CN114568980B - Dough processing mechanism for cake baking machine - Google Patents

Abstract

The invention provides a dough processing mechanism for a cake baking machine, which comprises: the device comprises a push rod sliding rail (4), a driving motor (5) fixedly arranged on the push rod sliding rail (4), a push rod (3) which is driven by the driving motor (5) and can slide back and forth on the push rod sliding rail (4), and a stop lever (2) connected with the push rod (3); the upper surface of the push rod sliding rail (4) is provided with a sliding column limiting groove (4 b) which comprises a front groove, a rear groove and a bevel groove positioned between the front groove and the rear groove; the push rod (3) comprises a front rod body part with a semi-enclosed shape and a rear rod body part; the stop lever (2) comprises a first arm part, a second arm part and a stop lever shaft hole between the first arm part and the second arm part, wherein the front end part of the first arm part is provided with a bending part which can form a surrounding structure with the pushing part of the push rod (3); the second arm part is provided with a sliding column (2 a) which can be inserted into the sliding column limit groove (4 b) to slide.

Description

Dough processing mechanism for cake baking machine

Technical Field

The invention relates to the field of cake baking machines, in particular to a dough processing mechanism for a cake baking machine.

Background

In the daily life of people, pasta foods such as pancakes, breads, desserts, etc. have been an indispensable part of life. With busy work, simple and quick food is favored by people of different levels.

An automatic cake baking machine is very popular in the prior art because of the characteristic of convenient use. The automatic cake baking machine mainly comprises a base, a agglomerating device, a cake pressing device and a baking device, wherein the agglomerating device, the cake pressing device and the baking device are arranged above the base. The baking device comprises an upper baking tray and a lower baking tray. A cake pusher is arranged between the upper baking tray and the lower baking tray, and is driven by the driving force of a cake pusher driving motor to push out the baked cake.

In making pancakes using the cookie machine, it is generally necessary to make a suitable dough by a briquetting apparatus and then place the dough on a baking pan for baking. It is also often desirable to press or mold the dough into a predetermined cake shape using a tortilla press or other similar mechanism prior to baking.

According to the prior art, in the process of placing dough on a baking pan from a agglomerating device, it is not ensured that the dough placed each time is accurately located at a predetermined position (for example, the center position of the baking pan) and maintained in a proper form, so that when the dough placed on the baking pan is pressed or molded, there are cases where an ideal cake shape cannot be formed and the dough is heated unevenly when baked due to the deviation of the placement position, which ultimately affects the baking effect of the dough.

Disclosure of Invention

In view of the foregoing problems of the prior art, the present invention provides a dough handling mechanism for a cookie maker, comprising: the device comprises a push rod sliding rail, a driving motor fixedly arranged on the push rod sliding rail, a push rod which is driven by the driving motor and can slide back and forth on the push rod sliding rail, and a stop lever which is connected with the push rod and is positioned above the push rod;

the upper surface of the push rod sliding rail is provided with a sliding column limiting groove extending along the front-back direction, and the sliding column limiting groove comprises a front groove, a rear groove and a bevel groove positioned between the front groove and the rear groove;

the push rod comprises a push top part with a semi-surrounding shape at the front part and a rod body part at the rear part;

The stop lever comprises a first arm part extending along the front-back direction, a second arm part arranged at an angle relative to the first arm part, and a stop lever shaft hole between the first arm part and the second arm part, wherein the front end part of the first arm part is provided with a bending part which can form a surrounding structure together with the pushing part of the push rod; the second arm part is provided with a sliding column, and the sliding column can be embedded into the sliding column limiting groove to slide.

Preferably, the upper surface of push rod slide rail is equipped with the protruding muscle that extends along fore-and-aft direction, be provided with the protruding muscle spacing groove that is located on the lower surface of push rod on the push rod, protruding muscle spacing groove movably block is on the protruding muscle of push rod slide rail.

Preferably, a wing plate limiting groove is formed in the upper surface of the push rod sliding rail, the wing plate limiting groove is opened towards one side, the push rod comprises a wing plate of the rod body part extending to the lateral direction, and the wing plate of the rod body part can be movably embedded into the wing plate limiting groove.

Preferably, the wing plate limiting groove is formed by extending a plate upwards on the upper surface of the push rod sliding rail and then extending to one side.

Preferably, a rack may be provided on the push rod, the drive motor has an output shaft and a drive gear is fixedly provided on the output shaft, the drive gear being capable of meshing with the rack.

Preferably, push arms extending outward and leftward are provided on both left and right sides of the push portion of the push rod.

Preferably, the device is characterized in that the push rod is provided with an induction stop lever, a control board is arranged on the push rod sliding rail, an induction switch is arranged on the control board, and when the induction stop lever passes through the induction switch, the running position and the running state of the push rod can be detected and controlled.

Preferably, the push rod is provided with a limit post, and the limit post can limit the rotation range of the stop lever.

Preferably, protruding points are provided at the ends of the pushing arms on the left and right sides of the pushing portion.

The dough processor for the pancake machine has the following advantages: it is ensured that the dough placed each time is automatically and accurately positioned at a predetermined position and maintained in a proper form, thereby ensuring that the shape of the cake can be ensured when the dough is pressed or molded and that the baking of the dough can be prevented from being affected.

Drawings

The accompanying drawings are included to provide a further understanding of the application and are incorporated in and constitute a part of this specification, illustrate and do not limit the application.

Fig. 1 is a schematic diagram showing an exploded structure of a dough handling mechanism for a cookie maker, a base of the cookie maker, and a agglomerating device according to the present invention.

Fig. 2 is a schematic diagram showing an assembly structure of a dough handling mechanism for a cookie maker, a base of the cookie maker, and a agglomerating device according to the present invention.

Fig. 3 is a schematic cross-sectional view of a dough handling mechanism for a cookie maker according to the present invention.

Fig. 4 is a schematic view of the structure of the push rod of the dough handling mechanism for a cookie maker according to the present invention, as seen from the lower perspective.

Fig. 5 is a schematic perspective view showing a dough handling mechanism for a cookie maker according to the present invention in a first position with respect to a base of the cookie maker.

Fig. 6 is a schematic perspective view showing a dough handling mechanism for a cookie maker according to the present invention in a second position with respect to a base of the cookie maker.

Fig. 7 is a schematic perspective view showing a dough handling machine for a cookie machine according to the present invention in a third position with respect to a base mechanism of the cookie machine.

Reference numerals illustrate:

1-stop lever tabletting 2-stop lever 3-push rod

4-Push rod slide rail 5-driving motor 6-agglomerating device

7-Base 8-lower baking tray 9-control panel

2 A-sliding column 3 a-sensing stop lever 3 b-fixing column

3 C-rack 3 d-convex rib limiting groove 3 e-convex point

3 F-limit post 3 g-wing plate 4 a-convex rib of rod body

4 B-sliding column limit groove 4 c-wing plate limit groove 5 a-driving gear

7 A-bump limit groove 9 a-first inductive switch 9 b-second inductive switch

9 C-third inductive switch

Detailed Description

Referring to fig. 1-7 of the present application, the present application provides a dough handling mechanism for a cookie maker.

The dough processing mechanism for the pancake machine comprises: the device comprises a push rod slide rail 4, a driving motor 5 fixedly mounted on the push rod slide rail 4, a push rod 3 which is driven by the driving motor 5 and can slide back and forth on the push rod slide rail 4, and a stop lever 2 which is connected with the push rod 3 and is positioned above the push rod 3.

The dough handling mechanism for a cookie maker of the present invention may be mounted on the base 7 of the cookie maker in the cookie maker. The base 7 may also be provided with a dough forming device 6 for dough mixing and providing dough. The base 7 may also include a lower baking pan 8 onto which dough produced by the agglomerating device 6 may be poured for subsequent pressing and baking operations.

The upper surface of the push rod sliding rail 4 is provided with a convex rib 4a, a sliding column limiting groove 4b and a wing plate limiting groove 4c which extend along the front-back direction. Wherein the sliding column limit groove 4b comprises a front groove, a rear groove and a corner groove which is positioned between the front groove and the rear groove and is connected with the front groove and the rear groove; the front and rear slots are parallel to each other and not collinear. The wing plate limit groove 4c is formed by extending a plate material upward on the upper surface of the push rod slide rail 4 and then extending to one side, that is, the wing plate limit groove 4c is opened to one side.

The push rod 3 comprises a push top part positioned at the front part and a rod body part positioned at the rear part, wherein the push top part and the rod body part can be integrally formed and can be connected and fixed together after being respectively formed; and the two can be fixedly connected in a way that the centers of the two are opposite to each other or are in offset fixed connection as shown in fig. 1 according to the requirement. The ejector has a semi-enclosed shape so as to be able to enclose the dough or cake to be ejected.

More preferably, push arms extending outward and leftward are provided on both sides of the push top, so that the range covered by the push top can be further widened.

The push rod 3 may be provided with: the induction bar 3a, a fixing column 3b and a limit column 3f extending upwards from the upper surface of the push rod 3, a rack 3c, a convex rib limit groove 3d positioned on the lower surface of the push rod 3, convex points 3e positioned at two sides of the push rod and a bar body wing plate 3g extending laterally at one side of the bar body.

After the installation, the rib limiting groove 3d is clamped on the rib 4a of the push rod sliding rail 4, so that the push rod 3 can move along the rib 4a of the push rod sliding rail 4 in the front-back direction.

The lever body wing 3g is fitted in the wing limiting groove 4c of the lateral opening so as to be movable back and forth, and the position of the push rod in the up-down direction can be limited.

The drive motor 5 has an output shaft and a drive gear 5a is fixedly provided on the output shaft. After installation, the drive gear 5a can engage with the rack 3c of the push rod 3. Thus, when the drive motor 5 is turned on, the output shaft of the drive motor 5 rotates, the drive gear 5a rotates, and the push rod 3 can be moved back and forth on the push rod slide rail 4 by engagement of the drive gear 5a with the rack 3 c.

The protruding points 3e at both sides of the push rod may be provided at the ends of the push arms at both the left and right sides of the push part.

The bar 2 that can be mounted above the push rod 3 has a substantially open clip-like shape. The lever 2 includes a first arm portion extending in the front-rear direction, a second arm portion disposed at an angle with respect to the first arm portion, and a lever shaft hole between the first arm portion and the second arm portion. Wherein the front end part of the first arm part is formed into a bending part, and the bending part and the pushing part of the push rod 3 can form a surrounding structure; the second arm portion is provided with a slide column 2a.

After installation, the sliding column 2a on the stop lever 2 is embedded into the sliding column limit groove 4b on the push rod sliding rail 4. The shaft hole is sleeved on the fixed column 3b, so that the stop lever 2 can be allowed to move back and forth along with the push rod 3 and can rotate around the fixed column 3b as a shaft.

In addition, when the bar 2 is mounted to the push rod 3 such that the fixing post 3b passes through the shaft hole of the bar 2, the bar pressing sheet 1 with a through hole may be placed on the upper surface of the bar 2, so that the fixing post 3b is also inserted into the through hole of the bar pressing sheet 1, thereby ensuring that the bar 2 is not easily separated from the fixing post 3 b.

In addition, a control board 9 can be installed on the push rod sliding rail 4, and an inductive switch is arranged on the control board 9, and the inductive switch can be a plurality of inductive switches. As shown in fig. 1, the control board 9 is provided on the push rod rail 4 so as to extend in the front-rear direction, and a first, a second, and a third induction switch 9a, 9b, and 9c are provided in the front-rear direction. When the push rod 3 moves back and forth on the push rod sliding rail 4, the sensing stop lever 3a on the push rod 3 can pass through the first sensing switch 9a, the second sensing switch 9b and the third sensing switch 9c, so that the running position and the running state of the push rod 3 can be detected and controlled.

As shown in fig. 5, when the dough making device 6 makes dough, the dough can be poured into a dough receiving area defined by the stop lever 2 and the push rod 3 on the lower baking tray 8 by automatic control. Although the pouring of dough into this dough receiving area is controlled automatically, it is still not entirely ensured that the poured dough is in the desired position, for example in the centre of the lower baking tray 8.

At this time, as shown in fig. 5, the sensing bar 3a on the push rod 3 is just at the second sensing switch 9b of the control board 9, so that the accurate position (at this time, the first position) of the push rod 3 can be known. After the above-described operation of pouring and receiving the dough, it is necessary to move the push rod 3 forward and push the dough a certain distance and then backward until the dough is moved to a desired position by the first arm of the bar 2. It may be provided that when the dough moves to a desired position (e.g., at the center of a lower baking tray), the sliding pillar 2a of the bar 2 moves exactly to the corner groove of the sliding pillar limit groove 4b, and at this time, the bar 2 starts to rotate by the action of the corner groove on the sliding pillar 2a, so that the first arm does not touch the dough, thereby parking the dough to the desired position.

The bar 2 can then continue to move backwards with the push rod 3, the sliding post 2a of the bar 2 being able to move in the rear slot of the sliding post limit slot 4b, so that the first arm of the bar 2 is further away from the dough. At this time, the stop post 3f provided on the push rod 3 can limit the stop lever 2 to excessively rotate.

The pressing and/or baking operation of the dough can be started until the push rod 3 and the bar 2 are all withdrawn from the lower baking pan 8 (the position and state shown in fig. 6). At this time, as shown in fig. 6, the sensing bar 3a on the push rod 3 is just at the first sensing switch 9a of the control board 9, whereby the accurate position of the push rod 3 (at this time, the second position) can be known so as to control the next operation.

After the dough is pressed into a cake shape on the lower baking tray and/or the baking operation is completed, as shown in fig. 7, the driving motor 5 can be powered to drive the push rod 3 to move forward, so that the cake is pushed out through the pushing part of the push rod 3, and the cake pushing function is completed. At this time, as shown in fig. 7, the sensing bar 3a on the push rod 3 is just at the third sensing switch 9c of the control board 9, whereby the exact position of the push rod 3 (at this time, the third position) can be known. Thereafter, the state of fig. 5 may be returned to await the next cycle.

The dough processor for the pancake machine has the following advantages: it is ensured that the dough placed each time is automatically and accurately positioned at a predetermined position and maintained in a proper form, thereby ensuring that the shape of the cake can be ensured when the dough is pressed or molded and that the baking of the dough can be prevented from being affected.

Although the embodiments of the present application are described above, the embodiments are only used for facilitating understanding of the present application, and are not intended to limit the present application. Any person skilled in the art to which the present application pertains will appreciate that numerous modifications and changes in form and detail can be made without departing from the spirit and scope of the disclosure.

Claims (9)

1. A dough handling mechanism for a cookie maker, comprising: the device comprises a push rod sliding rail (4), a driving motor (5) fixedly arranged on the push rod sliding rail (4), a push rod (3) which is driven by the driving motor (5) and can slide back and forth on the push rod sliding rail (4), and a stop lever (2) which is connected with the push rod (3) and is positioned above the push rod (3);

A sliding column limiting groove (4 b) extending along the front-rear direction is formed in the upper surface of the push rod sliding rail (4), and the sliding column limiting groove (4 b) comprises a front groove, a rear groove and a bevel groove positioned between the front groove and the rear groove;

the push rod (3) comprises a push top part with a semi-enclosed shape at the front part and a rod body part at the rear part;

The stop lever (2) comprises a first arm part extending along the front-back direction, a second arm part arranged at an angle relative to the first arm part, and a stop lever shaft hole between the first arm part and the second arm part, wherein the front end part of the first arm part is provided with a bending part which can form a surrounding structure together with the pushing part of the push rod (3); the second arm part is provided with a sliding column (2 a), and the sliding column (2 a) can be embedded into the sliding column limiting groove (4 b) to slide.

2. The dough handling mechanism for a cookie machine according to claim 1, wherein a protruding rib (4 a) extending in the front-rear direction is provided on the upper surface of the push rod slide rail (4), a protruding rib limiting groove (3 d) located on the lower surface of the push rod (3) is provided on the push rod (3), and the protruding rib limiting groove (3 d) is movably clamped on the protruding rib (4 a) of the push rod slide rail (4).

3. The dough handling mechanism for a cookie machine according to claim 2, wherein a wing plate limit groove (4 c) is provided on an upper surface of the push rod slide rail (4), the wing plate limit groove (4 c) is opened toward one side, the push rod (3) includes a rod body wing plate (3 g) protruding laterally at one side of the rod body, and the rod body wing plate (3 g) is movably fitted into the wing plate limit groove (4 c).

4. A dough handling mechanism for a cookie machine according to claim 3, wherein the wing plate limit groove (4 c) is formed by a plate extending upward and then to one side on the upper surface of the push rod slide rail (4).

5. A dough handling mechanism for a cookie machine according to claim 4, wherein a rack (3 c) may be provided on the push rod (3), a drive motor (5) has an output shaft and a drive gear (5 a) is fixedly provided on the output shaft, and the drive gear (5 a) is capable of meshing with the rack (3 c).

6. A dough handling mechanism for a cookie machine as defined in claim 5, wherein push arms extending outward and leftward are provided on both left and right sides of the push portion of the push rod (3).

7. The dough handling mechanism for a cookie machine according to claim 6, wherein the push rod (3) is provided with a sensing bar (3 a), a control board (9) is mounted on the push rod sliding rail (4), a sensing switch is provided on the control board (9), and when the sensing bar (3 a) passes through the sensing switch, the operation position and the operation state of the push rod (3) can be detected and controlled.

8. A dough handling mechanism for a cookie machine according to claim 7, wherein the push rod (3) is provided with a limit post (3 f), the limit post (3 f) being capable of limiting the range of rotation of the bar (2).

9. A dough handling mechanism for a cookie machine as claimed in claim 8, wherein protruding points (3 e) are provided at ends of push arms on both left and right sides of the push top.