A dough conveyor
By integrating the dough conveying, guiding, and correction functions of the dough conveyor cart, the problem of uncorrectable dough shape is solved, achieving continuous and stable dough conveying and shape correction, thus improving production efficiency and equipment applicability.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- ANHUI HENGYUAN FOOD MASCH CO LTD
- Filing Date
- 2025-08-11
- Publication Date
- 2026-07-03
AI Technical Summary
The dough's shape cannot be effectively corrected during transport, resulting in low production efficiency, increased labor and equipment costs, and production stoppages are easily caused by poor process connections.
Design a dough conveyor vehicle that integrates dough conveying, guiding movement and correction functions. The dough shape is corrected by an adjustable dough guiding correction component and a motor-driven correction roller. Combined with guide grooves, slider limits and scale pointers for precise adjustment, continuous and stable dough conveying and shape correction are achieved.
It improves the continuity and efficiency of dough processing, reduces equipment space occupation, expands the scope of application, ensures the consistency of dough shape and quality stability, simplifies production operations, and improves overall production efficiency.
Smart Images

Figure CN224440229U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to a dough conveyor vehicle, belonging to the field of pasta processing technology. Background Technology
[0002] Noodle processing refers to the production activities that use flour as the main raw material to make noodle products through processes such as kneading, shaping, and cooking, encompassing both traditional handmade products and industrialized production.
[0003] In food processing, all pasta products require the use of dough mixers. During production, the dough mixer pours the kneaded dough onto a cart, and then workers push the cart away to move the dough to the equipment that needs to be used. This process is extremely labor-intensive, time-consuming, and prone to contaminating the dough. Most conveying devices can only achieve simple dough transport and cannot effectively correct the shape of the dough during the transport process. As a result, the dough needs to be shaped manually or by additional equipment before entering the next processing step. This not only increases labor costs and equipment investment but also easily causes production to stop due to poor process connection, reducing overall production efficiency. Summary of the Invention
[0004] To solve the above-mentioned technical problems, this utility model provides a dough conveying vehicle.
[0005] The technical solution adopted by this utility model to solve its technical problem is:
[0006] A dough conveying vehicle includes a frame and a controller. The controller is disposed on one side of the frame. A dough conveying part is disposed on the upper side of the frame. A guide moving part is disposed on the lower side of the frame. A dough correction guide part is disposed on the upper side of the frame and above the dough conveying part. The dough correction guide part includes a support frame. An adjustable dough guide correction component is disposed on one side of the support frame.
[0007] With the above technical solution, the frame serves as the installation base, the controller is used for the overall operation control of the equipment, the dough conveying section on the upper side of the frame is responsible for the bearing and conveying of the dough, the guide moving section on the lower side realizes the overall movement of the equipment, and the dough correction guide section located above the dough conveying section corrects and guides the shape of the dough during the conveying process through its support frame and adjustable dough guide correction components. All components work together to complete the conveying and correction of the dough.
[0008] By integrating dough conveying, guiding movement, and correction functions, the equipment becomes fully functional, eliminating the need for multiple additional devices, reducing equipment space requirements, and improving the continuity and efficiency of dough processing.
[0009] Preferably, the adjustable dough guide correction assembly includes a threaded adjustment rod, which is rotatably connected to one side of the support frame. Two movable seats are threadedly connected to the outer side of the threaded adjustment rod. A second reducer is provided on one side of the movable seats, a correction motor is provided on one side of the second reducer, and a correction roller is provided on the other side of the second reducer. The correction roller is perpendicular to the dough conveying part.
[0010] Through the above technical solution, in the adjustable dough guide correction assembly, the threaded adjustment rod is rotatably connected to the support frame. When the threaded adjustment rod is rotated, the two movable seats connected to its outer thread will move relative to or towards each other along the axial direction of the threaded adjustment rod, thereby driving the reducer II, correction motor and correction roller installed on the movable seats to move synchronously, realizing the adjustment of the distance between the two correction rollers; when the correction motor is running, the power is transmitted to the correction roller through the reducer II, driving the correction roller to rotate, and the correction roller is set perpendicular to the dough conveying part, and rolls and corrects its side or shape during the dough conveying process.
[0011] The spacing between the correction rollers can be flexibly adjusted via a threaded adjustment method, which can adapt to the correction needs of dough of different sizes and shapes, and has a wide range of applications; the correction motor drives the correction rollers to rotate actively for correction, which improves the effect and uniformity of dough shape correction and ensures the consistency of dough shape.
[0012] Preferably, a guide groove is provided on one side of the support frame, and a guide slider is slidably connected in the guide groove, with one side of the guide slider connected to one side of the movable seat.
[0013] Through the above technical solution, the guide groove on one side of the support frame provides a sliding track for the guide slider. The guide slider is connected to the movable seat. When the movable seat moves under the action of the threaded adjusting rod, the guide slider will slide synchronously with the movable seat in the guide groove, thereby limiting and guiding the movement direction of the movable seat.
[0014] The cooperation between the guide groove and the guide slider restricts the movement trajectory of the moving seat, preventing the moving seat from deviating or shaking during movement, ensuring the smoothness and accuracy of the movement of the moving seat and the correction roller, and improving the precision of dough correction.
[0015] Preferably, a scale is provided on the upper side of the support frame, and a pointer is provided on the upper side of the movable seat.
[0016] With the above technical solution, the scale on the upper side of the support frame is marked with graduations, and the pointer on the upper side of the moving seat moves synchronously with the moving seat. When the moving seat drives the correction roller to move and adjust the spacing, the pointer points to the corresponding graduation on the scale, which can intuitively reflect the size of the spacing between the two correction rollers.
[0017] By using the pointer and ruler, operators can intuitively and accurately grasp the spacing parameters of the correction roller, making it easy to make precise adjustments according to the dough size requirements, reducing adjustment errors, and improving the convenience of operation and the consistency of parameter settings.
[0018] Preferably, the dough conveying unit includes a conveying frame, which is disposed on one side of the machine frame. A speed reducer is disposed on one side of the conveying frame, a conveying motor is disposed on one side of the speed reducer, a drive shaft is disposed on the other side of the speed reducer, and a driven shaft is disposed on one side of the conveying frame. A conveyor belt is rotatably sleeved on the outer side of the driven shaft and the drive shaft.
[0019] Through the above technical solution, in the dough conveying section, the power generated by the conveyor motor is reduced by a reducer and then transmitted to the drive shaft. The drive shaft rotates and drives the driven shaft to rotate synchronously through the conveyor belt, so that the conveyor belt forms a cyclic motion. The dough is placed on the conveyor belt and is continuously conveyed from one place to another as the conveyor belt moves.
[0020] The conveyor belt driven by a motor provides stable and reliable transmission, enabling continuous and uniform conveying of dough. This avoids stagnation or accumulation during dough conveying, thus improving the efficiency and stability of dough conveying.
[0021] Preferably, the guide moving part includes a moving motor, which is disposed on one side of the frame. A synchronous pulley is disposed on the shaft end of the moving motor. A synchronous belt is sleeved on the outer side of the synchronous pulley, and a synchronous pulley is sleeved on the inner side of the synchronous belt. A plurality of side plates are disposed on the lower side of the frame. A connecting shaft is rotatably connected through one side of the side plate. A roller is fixedly sleeved on the outer side of the connecting shaft. The synchronous pulley is fixedly sleeved with one of the connecting shafts. A guide frame is disposed at the bottom of one side of the frame, and a matching double-groove guide rail is disposed on the lower side of the guide frame.
[0022] Through the above technical solution, in the guide moving part, the moving motor drives the first synchronous wheel to rotate, and the first synchronous wheel transmits power to the second synchronous wheel through the synchronous belt. The rotation of the second synchronous wheel drives the coupling shaft that is fixedly sleeved with it to rotate, and the coupling shaft drives the roller to rotate, so that the equipment moves. At the same time, the guide frame at the bottom of the frame matches the double groove guide rail, which plays a guiding role during the movement of the equipment and ensures that the equipment moves along the direction of the guide rail.
[0023] The rollers are rotated by a synchronous belt drive, which has high transmission efficiency and smooth operation. The cooperation between the guide frame and the double-groove guide rail ensures the accuracy of the equipment's movement direction, avoids deviation during equipment movement, improves the flexibility and precision of equipment movement, and facilitates the adjustment of the equipment's position within the production site.
[0024] Compared with the prior art, the beneficial effects of this utility model are as follows:
[0025] This invention integrates a dough conveying unit, a guiding and moving unit, and a dough correction guiding unit onto a frame, achieving integrated operation of dough conveying, equipment movement, and shape correction. It eliminates the need for multiple independent devices, effectively reducing the space occupied by equipment in the production area, simplifying the dough processing flow, improving the continuity of operations from dough conveying to shape correction, and increasing overall production efficiency.
[0026] This utility model features an adjustable dough guide correction assembly that allows for flexible adjustment of the distance between two correction rollers via a threaded adjustment rod. This adapts to the correction needs of dough of different sizes and shapes, significantly expanding the applicability of the equipment. The correction motor drives the correction rollers to rotate actively via a reducer. Combined with the vertical arrangement of the correction rollers and the dough conveying section, the dough is uniformly rolled and corrected during the conveying process, effectively improving the effect and consistency of dough shape correction and ensuring the stable quality of the dough in subsequent processing.
[0027] This invention precisely limits the movement trajectory of the moving seat by the sliding cooperation of the guide groove and the guide slider, avoiding deviation, shaking or jamming when the moving seat moves under the action of the threaded adjustment rod, ensuring that the moving seat and the correction roller move smoothly and steadily, thereby improving the accuracy of the correction roller spacing adjustment and the stability of the dough correction operation.
[0028] This invention visualizes the correction roller spacing parameter through the combination of a scale and a pointer, allowing operators to intuitively read and accurately control the correction roller spacing. This reduces reliance on experience and trial-and-error costs during the adjustment process, lowers adjustment errors, improves the convenience and consistency of parameter settings, and facilitates standardized production operations. Attached Figure Description
[0029] To more clearly illustrate the technical solutions in the embodiments of this utility model or the prior art, the drawings used in the description of the embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on the structures shown in these drawings without creative effort.
[0030] Figure 1 This is a schematic diagram of the explosive structure of this utility model;
[0031] Figure 2 This is a schematic diagram of the structure of the dough correction guide of this utility model;
[0032] Figure 3 This is a schematic diagram of the front axonometric structure of this utility model;
[0033] Figure 4 This is a schematic diagram of the axial structure on the back side of this utility model.
[0034] In the diagram: 1. Frame; 2. Controller; 3. Dough conveying section; 31. Conveyor frame; 32. Reducer 1; 33. Conveyor motor; 34. Drive shaft; 35. Driven shaft; 36. Conveyor belt; 4. Dough correction guide section; 41. Support frame; 42. Threaded adjusting rod; 43. Moving seat; 44. Reducer 2; 45. Correction motor; 46. Correction roller; 47. Guide chute; 48. Guide slider; 49. Scale; 410. Pointer; 5. Guide moving section; 51. Moving motor; 52. Synchronous pulley 1; 53. Synchronous belt; 54. Synchronous pulley 2; 55. Side plate; 56. Connecting shaft; 57. Roller; 58. Guide frame; 59. Double groove guide rail. Detailed Implementation
[0035] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.
[0036] Please see Figures 1-4 This utility model provides a technical solution:
[0037] A dough conveying vehicle includes a frame 1, a controller 2 fixedly installed on one side of the outer wall of the frame 1 for setting, regulating and monitoring the operating parameters of the entire equipment, a dough conveying unit 3 fixedly installed on the upper side of the frame 1 by bolts, responsible for the carrying and conveying of dough; a guide moving unit 5 is installed on the lower side of the frame 1 to realize the directional movement of the equipment in the production site; a dough correction guide unit 4 is fixedly welded on the upper side of the frame 1 and directly above the dough conveying unit 3. The dough correction guide unit 4 includes a support frame 41 with a portal structure, and an adjustable dough guide correction component is provided between the vertical beams on both sides of the support frame 41 for accurately correcting the shape of the dough during the conveying process.
[0038] The adjustable dough guide correction assembly includes a support frame 41, with a threaded adjustment rod 42 rotatably connected between the two vertical beams of the support frame 41. The two ends of the threaded adjustment rod 42 are rotatably engaged with the support frame 41 through bearing seats, and one end extends to the outside of the support frame 41 and is equipped with an adjustment handwheel.
[0039] The outer side of the threaded adjusting rod 42 is provided with two external threads with opposite directions, which are threadedly connected to two moving seats 43. When the threaded adjusting rod 42 is rotated, the two moving seats 43 can move relative to each other or towards each other along the axial direction of the threaded adjusting rod 42.
[0040] A reducer 44 is bolted to one side of each movable seat 43. The input end of the reducer 44 is connected to the output shaft of the correction motor 45 via a coupling. The correction motor 45 is fixed to the movable seat 43 via a motor mount.
[0041] The output end of the reducer 44 is fixed with a correction roller 46 by a key. The axis of the correction roller 46 is set perpendicular to the conveying direction of the dough conveying section 3. When the correction motor 45 is running, the power is reduced and increased by the reducer 44 and then transmitted to the correction roller 46, which drives the correction roller 46 to rotate at a set speed to roll and correct the sides of the conveyed dough.
[0042] To ensure the stability of the movement of the movable seat 43, a guide groove 47 is provided on the inner side wall of the support frame 41 along the axial direction of the threaded adjusting rod 42. A guide slider 48 is slidably embedded in the guide groove 47. The side of the guide slider 48 away from the groove is fixedly connected to the side wall of the movable seat 43 by bolts.
[0043] When the movable seat 43 moves under the drive of the threaded adjusting rod 42, the guide slider 48 slides synchronously along the guide groove 47, forming a guide limit on the movable seat 43 to prevent it from rotating or deviating.
[0044] To achieve precise adjustment of the spacing of the correction rollers 46, a scale 49 is attached and fixed along the length direction on the top surface of the upper crossbeam of the support frame 41. The scale accuracy of the scale 49 is 1mm. A pointer 410 is welded and fixed to the upper side of each moving seat 43, and the tip of the pointer 410 points to the scale surface of the scale 49.
[0045] When the moving seat 43 drives the correction roller 46 to move, the pointer 410 moves synchronously with the moving seat 43. The operator can directly read the distance between the two correction rollers 46 through the scale value pointed to by the pointer 410, so as to achieve millimeter-level precision adjustment.
[0046] The dough conveying unit 3 includes a conveying frame 31, which is fixedly installed on the upper surface of the frame 1 by bolts. A reducer 32 is fixedly installed on one side end of the conveying frame 31 by a motor mount. The input end of the reducer 32 is connected to a conveying motor 33 by a coupling. The output speed of the conveying motor 33 is adjusted by the reducer 32 and then drives the drive shaft 34 to rotate through the output shaft.
[0047] The driven shaft 35 is rotatably connected to the end of the conveyor frame 31 away from the drive shaft 34 via a bearing seat. The drive shaft 34 and the driven shaft 35 are rotatably sleeved on the outside of the drive shaft 34 and the driven shaft 35. The conveyor belt 36 is made of food-grade rubber and has anti-slip texture on its surface.
[0048] When the conveyor motor 33 starts, the drive shaft 34 drives the driven shaft 35 to rotate synchronously through the conveyor belt 36, forming a circular conveying trajectory. The dough is placed on the conveyor belt 36 and moves with it to achieve continuous conveying.
[0049] The guide moving part 5 includes a moving motor 51, which is fixedly mounted on the lower outer wall of the frame 1 via a motor base. The output shaft end of the moving motor 51 is connected and fixed with a first synchronous pulley 52 via a key. A synchronous belt 53 is sleeved on the outer side of the first synchronous pulley 52, and a second synchronous pulley 54 is sleeved on the inner side of the synchronous belt 53 away from the first synchronous pulley 52, forming a belt drive mechanism.
[0050] Side plates 55 are welded and fixed at the four corners of the lower side of the frame 1. A connecting shaft 56 is rotatably connected through one side of the side plate 55. One end of the connecting shaft 56 is rotatably engaged with the side plate 55 through a bearing. Rollers 57 are fixedly sleeved on the outer side of the connecting shaft 56 corresponding to the two sides of the frame 1.
[0051] One end of the coupling 56 is fixedly connected to the second synchronous pulley 54 by a key. When the moving motor 51 is running, the power is transmitted to the second synchronous pulley 54 through the first synchronous pulley 52 and the synchronous belt 53, which drives the coupling 56 and the roller 57 to rotate, thereby realizing the movement of the equipment.
[0052] A guide frame 58 is fixed to one side bottom of the frame 1 by bolts. A matching double groove guide rail 59 is slidably engaged at the lower opening of the guide frame 58. The double groove guide rail 59 is fixed to the ground by expansion bolts. During the movement of the equipment, the guide frame 58 slides along the trajectory of the double groove guide rail 59 to ensure that the equipment moves along the preset path.
[0053] The workflow of this embodiment is as follows: During operation, the operator sets parameters such as the conveying speed of the conveyor belt 36, the rotation speed of the correction roller 46, and the moving speed of the equipment through the controller 2; according to the target size of the dough, the threaded adjustment rod 42 is rotated, and the distance between the two correction rollers 46 is adjusted to the set value through the cooperation of the pointer 410 and the scale 49.
[0054] After the equipment is started, the guide moving part 5 drives the equipment to move along the double groove guide rail 59 to the feeding station. The dough is placed on the conveyor belt 36 and is conveyed to the dough correction guide part 4. When passing the correction roller 46, the two relatively rotating correction rollers 46 roll and correct the two sides of the dough. The corrected dough continues to be conveyed to the next processing station with the conveyor belt 36, completing the entire dough conveying and correction operation.
[0055] Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the present invention, the scope of which is defined by the appended claims and their equivalents.
Claims
1. A dough conveyor cart, comprising a frame and a controller, wherein the controller is disposed on one side of the frame, characterized in that, The upper side of the frame is provided with a dough conveying part, the lower side of the frame is provided with a guide moving part, and the upper side of the frame and above the dough conveying part is provided with a dough correction guide part. The dough correction guide part includes a support frame, and an adjustable dough guide correction component is provided on one side of the support frame.
2. The dough conveyor cart according to claim 1, characterized in that, The adjustable dough guide correction assembly includes a threaded adjustment rod, which is rotatably connected to one side of the support frame. Two movable seats are threadedly connected to the outer side of the threaded adjustment rod. A speed reducer is provided on one side of the movable seats, a correction motor is provided on one side of the speed reducer, and a correction roller is provided on the other side of the speed reducer. The correction roller is perpendicular to the dough conveying part.
3. A dough conveyor cart according to claim 2, characterized in that, A guide groove is provided on one side of the support frame, and a guide slider is slidably connected in the guide groove. One side of the guide slider is connected to one side of the movable seat.
4. A dough conveyor cart according to claim 2, characterized in that, A scale is provided on the upper side of the support frame, and a pointer is provided on the upper side of the movable seat.
5. A dough conveyor cart according to claim 1, characterized in that, The dough conveying unit includes a conveying frame, which is disposed on one side of the machine frame. A speed reducer is disposed on one side of the conveying frame, a conveying motor is disposed on one side of the speed reducer, a drive shaft is disposed on the other side of the speed reducer, and a driven shaft is disposed on one side of the conveying frame. A conveyor belt is rotatably sleeved on the outer side of the driven shaft and the drive shaft.
6. A dough conveyor according to claim 1, characterized in that, The guiding moving part includes a moving motor, which is disposed on one side of the frame. A synchronous pulley is disposed on the shaft end of the moving motor. A synchronous belt is sleeved on the outer side of the synchronous pulley, and a synchronous pulley is sleeved on the inner side of the synchronous belt. Several side plates are disposed on the lower side of the frame. A connecting shaft is rotatably connected through one side of the side plate. A roller is fixedly sleeved on the outer side of the connecting shaft. The synchronous pulley is fixedly sleeved with one of the connecting shafts. A guide frame is disposed at the bottom of one side of the frame. A matching double-groove guide rail is disposed on the lower side of the guide frame.