阅读说明：本技术 一种全自动压面机 (Full-automatic noodle press ) 是由 张广锦 于 2020-07-21 设计创作，主要内容包括：本发明公开了一种全自动压面机：压面机包括面料容置箱,自动切料机构,压面机构,叠面机构,出料输送机构；切面机构置于原料输送机构之上与面料容置箱相连,压面机构由三个压面辊组成压面组合,在顶部有一能作正反向动作的换向辊,换向辊反向运动时,已压好的面料送入出料输送带,正向运动时,面料向二辊压面机构前进,二辊压面后再进入叠面机构；叠面机构由摆面杆组件、电机及偏心轮连杆组件组成,叠面机构在偏心轮连杆组件带动下作前后摆动运动,将片状的面料片前后扬起并落在运输带上叠成层,叠成片层的面料再输送入压面机构作重复压的工作。(The invention discloses a full-automatic noodle press, which comprises the following components: the noodle press comprises a fabric accommodating box, an automatic cutting mechanism, a noodle pressing mechanism, a noodle stacking mechanism and a discharging and conveying mechanism; the dough cutting mechanism is arranged on the raw material conveying mechanism and connected with the fabric containing box, the dough pressing mechanism is composed of three dough pressing rollers to form a dough pressing combination, a reversing roller capable of doing forward and reverse actions is arranged at the top of the dough pressing mechanism, when the reversing roller moves reversely, the pressed fabric is conveyed into the discharging conveying belt, when the reversing roller moves forward, the fabric moves forward to the two dough pressing mechanisms, and then enters the dough stacking mechanism after the two dough pressing mechanisms press the dough; the surface stacking mechanism is driven by the eccentric wheel connecting rod assembly to swing back and forth, sheet-shaped flour sheets are lifted back and forth and fall on the conveying belt to be stacked, and the stacked flour sheets are conveyed into the surface pressing mechanism to be pressed repeatedly.)

1. The utility model provides a full-automatic oodle maker, its is including oodle maker constructs (10) and (15), fold face mechanism (16), lower conveyer belt (9) and last conveyer belt (13), ejection of compact conveyer belt (17), its characterized in that: the dough pressing mechanism (10) is connected with the lower conveying belt (9), the lower conveying belt (9) receives the dough delivered by the raw material conveying mechanism, the dough containing box (1) is connected with the toothed feeding rod (3), the dough cutting mechanism (5) is arranged on the raw material conveying mechanism and connected with the dough containing box (1), and the circuit control device (22) controls the operation of each mechanism.

2. The full-automatic noodle press according to claim 1, characterized in that a reversing roller (11) is arranged above three noodle press rollers of the noodle press mechanism (10), and the reversing roller (11) is driven by a motor (805) to run in the reverse direction.

3. The full-automatic noodle press according to claim 1, characterized in that: the bottom of the fabric containing box (1) is provided with supporting legs (7), and the bottom of the box main body is composed of a front conveying belt (2).

4. The full-automatic noodle press according to claim 1, characterized in that: the raw material conveying mechanism consists of motors (801) and (802), a plurality of gears, a toothed feeding rod (3), a front conveying belt (2) and a rear conveying belt (6), wherein the motors (801) are connected with the gears in a transmission mode, the gears are in transmission connection with the toothed feeding rod (3), after the motors (801) run, the raw materials on the front conveying belt (2) are conveyed to the position of the automatic cutting mechanism (5) through the toothed feeding rod (3) by the force of gear transmission, and the motors (802) drive the rear conveying belt (6).

5. The full-automatic noodle press according to claim 1, characterized in that: the automatic cutting mechanism (5) consists of an air cylinder, an electromagnetic valve and a cutting knife, wherein the air cylinder controls the cutting knife to act under the action of air pressure to cut off the fabric, and the electromagnetic valve acts to control a pneumatic device.

6. The full-automatic noodle press according to claim 1, characterized in that:

after being cut off from the automatic cutting mechanism (5), the fabric is sent to the position of the noodle pressing mechanism (10) through the rear conveying belt (6) and the lower conveying belt (9), and the lower conveying belt (9) is fixed on the periphery (12) of the noodle pressing mechanism and the periphery (14) of the noodle stacking mechanism.

7. The full-automatic noodle press according to claim 1, characterized in that:

the dough pressing mechanism (10) consists of three dough pressing rollers (A, B, C), a motor (806), a gear and a transmission chain, wherein the motor operates to drive the gear to transmit, the gear drives a roller rod to rotate, and the roller rod presses and grinds the fabric.

8. The full-automatic noodle press according to claim 1, characterized in that:

the dough pressing mechanism (15) consists of two dough pressing rollers (E, F), a motor (807), a gear and a transmission chain, wherein the motor operates to drive the gear to transmit, the gear drives a roller rod to rotate, and the roller rod presses and grinds the fabric.

9. The full-automatic noodle press according to claim 1, characterized in that: the dough folding mechanism (16) consists of a gear assembly, a motor, an eccentric wheel connecting rod assembly and a swing rod assembly (1601), wherein the swing rod assembly (1601) reciprocates left and right through the eccentric wheel connecting rod assembly to lift and fold the flaky fabrics in the swing rod assembly into layers and drop to the lower conveying belt (9), and the conveying belt conveys the fabrics into the position of the dough pressing mechanism (10) again, so that the operation is repeated in a circulating way.

10. The full-automatic noodle press according to claim 1, characterized in that: the circuit control device (22) comprises a power supply module, a detection module, a microprocessor control module and a motor driving module; the power supply module is used for supplying working voltage to the mechanism; the detection module is used for detecting the effect degree of the fabric after being repeatedly kneaded and pressed, and the detection mode can be set by time to be used as the reflection of the effect degree. And sending a corresponding signal after the fabric reaches the qualified degree, and making an action after the motor or the switch receives the signal. The micro-processing control unit makes action instructions to the detection module and other operation mechanisms.

Technical Field

The invention relates to the field of automatic fabric processing machines for making bread, in particular to the automatic fabric kneading and pressing aspect.

Background

Before flour is processed into food, a large amount of kneading and pressing are needed after flour is made into the fabric, and good taste and quality can be produced after the quality of the fabric is changed. However, dough kneaders on the market at present are in a semi-automatic mode, the technology in the aspects of feeding, pressing and discharging still stays at a relatively laggard level, for example, some similar dough kneaders do not have an automatic material cutting device and a containing box, and an automatic reverse structure is not arranged in the aspect of a dough pressing roller, so that the dough can only be manually output from a reverse direction after being well pressed, and meanwhile, an automatic detection function is not arranged in the aspect of a dough kneading effect, for example, an invention patent with the publication number of CN102986759A discloses an automatic dough kneader. Thus, the whole process of pressing the dough becomes extremely time-consuming and labor-intensive, and meanwhile, the kneading quality is lack of the control and convenience.

Disclosure of Invention

In order to improve the lagging condition of the noodle press on the market, the invention aims to provide the noodle press which can be fully automatically operated and can control the kneading and pressing quality.

In order to enable raw materials to be automatically fed, the invention provides a fabric box with a bottom plate consisting of a conveying belt, wherein a support frame is arranged at the bottom of the box to support the weight of the fabric box, and large balls of fabric can be placed on the conveying belt in the box and then are conveyed by the conveying belt driven by a motor to automatically reach the next process position.

In order to control the weight of the fabric to enter the dough pressing mechanism, a material cutting mechanism is arranged before the fabric is conveyed into the dough pressing mechanism, the material cutting mechanism can control the weight of the fabric, and when a certain weight is reached, a cutter on the mechanism cuts off the fabric, so that more fabric is stopped to be conveyed.

The fabric is cut off from the cutting mechanism and is conveyed by a conveying belt, the fabric is conveyed to the position of a flour pressing mechanism, the flour pressing mechanism consists of three groups of rollers, three rollers move oppositely under the drive of a motor to press the fabric into sheets, then the sheets are conveyed to a two-roller flour pressing mechanism through the conveying belt, the fabric enters a flour stacking mechanism after being kneaded by two rollers, the flour stacking mechanism consists of two flour swinging frames and an eccentric wheel connecting rod assembly, the flour swinging frames are distributed in a front-back mode, each flour swinging frame consists of a plurality of round rods and a four-side surrounding sheet, the fabric descends from two rollers and enters the middle of the two groups of flour swinging frames, the flour swinging frames swing in a front-back mode under the drive of the eccentric wheel connecting rod assembly, so that a fabric layer is lifted and stacked on a conveying belt below layer by layer, the conveying belt conveys the fabric into the flour pressing mechanism for repeated kneading until the kneaded quality reaches the requirement, and after the detection mechanism detects the fabric and sends out a qualified signal, the fabric is output from the reversing roller to the rear conveying belt, and the whole manufacturing process flow is completed. The circuit control device comprises a power supply module, a detection module, a microprocessor control module and a motor driving module; the power supply module is used for supplying working voltage to the mechanism; the detection module is used for detecting the effect degree of the fabric after being repeatedly kneaded and pressed, and the detection mode can be set by time to be used as the reflection of the effect degree. And sending a corresponding signal after the fabric reaches the qualified degree, and making an action after the motor or the switch receives the signal. The micro-processing control unit makes action instructions to the detection module and other operation mechanisms.

Drawings

Embodiments of the invention are described in further detail below with reference to the attached drawing figures, wherein:

fig. 1 is a schematic view of the machine composition of the present invention.

Fig. 2 is an assembled top view of the present invention.

Fig. 3 is a perspective view of the swing frame of the present invention.

Fig. 4 is a circuit structure composition diagram of the present invention.

Detailed Description

The present invention will be described in further detail with reference to specific embodiments in the following drawings. It should be understood that the following examples are intended to illustrate the present invention only and not to limit the scope of the present invention, and that other drawings may be derived from those figures without inventive exercise for those skilled in the art.

The invention is used for realizing the full-automatic noodle press, as shown in figure 1: the noodle making machine comprises noodle pressing mechanisms (10) and (15), a noodle stacking mechanism (16), a lower conveying belt (9), an upper conveying belt (10) and a discharge conveying belt (17), wherein the noodle pressing mechanism (10) is connected with the lower conveying belt (9), the lower conveying belt (9) is used for bearing the fabrics conveyed by the raw material conveying mechanism, a fabric containing box (1) is connected with a toothed feeding rod (3), a noodle cutting mechanism (5) is arranged on the raw material conveying mechanism and connected with the fabric containing box (1), and a circuit control device (22) is used for controlling the operation of each mechanism.

Referring to an arrow forward schematic in fig. 1, the original fabric is placed in a fabric accommodating box (1), and a conveying belt at the bottom of the box conveys the fabric forward under the driving of a motor and enters a toothed feeding rod (3).

Furthermore, a toothed feeding rod (3) is connected with a gear set, a gear drives the toothed feeding rod (3) to move under the driving of a motor, toothed anti-slip threads are distributed on the surface of the toothed feeding rod (3), the fabric can be effectively rolled, after the fabric is conveyed to a certain amount, a signal is sent to a circuit control device (22), a control calculation mode of specific amount can be used as one of program design modes through time, the circuit control device (22) sends a movement instruction to a cutting mechanism (5) through an electromagnetic valve and an air cylinder (4), and a cutting knife operates downwards to cut the fabric. The cut fabric is conveyed to a lower conveyer belt (9) through a rear conveyer belt (6).

Furthermore, a lower conveying belt (9) is in butt joint with the noodle pressing mechanism in a gradient manner, the lower conveying belt (9) is fixed on the periphery (12) of the noodle pressing mechanism and the periphery (14) of the noodle stacking mechanism and is supported by supporting legs (7), and a bottom frame (20) of the noodle pressing and noodle stacking mechanism is arranged below the lower conveying belt (9) and plays a role of supporting the two mechanisms.

Furthermore, when the flour is conveyed to the flour pressing mechanism (10), three rollers which run oppositely knead and press the flour, the three rollers are driven by a gear assembly (18) and a motor (20) to act, the gears are connected by a chain belt to generate transmission, the periphery (12) of the flour pressing mechanism is made of metal materials, and the flour pressing mechanism is protected. A reversing roller (11) is arranged above three dough pressing rollers of the dough pressing mechanism (10), the reversing roller (11) can perform reversing operation in the positive and negative directions under the control of a circuit, when the dough is qualified by kneading, the reversing roller (11) acts under the control of the circuit to convey the dough to a rear conveying belt (17), the rear conveying belt (17) is supported by a support (21), and power is driven by a motor.

Furthermore, the kneaded fabric enters an upper conveying belt (13), the upper conveying belt (13) is driven by a motor (806), the fabric enters a noodle pressing mechanism (15) after passing through the conveying belt, the noodle pressing mechanism consists of two rollers, a gear assembly (19) and a motor (21) drive the two rollers to run, and gears are connected by a chain belt to generate transmission.

The dough pressing mechanism (15) and the dough stacking mechanism (16) are surrounded by a control housing (14) which is provided with a circuit control device (22) of the dough pressing machine.

Furthermore, the fabric pressed out of the two rollers moves forwards towards the fabric stacking mechanism (16), the fabric stacking mechanism (16) is composed of two fabric swinging frames and a synchronous motor, the fabric swinging frames (1601) are distributed in a front-to-back mode, the fabric swinging frames (1601) are composed of a plurality of round rods and a four-side surrounding sheet, the fabric enters the middle of the two groups of the fabric swinging frames after moving downwards from the two rollers, the fabric swinging frames (1601) swing in a front-to-back mode greatly under the driving of the eccentric wheel connecting rod assemblies, so that the fabric layer is lifted, the fabric layer is stacked on the conveying belt below layer by layer, and the conveying belt sends the fabric into the fabric pressing mechanism to be repeatedly kneaded until the quality of the kneaded fabric reaches the requirement.

Furthermore, after the detection mechanism detects and sends out a qualified signal, the fabric is output from the reversing roller (11) to the rear conveying belt, and the whole manufacturing process flow is completed.

The circuit control device (22) comprises a power supply module, a detection module, a microprocessor control module and a motor driving module; the power supply module is used for supplying working voltage to the mechanism; the detection module is used for detecting the effect degree of the fabric after repeated kneading and pressing, and one of the detection modes can be set by time to be used as the reflection of the effect degree. And sending a corresponding signal after the fabric reaches the qualified degree, and making an action after the motor or the switch receives the signal. The micro-processing control unit makes action instructions to the detection module and other operation mechanisms.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein.