A toast production auxiliary demolding device and a demolding method thereof

Abstract

The application relates to the technical field of toast production equipment and discloses a toast production auxiliary demolding device and a demolding method thereof, which comprises a rack, a rotating shaft, a clamping assembly, a knocking assembly and a blowing piece. The rotating shaft is connected to the rack in a step rotation mode, and the axis extends along the horizontal direction. The clamping assembly is installed on the rotating shaft in multiple groups and in a circumferential mode, and is used for clamping a mold. The knocking assembly is installed on the rotating shaft, and is used for knocking the mold on the clamping assembly. The blowing piece is installed on the rack, and is arranged in multiple groups in a circumferential mode along the rotating shaft, and is used for heat dissipation of the mold. When the rotating shaft is static relative to the rack, the mold clamped by the clamping assembly at the bottom of the rotating shaft has an opening facing downward. The clamping assembly at the bottom of the rotating shaft is replaced every time the rotating shaft rotates once. The application can improve the demolding efficiency of the toast.

Description

Technical Field

[0001] This application relates to the technical field of toast production equipment, and in particular to a toast production auxiliary demolding device and demolding method. Background Technology

[0002] In the production of toast, demolding is one of the key process steps. Demolding usually requires waiting for the toast to cool after baking, and then the operator swings the mold back and forth to pour the toast out. The efficiency of toast demolding is often affected by the fatigue of the operators, resulting in low demolding efficiency. Summary of the Invention

[0003] To improve the efficiency of toast demolding, this application provides a toast production auxiliary demolding device and demolding method.

[0004] In the first aspect, this application provides a toast production auxiliary demolding device, which adopts the following technical solution:

[0005] A toast production auxiliary demolding device includes a frame;

[0006] A rotating shaft is connected to the frame by a stepping rotation, and the axis extends horizontally.

[0007] A clamping assembly having multiple sets and circumferentially mounted on the rotating shaft for clamping a mold;

[0008] A vibratory striking assembly, mounted on the rotating shaft, is used to strike the mold on the clamping assembly; and

[0009] A blower is mounted on the frame and multiple blowers are arranged circumferentially along the rotation axis for dissipating heat from the mold.

[0010] When the rotating shaft is stationary relative to the frame, the mold opening held by the clamping assembly at the bottom of the rotating shaft faces downward, and the clamping assembly at the bottom of the rotating shaft is replaced every time the rotating shaft rotates.

[0011] By adopting the above technical solution, the vibration tapping component effectively promotes the separation of the toast from the mold, reduces the difficulty of demolding, and minimizes toast breakage. The blower accelerates the heat dissipation process of the mold and the toast, which is beneficial for the rapid cooling and shaping of the toast, thus improving product quality.

[0012] Optionally, a movable sleeve is coaxially sleeved on the rotating shaft, and the vibration tapping assembly is mounted on the movable sleeve. The movable sleeve is axially movable along the rotating shaft to move the vibration tapping assembly relative to or away from the clamping assembly. Multiple sets of vibration tapping assemblies are located between adjacent clamping assemblies; each set of vibration tapping assemblies includes...

[0013] The connecting rod moves relative to the rotating shaft;

[0014] A power component, mounted on the rotating shaft, is used to drive the connecting rod to reciprocate radially along the rotating shaft;

[0015] The telescopic rod has two members, each with an adjustable length. The two telescopic rods are respectively hinged to opposite sides of the connecting rod, and each telescopic rod is opposite to a clamping assembly on either side of the connecting rod.

[0016] An adjusting element, disposed on the connecting rod, is used to adjust the angle between the telescopic rod and the connecting rod;

[0017] When the power component drives the connecting rod to reciprocate, it causes the striking component to strike or leave the mold.

[0018] By adopting the above technical solution and setting up multiple sets of vibration tapping components, the uniformity and comprehensiveness of tapping are improved, further reducing the difficulty of demolding. Furthermore, by adjusting the length of the telescopic rod, it is possible to tap molds of different sizes, improving the adaptability of the device. The adjustable component, which controls the tapping direction, further enhances the device's adaptability.

[0019] Optionally, the adjusting element includes

[0020] The gears correspond one-to-one with the telescopic rods, are fixed to one end of the telescopic rods that are hinged to the connecting rods, and are coaxial with the hinge axis of the telescopic rods.

[0021] A rack, located between the gears on opposite sides of the connecting rod, has teeth extending along the length of the connecting rod on both opposite sides of the two gears; and

[0022] A drive source is installed in the connecting rod to drive the rack to move along the length of the connecting rod.

[0023] By adopting the above technical solution, the rack is driven to move by the drive source, so that the telescopic rods on both sides of the connecting rod can rotate synchronously through the meshing of the rack and gear.

[0024] Optionally, the telescopic rod includes a main rod and a secondary rod, the main rod is hinged to the connecting rod, and the secondary rod moves along the length of the main rod at the end of the main rod away from the connecting rod.

[0025] Optionally, the stroke of the connecting rod driven by the power component can be adjusted so that the telescopic rod can strike the mold sidewall or the mold end face.

[0026] By adopting the above technical solution, the reciprocating stroke of the connecting rod can be adjusted so that the striking action can be customized according to the needs of different molds or toast, thereby improving the flexibility and effect of demolding.

[0027] Optionally, each set of the clamping components includes

[0028] An extension member is connected to the rotating shaft and extends radially along the rotating shaft;

[0029] Mounting frame, connected to the end of the extension rod away from the rotation axis;

[0030] The first clamping member has two parts, which are respectively located on opposite sides of the mounting frame and are adjustable in position on the mounting frame along the distribution direction of the two first clamping members; and

[0031] The second clamping member has two parts, which are respectively located at opposite ends of the mounting frame and can be adjusted in position on the mounting frame along the distribution direction of the two second clamping members;

[0032] The two first clamping members and the two second clamping members are used to jointly clamp the mold.

[0033] By adopting the above technical solution, the independent adjustment of the first clamping component and the second clamping component improves the stability and adaptability of mold clamping, making it suitable for molds of various specifications.

[0034] Optionally, the blower is spatially opposite to the two adjacent sets of clamping components.

[0035] By adopting the above technical solution, the space between the blower and the two adjacent clamping components is such that the molds on the two clamping components can be cooled simultaneously.

[0036] Optionally, a conveying assembly is also included, the conveying assembly including a base and a conveyor belt conveyed on the base, the conveyor belt being used to catch toast falling from the clamping assembly.

[0037] By adopting the above technical solution, the conveyor component enables the smooth transfer of toast from the mold to the next process, further improving production efficiency.

[0038] Secondly, this application provides a method for assisting in the demolding of toast production, which adopts the following technical solution:

[0039] A method for assisting in the demolding of toast production, using the aforementioned toast production assisting demolding device, includes the following steps:

[0040] S1, the mold after it comes out of the oven is clamped by the clamping assembly;

[0041] S2, the rotating shaft rotates intermittently in a step-by-step manner, and pauses after each rotation of the rotating shaft, so that the mold opening in the clamping assembly at the bottom of the rotating shaft faces downward. At the same time, the vibrating component knocks on each mold, and the blowing component dissipates heat from the mold on the clamping assembly.

[0042] S3, after the toast in the clamping component at the bottom of the rotating shaft falls out of the mold, the rotating shaft rotates again. Then the operator removes the mold from which the toast has been removed and replaces it with a new toast mold.

[0043] In summary, this application includes at least one of the following beneficial effects:

[0044] 1. The demolding device uses clamping components to clamp the mold and vibrating components to tap the mold, so that the toast inside the mold can be easily removed without leaving any residue. At the same time, the blowing component dissipates heat from the mold to accelerate the demolding speed of the toast and improve demolding efficiency.

[0045] 2. The striking position and striking intensity of the telescopic rod on the mold are adjustable, which can adapt to molds of different sizes and structures, thus improving the versatility of the demolding device. Attached Figure Description

[0046] Figure 1 This is a structural schematic diagram of an embodiment of this application;

[0047] Figure 2 This is a schematic diagram of the structure of the clamping component and the vibration knocking component according to an embodiment of this application;

[0048] Figure 3 This is a schematic diagram of the exploded structure between the clamping assembly and the mold in an embodiment of this application;

[0049] Figure 4 This is a cross-sectional view of the vibration tapping component according to an embodiment of this application;

[0050] Figure 5 yes Figure 4 Enlarged structural diagram at point A;

[0051] Figure 6 This is a schematic diagram of the structure of the vibration component and the mold in an embodiment of this application.

[0052] Explanation of reference numerals in the attached drawings: 1. Frame; 2. Rotating shaft; 3. Clamping assembly; 31. Extension piece; 32. Mounting frame; 33. First clamping piece; 34. Second clamping piece; 4. Vibration assembly; 41. Connecting rod; 42. Power component; 43. Telescopic rod; 431. Main rod; 432. Secondary rod; 44. Adjusting component; 441. Gear; 442. Rack; 443. Drive source; 5. Blowing component; 6. Moving sleeve; 7. Base; 8. Conveyor belt; 9. Screw; 10. Cylinder; 11. Mold. Detailed Implementation

[0053] The following is in conjunction with the appendix Figure 1-6 This application will be described in further detail.

[0054] This application discloses an auxiliary demolding device for toast production. (Refer to...) Figure 1 The toast production auxiliary demolding device includes a frame 1, a rotating shaft 2, a clamping assembly 3, a vibrating and tapping assembly 4, and a blower 5. The rotating shaft 2 is rotatably connected to the frame 1. The clamping assembly 3 and the vibrating and tapping assembly 4 are mounted on the rotating shaft 2 and move together with it as the shaft 2 rotates. The clamping assembly 3 is used to clamp the mold 11, and the vibrating and tapping assembly 4 is used to tap the clamped mold 11 to improve the smoothness of toast demolding. The blower 5 is mounted on the frame 1 and is used to cool the mold 11 by blowing air.

[0055] Reference Figure 1 and Figure 2 The rotating shaft 2 extends horizontally, and a motor connected to the rotating shaft 2 is mounted on the frame 1 to drive the rotating shaft 2 to rotate. The motor type is a stepper motor, which drives the rotating shaft 2 to rotate step by step. The clamping assembly 3 has multiple sets and is evenly spaced along the circumference of the rotating shaft 2. The number of clamping assemblies 3 is n. The angle of each rotation of the rotating shaft 2 is 360° / n, so that each rotation of the rotating shaft 2 drives one set of clamping assemblies 3 to move to the lower side of the rotating shaft 2, so that the opening of the clamping assembly 3 clamps the mold 11 facing downward, so that the toast in the mold 11 falls down under the tapping of the vibrating assembly 4.

[0056] Reference Figure 2 and Figure 3 In this embodiment, the clamping assembly 3 has four sets, with one rotating side serving as the loading position for the operator to load and unload the mold 11. Each set of clamping assemblies 3 includes an extension member 31, a mounting frame 32, a first clamping member 33, and a second clamping member 34. The extension member 31 is rod-shaped, with one end fixed to the outer wall of the rotating shaft 2 and the other end fixedly connected to the mounting frame 32. The extension member 31 extends radially away from the rotating shaft 2. The mounting frame 32 is square-shaped, with its plane parallel to the axis of the rotating shaft 2. The outer wall of the middle edge of one end of the mounting frame 32 is fixed to the extension member 31.

[0057] Reference Figure 3 Each clamping assembly 3 has two first clamping members 33 and two second clamping members 34, which together clamp the mold 11. Specifically, the first clamping member 33 is rod-shaped, and the two first clamping members 33 are parallel to each other and parallel to the upper and lower sides of the mounting frame 32. The two ends of each first clamping member 33 slide on the left and right ends of the mounting frame 32, forming a space between the two first clamping members 33 for placing the mold 11. Both ends of the mounting frame 32 are fixed with screws 9 along their own edges for the ends of the first clamping members 33 to be sleeved and slid. The position of the first clamping member 33 is adjusted by sliding on the screws 9, and the screws 9 have a pair of nuts that abut against the opposite sides of the first clamping member 33 to position the first clamping member 33.

[0058] The second clamping member 34 is also rod-shaped. The two second clamping members 34 are parallel to each other and parallel to the left and right ends of the mounting frame 32, making the second clamping member 34 perpendicular to the first clamping member 33. Multi-stage electric telescopic rods are installed at both ends of the mounting frame 32. The electric telescopic rods at both ends of the mounting frame 32 are respectively connected to the two second clamping members 34. The electric telescopic rods drive the second clamping members 34 to move in a direction parallel to the length of the first clamping member 33.

[0059] When placing the mold 11 on the clamping assembly 3, the distance between the two first clamping members 33 is adjusted to match the size of the mold 11 before placing the mold 11, and the space between the two first clamping members 33 is located in the middle of the mounting frame 32. Then, the mold 11 is placed between the two first clamping members 33, and the electric telescopic rod is driven to move the two second clamping members 34 toward each other, so that the two second clamping members 34 together clamp the mold 11 in the middle position to position the mold 11.

[0060] In addition, the mold 11 has a square structure and an outer edge extending circumferentially along the opening. When placing the mold 11, the outer edge of the mold 11 is brought into contact with the first clamping member 33 so that the molds 11 of the same batch are all in the same position on the clamping assembly 3.

[0061] Reference Figure 2 and Figure 4For the vibration assembly 4, a cylindrical movable sleeve 6 is coaxially sleeved on the outer wall of the rotating shaft 2. A cylinder 10 is installed on the frame 1 to drive the movable sleeve 6 to move axially along the rotating shaft 2. When the rotating shaft 2 rotates, the movable sleeve 6 does not rotate with the rotating shaft 2. Each set of vibration assemblies 4 is located between two adjacent sets of clamping assemblies 3. All vibration assemblies 4 are mounted on the movable sleeve 6. When the rotating shaft 2 is stationary, when the piston rod of the cylinder 10 extends, it drives the vibration assembly 4 to move opposite to the clamping assembly 3. When the piston rod of the cylinder 10 retracts, it drives the vibration assembly 4 to move away from the clamping assembly 3. At this time, the rotating shaft 2 can rotate while the clamping assembly 3 does not interfere with the vibration assembly 4.

[0062] The number of sets of the vibration-tapping assembly 4 is the same as that of the clamping assembly 3, and in this embodiment, there are four sets. Each set of vibration-tapping assembly 4 includes a connecting rod 41, a power component 42, a telescopic rod 43, a striking component, and an adjusting component 44. The power component 42 is an electric telescopic rod, and the frame 1 of the power component 42 is fixedly installed on the outer wall of the rotating shaft 2. The telescopic end of the power component 42 extends radially along the rotating shaft 2. One end of the connecting rod 41 is fixed to the telescopic end of the power component 42. The connecting rod 41 also extends radially along the rotating shaft 2, and the connecting rod 41 serves as the angle bisector of the angle between two adjacent clamping assembly 3 extensions 31.

[0063] Reference Figure 2 and Figure 4 The telescopic rod 43 includes a main rod 431 and a secondary rod 432. The main rod 431 is shaped like a screw 9, and the secondary rod 432 is coaxially sleeved and threadedly connected to the outer wall of one end of the main rod 431. The extension length of the telescopic rod 43 is adjusted by the threaded movement of the secondary rod 432 on the main rod 431. Each set of vibration assembly 4 has two telescopic rods 43. The main rods 431 of the two telescopic rods 43 are respectively hinged to opposite sides of the connecting rod 41 through hinge seats. The hinge axis of the main rod 431 and the connecting rod 41 is parallel to the axis of the rotation shaft 2. Both telescopic rods 43 are located at the end of the connecting rod 41 away from the rotation shaft 2, and each telescopic rod 43 corresponds to two adjacent extension members 31.

[0064] Reference Figure 4 and Figure 5An adjusting component 44 is installed between the connecting rod 41 and the main rod 431 to drive the two main rods 431 on the connecting rod 41 to rotate synchronously in opposite directions. Specifically, the adjusting component 44 includes a gear 441, a rack 442, and a drive source 443. There are two gears 441, which are respectively fixed on the main rods 431 on both sides of the connecting rod 41, and the axis of the gears 441 is parallel to the hinge axis between the main rods 431 and the connecting rod 41. The connecting rod 41 is hollow, and the rack 442 and the drive source 443 are both located in the cavity of the connecting rod 41. The drive source 443 is an electric telescopic rod, and the frame 1 of the drive source 443 is fixed relative to the connecting rod 41. The telescopic end of the drive source 443 is connected to the rack 442 to drive the rack 442 to move along the length direction of the connecting rod 41. The rack 442 has teeth distributed along the length of the connecting rod 41 on both sides. The teeth on both sides of the rack 442 mesh with the gears 441 on both sides of the connecting rod 41. When the rack 442 moves along the length of the connecting rod 41, it drives the gears 441 to rotate, thereby adjusting the angle between the main rod 431 and the connecting rod 41.

[0065] When the telescopic end of the drive source 443 retracts, it drives the two main rods 431 to rotate away from each other, so that the included angle between the two main rods 431 adapts to the included angle between the end faces of the two adjacent molds 11. When the telescopic end of the drive source 443 extends, it drives the two main rods 431 to rotate towards each other, so that the two auxiliary rods 432 respectively fit against the opposite sides of the connecting rod 41.

[0066] Reference Figure 4 and Figure 6 During the rotation of the rotating shaft 2, the telescopic end of the power component 42 extends and retracts cyclically, driving the connecting rod 41 to reciprocate along the axis of the rotating shaft 2. When the telescopic end of the drive source 443 is retracted, the movement of the connecting rod 41 can drive the auxiliary rods 432 on both sides of the connecting rod 41 to strike the two adjacent molds 11 respectively.

[0067] The telescopic stroke of the power component 42 can be adjusted. In this embodiment, the telescopic stroke of the power component 42 has two types, namely a first stroke and a second stroke. The power component 42 in the first stroke and the power component 42 in the second stroke are alternately arranged along the circumference of the movable sleeve 6.

[0068] When the extension stroke of the power component 42 is the first stroke, the extension end of the power component 42 extends and drives the auxiliary rod 432 to strike the end face of the mold 11 near the rotating shaft 2. The extension end of the power component 42 retracts and drives the auxiliary rod 432 away from the mold 11. When the extension stroke of the power component 42 is the second stroke, the extension end of the power component 42 retracts and drives the auxiliary rod 432 to strike the outer peripheral wall of the mold 11. The extension end of the power component 42 extends and drives the auxiliary rod 432 away from the mold 11.

[0069] Furthermore, the telescopic end of the drive source 443 extends after the power component 42 retracts, driving the auxiliary rod 432 to rotate and retract towards the connecting rod 41; the telescopic end of the drive source 443 also retracts after the power component 42 extends, driving the auxiliary rod 432 to rotate away from the connecting rod 41, so that the auxiliary rod 432, which cooperates with the first stroke power component 42, unfolds to strike the mold 11 when it is driven to the striking position, and the auxiliary rod 432, which cooperates with the second stroke power component 42, can give the mold 11 a tendency force to move towards the rotating shaft 2 when it rotates back towards the connecting rod 41, making it less likely for the mold 11 to fall off the clamping assembly 3.

[0070] Reference Figure 1 For the blower component 5, which is a blower, there are two sets of blowers, each set containing multiple blowers. The two sets of blowers are respectively mounted on opposite sides of the frame 1 and located at the top of the frame 1. When the rotating shaft 2 is stationary, the two sets of blowers are located on opposite sides of the top mounting frame 32 of the rotating shaft 2, with the blowers facing the rotating shaft 2, so that each set of blowers is opposite to the space between two adjacent mounting frames 32, thereby allowing the blowers to simultaneously cool the side walls of the two sets of molds 11.

[0071] Reference Figure 1 Furthermore, the lower side of the frame 1 has a conveying assembly located below all the clamping assemblies 3. The conveying assembly includes a base 7 and a conveyor belt 8. The base 7 is mounted on the lower side of the frame 1, and the conveyor belt 8 is conveyed on the base 7. The upper surface of the conveyor belt 8 is opposite to the clamping assembly 3 located at the lowest side of the rotating shaft 2, so as to receive the toast falling from the mold 11 and convey the toast to the next processing station.

[0072] The implementation principle of the toast production auxiliary demolding device in this application embodiment is as follows: The operator fixes the hot toast mold 11 after it comes out of the oven using the clamping assembly 3. As the rotating shaft 2 rotates intermittently in a step-by-step manner, the mold 11 is brought to the bottom position in sequence, at which point the opening of the mold 11 faces downward. During this process, the vibration tapping assembly 4 taps the bottom mold 11, using vibration to help separate the toast from the mold 11. At the same time, the blower 5 blows air to cool the mold 11, further promoting the rapid demolding of the toast. After the toast is removed from the mold 11, it is collected, thus completing the entire demolding process.

[0073] This application embodiment also provides a method for assisting in the demolding of toast production, which uses the above-mentioned device for assisting in the demolding of toast production, and includes the following steps:

[0074] S1, the mold 11 after being taken out of the furnace is placed into the clamping component 3 at the feeding position;

[0075] S2, the rotating shaft 2 rotates intermittently in a step-by-step manner, and pauses after each rotation of the rotating shaft 2, so that the mold 11 in the clamping assembly 3 at the bottom of the rotating shaft 2 faces downward;

[0076] S3, after the rotating shaft 2 stops rotating, the piston rod of the cylinder 10 extends to drive the vibrating component 4 to move to the position opposite to the clamping component 3. At the same time, the power component 42 in each vibrating component 4 drives the connecting rod 41 to move back and forth to strike the mold 11; at the same time, the blower 5 dissipates heat from the mold 11 on the clamping component 3.

[0077] S3, after the toast in the bottom clamping component 3 of the rotating shaft 2 falls from the mold 11, the piston rod of the cylinder 10 retracts to drive the vibrating component 4 away from the position opposite to the clamping component 3. Then the rotating shaft 2 rotates again, causing the clamping component 3, which was originally located at the bottom of the rotating shaft 2, to rotate to the feeding position. The operator removes the mold 11 and replaces it with a new toast mold 11.

[0078] The above are all preferred embodiments of this application, and are not intended to limit the scope of protection of this application. Therefore, all equivalent changes made in accordance with the structure, shape and principle of this application should be covered within the scope of protection of this application.

Claims

1. A toast production auxiliary demolding device, characterized in that: Including rack (1); The rotating shaft (2) is connected to the frame (1) by step rotation, and the axis extends horizontally; The clamping assembly (3) has multiple sets and is mounted circumferentially on the rotating shaft (2) for clamping the mold (11). The vibrating component (4) is mounted on the rotating shaft (2) and is used to strike the mold (11) on the clamping component (3); as well as A blower (5) is installed on the frame (1) and multiple blowers are arranged circumferentially along the rotating shaft (2) for heat dissipation of the mold (11); When the rotating shaft (2) is stationary relative to the frame (1), the mold (11) held by the clamping assembly (3) at the bottom of the rotating shaft (2) faces downwards. The rotating shaft (2) is coaxially fitted with a movable sleeve (6), and the vibration knocking component (4) is mounted on the movable sleeve (6). The movable sleeve (6) can move axially along the rotating shaft (2) to drive the vibration knocking component (4) to be opposite to or away from the clamping component (3). The vibration knocking component (4) has multiple sets and is located between each pair of adjacent clamping components (3). Each set of the vibration knocking component (4) includes The connecting rod (41) moves relative to the rotating shaft (2); A power component (42) is mounted on the rotating shaft (2) and is used to drive the connecting rod (41) to reciprocate radially along the rotating shaft (2); Two telescopic rods (43) are provided, each with an adjustable length. The two telescopic rods (43) are respectively hinged to opposite sides of the connecting rod (41), and each telescopic rod (43) is opposite to the clamping assemblies (3) on both sides of the connecting rod (41). Each telescopic rod (43) includes a main rod (431) and a secondary rod (432). An adjusting member (44) is provided on the connecting rod (41) for adjusting the angle between the telescopic member (43) and the connecting rod (41); When the power component (42) drives the connecting rod (41) to move back and forth, it causes the telescopic rod (43) to strike or leave the mold (11). The adjusting member (44) includes The gear (441) corresponds one-to-one with the telescopic rod (43), is fixed to one end of the telescopic rod (43) hinged to the connecting rod (41), and is coaxial with the hinge axis of the telescopic rod (43); A rack (442), located between the gears (441) on opposite sides of the connecting rod (41), has teeth extending along the length of the connecting rod (41) on both opposite sides of the two gears (441); and A drive source (443) is installed in the connecting rod (41) to drive the rack (442) to move along the length of the connecting rod (41); The stroke of the power component (42) driving the connecting rod (41) to reciprocate can be adjusted so that the telescopic rod (43) can strike the side wall of the mold (11) or the end face of the mold (11). The extension stroke of the power component (42) has two types, namely a first stroke and a second stroke. The power component (42) in the first stroke and the power component (42) in the second stroke are alternately arranged along the circumference of the movable sleeve (6). When the extension stroke of the power component (42) is the first stroke, the extension end of the power component (42) extends and drives the auxiliary rod (432) to strike the end face of the mold (11) near the rotating shaft (2). When the extension stroke of the power component (42) is the second stroke, the extension end of the power component (42) retracts and drives the auxiliary rod (432) to strike the outer peripheral wall of the mold (11). The telescopic end of the drive source (443) extends after the power component (42) is retracted, so as to drive the auxiliary rod (432) to rotate and retract towards the connecting rod (41); the telescopic end of the drive source (443) retracts after the power component (42) is extended, so as to drive the auxiliary rod (432) to rotate away from the connecting rod (41), so that the auxiliary rod (432) cooperating with the power component (42) in the first stroke can extend and strike the mold (11) when it is driven to the striking position, and the auxiliary rod (432) cooperating with the power component (42) in the second stroke can give the mold (11) a tendency force to move towards the rotating shaft (2) when it rotates back towards the connecting rod (41).

2. The toast production auxiliary demolding device according to claim 1, characterized in that: The main rod (431) is hinged to the connecting rod (41), and the auxiliary rod (432) moves along the length of the main rod (431) at the end of the main rod (431) away from the connecting rod (41).

3. The toast production auxiliary demolding device according to claim 1, characterized in that: Each set of clamping components (3) includes An extension member (31) is connected to the rotating shaft (2) and extends radially along the rotating shaft (2); Mounting frame (32) is connected to the end of the extension (31) away from the rotating shaft (2); The first clamping member (33) has two parts, and the two first clamping members (33) are respectively located on opposite sides of the mounting frame (32), and their positions can be adjusted on the mounting frame (32) along the distribution direction of the two first clamping members (33); as well as The second clamping member (34) has two parts, and the two second clamping members (34) are respectively located at opposite ends of the mounting frame (32), and their positions can be adjusted on the mounting frame (32) along the distribution direction of the two second clamping members (34); The two first clamping members (33) and the two second clamping members (34) are used to clamp the mold (11) together, and the second clamping members (34) are perpendicular to the first clamping members (33).

4. The toast production auxiliary demolding device according to claim 1, characterized in that: The blower (5) is spatially opposite to the two adjacent sets of clamping components (3).

5. The toast production auxiliary demolding device according to claim 1, characterized in that: It also includes a conveying assembly, which includes a base (7) and a conveyor belt (8) conveyed on the base (7), the conveyor belt (8) being used to catch toast falling from the clamping assembly (3).

6. A method for assisting in the demolding of toast production, using the toast production assisting demolding device according to any one of claims 1-5, characterized in that, Includes the following steps: S1, the mold (11) after being taken out of the oven is clamped by the clamping assembly (3); S2, the rotating shaft (2) rotates intermittently in a step-by-step manner, and pauses after each rotation of the rotating shaft (2) so that the mold (11) in the clamping assembly (3) at the bottom of the rotating shaft (2) faces downward. At the same time, the vibrating assembly (4) strikes each mold (11), and the blowing component (5) dissipates heat from the mold (11) on the clamping assembly (3). S3, after the toast in the bottom clamping component (3) of the rotating shaft (2) falls out of the mold (11), the rotating shaft (2) rotates again. Then the operator removes the mold (11) from which the toast has been removed and replaces it with a new toast mold (11).

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