to the third support plate 212.

The first support plate 205 is provided with a dovetail-shaped sliding block, and the square hole 206 is provided with a dovetail groove, so that the first support plate 205 can move left and right without moving longitudinally.

The first support plate 205 is provided with a circular through hole, and the disc 204 is disposed in the circular through hole and rotates along the circular through hole.

As a further explanation of this example, referring to fig. 2 to 3 and fig. 11, the sliding mechanism 200 includes a motor 201, a motor output shaft 202, a first rotating shaft 203, a circular disc 204, a first support plate 205, a second support plate 207, a square hole 206, a first guide rail 208, a first link 209, a second link 210, a third link 211, a third support plate 212, a top plate 213, a knife feed opening 107, a cross bar 108, and a longitudinal guide rail 109;

the motor 201 is fixedly connected with the machine body 101, the motor output shaft 202 is in driving connection with the first rotating shaft 203, the first rotating shaft 203 is non-coaxially fixed with the disc 204, the disc 204 is mounted on the first supporting plate 205 through a bearing and rotates along the first supporting plate 205, the first supporting plate 205 moves along the square hole 206, the square hole 206 is arranged on the second supporting plate 207, the second supporting plate 207 moves along the first guide rail 208, the first guide rail 208 is fixedly connected with the machine body 101, the upper part of the second supporting plate 207 is hinged with one end of the first connecting rod 209, the other end of the first connecting rod 209 is hinged with one end of the second connecting rod 210, the middle part of the second connecting rod 210 is hinged with the machine body 101, the other end of the second connecting rod 210 is hinged with one end of the third connecting rod 211, and the other end of the third connecting rod 211 is hinged with the third supporting plate 212, the third support plate 212 is fixedly connected to a top plate 213, the top plate 213 is capable of being attached to a second blade 103, the plurality of second blades 103 are disposed in and move along the feed openings 107, the plurality of feed openings 107 are uniformly formed in the placement table 104, the second blade 103 is fixedly connected to the cross bar 108, the cross bar 108 moves along the longitudinal rail 109, and the longitudinal rail 109 is fixedly connected to the placement plate 104;

a structural body composed of two sets of the first guide rail 208, the first link 209, the second link 210, the third link 211, and the third support plate 212 is symmetrically disposed about the center of the second support plate 207.

According to the invention, the disc 204 is driven to rotate by the motor 201, so that the second supporting plate 207 moves up and down, and on one hand, the first blade 102 is driven to cut the food 105; on the other hand, the first link 209 is driven to move, so that the second link 210 drives the third link 211 to move up and down, so that the top plate 213 sequentially ejects the second blades 103 in the feed opening 107, the second blades 103 move up and down, and the food 105 is cut, and the cutting efficiency is improved by the cooperation of the first blades 102 and the second blades 103.

Wherein the cross bar 108 can move up and down along the longitudinal rail 109, and also can prevent the second blade 103 from falling and enhance the sealing property of the placing plate 104.

Wherein the horizontal length of the square hole 206 is more than 2 times the diameter of the circular disc 204.

The first rotating shaft 203 is non-coaxially and fixedly connected with the disc 204, so that the second supporting plate 207 can move up and down.

The other end of the third link 211 passes through a groove formed in the first guide rail 208 and is hinged to the third support plate 212.

The first support plate 205 is provided with a dovetail-shaped sliding block, and the square hole 206 is provided with a dovetail groove, so that the first support plate 205 can move left and right without moving longitudinally.

The first support plate 205 is provided with a circular through hole, and the disc 204 is disposed in the circular through hole and rotates along the circular through hole.

As a further explanation of this example, referring to fig. 5 and 9, the automatic slicing apparatus further includes an intermittent mechanism 300, the intermittent mechanism 300 includes a crank 301, a fourth link 303, a first groove 304, a pin 305, an intermittent lever 306, a first guide sleeve 307, a second rotating shaft 308, a first gear 309, a first rack 311, a second guide rail 310;

the motor output shaft 201 is fixedly connected with one end of the crank 301, the other end of the crank 301 is hinged with one end of the fourth connecting rod 303, the other end of the fourth connecting rod 303 moves along the first guide sleeve 307, the first groove 304 is formed in the end surface of the fourth connecting rod 303 along the length direction of the fourth connecting rod, one end of the pin shaft 305 which moves along the first groove 304 is arranged in the first groove, the other end of the pin shaft 305 is fixedly connected with at least six intermittent rods 306 which are uniformly distributed, at least six intermittent rods 306 are distributed along the circumferential direction of the second rotating shaft 308 and fixed with the second rotating shaft, the second rotating shaft 308 is in bearing connection with the first guide sleeve 307, one end of the second rotating shaft 308 is mounted on the machine body 101 through a bearing, the other end of the second rotating shaft 308 is coaxially fixed with the first gear 309, and the first gear 309 is engaged with the first rack 311, the first rack 311 is fixedly connected to the inner surface of the placing table 104, the placing table 105 moves along the second guide rail 310, and the second guide rail 310 is connected to the machine body 101.

According to the invention, the motor 201 drives the crank 301 to rotate, so that the fourth connecting rod 303 swings from back to front, the first groove 304 drives the pin shaft 305 to move, the intermittent wheel 306 rotates once, and when the first groove 304 drives the next pin shaft 305 to move, the intermittent wheel 306 rotates once again, so that the first gear 309 rotates intermittently, therefore, the food 105 on the placing table 104 is accurately cut, the cutting width is controlled, the error of manual cutting is reduced, and the product quality is ensured.

Wherein, the first groove 304 is preferably a U-shaped groove, so that the movement is smoother.

The second guide rail 310 is fixedly connected with the machine body 101.

The second guide rail 310 has a dovetail groove, and a dovetail slider is disposed at the bottom of the placement stage 105, so that the placement stage 105 moves forward without moving longitudinally.

As a further explanation of the present example, referring to fig. 1 and 5 and fig. 10, the automatic slicing apparatus further includes a reciprocating mechanism 400, the reciprocating mechanism 400 includes a first fixing rod 401, a fifth link 402, a sixth link 403, a pin 404, a long hole 405, a spring 420, a second fixing rod 405, a first blind hole 406, a fourth guide rail 408, a second gear 409, a third rotating shaft 410, a second gear 411, a first pulley 412, a first belt 413, a second pulley 414;

the placing table 104 is fixedly connected to one end of the first fixing rod 401, the other end of the first fixing rod 401 can be overlapped with one end of the fifth connecting rod 402, the middle portion of the fifth connecting rod 402 is hinged to the machine body 101, the other end of the fifth connecting rod 402 is fixedly connected to one end of the pin shaft 404, the other end of the pin shaft 404 is disposed in the elongated hole 405 and moves along the elongated hole 405, the elongated hole 405 is formed in the sixth connecting rod 403, one end of the sixth connecting rod 403 is fixedly connected to one end of the spring 420, the other end of the spring 420 is fixedly connected to the machine body 101, the other end of the sixth connecting rod 403 is fixedly connected to the second fixing rod 405, the other end of the second fixing rod 405 is sleeved in the first blind hole 406 and moves along the first blind hole 406, the first through hole 406 is formed in the end face of the second guide rail 310, and the second guide rail 310 moves along the fourth guide rail 408, the fourth guide rail 408 is fixedly connected with the machine body 101;

the second rack 411 is fixed on the inner surface of the placing table 104 opposite to the first rack 311, the second rack 411 can be engaged with the second gear 409, the second gear 409 is coaxially fixed with the third rotating shaft 410, the third rotating shaft 410 is mounted on the machine body 101 through a bearing, the third rotating shaft 410 is coaxially fixed with the first pulley 412, the first pulley 412 is in belt transmission connection with the second pulley 414 through a first belt 415, and the second pulley 414 is coaxially fixed with the motor output shaft 201.

The structural body composed of two sets of the first fixing rod 401, the fifth connecting rod 402, the sixth connecting rod 403, the spring 420, the second fixing rod 404, the first through hole 406, the third fixing rod 405 and the third guide rail 407 is symmetrically arranged around the placing table 104.

According to the invention, the placing table 104 moves forwards, the first fixed rod 401 is enabled to be propped against the fifth connecting rod 402, the fifth connecting rod 402 drives the sixth connecting rod 403 to move backwards, so that the second guide rail 310 moves rightwards, the placing table 104 moves rightwards, at the moment, the meshing of the first gear 309 and the first rack 311 is finished, so that the second gear 409 is meshed with the second rack 411, the placing table 104 moves backwards, the placing table 104 moves leftwards to reset through the movement of the symmetrical structure, the first gear 309 and the first rack 311 are meshed to move circularly, continuous cutting is realized, the speed in the resetting process is high, the resetting can be realized rapidly, and the efficiency is improved.

The first through hole 406 is obliquely arranged from back to front and from left to right.

The bottom of the second guide rail 310 is provided with a dovetail-shaped sliding block, the fourth guide rail 408 is provided with a dovetail groove, and the dovetail-shaped sliding block and the fourth guide rail are matched to enable the second guide rail 310 to move left and right without disengaging from the groove.

Wherein the elongated hole 405 is a longitudinal elongated hole.

As a further explanation of the present example, referring to fig. 2 to 4 and fig. 7 to 8, the motor output shaft 202 is drivingly connected to the first rotating shaft 203 through a gear mechanism 500, and the gear mechanism 500 includes a first helical gear 501, a second helical gear 520, a fifth rotating shaft 502, a third helical gear 503, a fourth helical gear 504, a fifth fixing rod 505, a sixth fixing rod 506, a fifth helical gear 508, a sixth rotating shaft 509, a third belt pulley 510, a second belt 511, and a fourth belt pulley 512;

the motor output shaft 202 is coaxially fixed to the first helical gear 501, the first helical gear 501 is engaged with the second helical gear 520, the second helical gear 520 is coaxially fixed to the fifth rotating shaft 502, the fifth rotating shaft 502 is mounted to the machine body 101 through a bearing, the fifth rotating shaft 502 is coaxially fixed to the third helical gear 503, the third helical gear 503 is engaged with the fourth helical gear 504, the fourth helical gear 504 is mounted to the fifth fixing rod 505 through a bearing, the fifth fixing rod 505 is fixedly connected to the sixth fixing rod 506, the sixth fixing rod 506 is fixedly connected to the second guide rail 310, the fourth helical gear 504 is engaged with the fifth helical gear 508, the fifth helical gear 508 is coaxially fixed to the sixth rotating shaft 509, and the sixth rotating shaft 509 is mounted to the machine body 101 through a bearing, the sixth rotating shaft 509 is coaxially fixed to the third belt pulley 510, the third belt pulley 510 is in belt transmission connection with the fourth belt pulley 512 through a second belt 511, and the fourth belt pulley 512 is coaxially fixed to the first rotating shaft 203.

In the invention, the motor 201 drives the first bevel gear 501 to rotate, so that the fifth rotating shaft 502 drives the third bevel gear 503 to rotate, when the placing table 104 moves forwards, the third bevel gear 503 can be meshed with the fourth bevel gear 504, so that the fourth bevel gear 504 drives the fifth bevel gear 508 to rotate, so that the fifth bevel gear 508 drives the sixth rotating shaft 509 to rotate, so that the sliding mechanism 200 moves through the transmission of the third belt pulley 510 and the fourth belt pulley 512, when the placing table 104 moves leftwards, the fifth fixing rod 505 is driven to move leftwards, so that the third bevel gear 503 cannot be meshed with the fourth bevel gear 504, so that the sliding mechanism 200 does not move, namely, after a food 105 is cut, the placing table 104 does not move in the resetting process, so that the cost is saved, when the placing table 104 moves rightwards, the fifth fixing rod 505 is driven to move rightwards, so that the third bevel gear 503 can be meshed with the fourth bevel gear 504, by moving the sliding mechanism 200 to continue the movement, the present invention improves the service life of the first blade 102 and the second blade 103 and saves costs.

As a further explanation of this example, referring to fig. 5 and 9, the automatic slicing apparatus further comprises a control mechanism comprising a second motor 424, a second motor output shaft 425, a second crank 426, an eighth link 427, a third guide sleeve 428, a second stop 429, a third catch 430;

the second motor 424 is fixedly connected with the machine body 101, the second motor output shaft 425 is fixedly connected with one end of the second crank 426, the other end of the second crank 426 is hinged with one end of the eighth connecting rod 427, the other end of the eighth connecting rod 427 is hinged with the second stopper 429, the second stopper 429 moves along the third guide sleeve 428, the third guide sleeve 428 is fixed with the machine body 101, the second stopper 429 can be overlapped with the third locking pin 430, and the plurality of third locking pins 430 are uniformly distributed along the circumferential direction of the first gear 309.

According to the invention, the second crank 426 is driven by the second motor 424 to rotate, so that the second stop rod 429 moves left and right, when the intermittent rod 306 drives the first gear 309 to rotate, the second stop plate 429 moves right and is not overlapped with the third clamping pin, and when the intermittent rod 306 does not drive the first gear 309 to rotate, the second stop plate 429 moves left and is overlapped with the third clamping pin 430, so that the first gear 309 is prevented from being reversed, and the rotation of the intermittent rod 306 is ensured.

As a further explanation of this example, referring to fig. 3, the second support plate 207 is provided with a dovetail block on a side surface thereof, and the first guide rail 208 is provided with a dovetail groove.

The present invention enables the second support plate 207 to move up and down without disengaging the groove.

The above-mentioned embodiments are merely illustrative of the preferred embodiments of the present invention, and do not limit the scope of the present invention, and various modifications and improvements of the technical solution of the present invention by those skilled in the art should fall within the protection scope defined by the claims of the present invention without departing from the spirit of the present invention.