CN220235849U - Flour puff separating device - Google Patents

Abstract

The embodiment of the utility model provides a flour puff separating device which is used for separating fine dried noodles from flour puffs, and comprises a containing box and a pushing assembly, wherein a conveying channel for placing the fine dried noodles is arranged in the containing box; the pushing component can reciprocate and is connected with the accommodating box so as to drive the accommodating box to reciprocate; the bottom wall of the conveying channel is provided with a plurality of steps along the moving direction of the fine dried noodles, the height of the top surface of each step is gradually reduced, and at least part of the pushing component is arranged in the conveying channel and used for restraining the moving range of the fine dried noodles along the moving direction of the fine dried noodles. According to the flour puff separating device, flour puffs on the surface of the fine dried noodles are separated from the fine dried noodles under the action of friction force by moving the fine dried noodles, so that the residual flour puff amount of the fine dried noodles is reduced; in the process of moving the fine dried noodles, the fine dried noodles roll down to the next step by step under the action of gravity, so that the probability that the fine dried noodles positioned at the downstream along the moving direction of the fine dried noodles return to the upstream and are adhered to the separated flour puff again is reduced.

Description

Flour puff separating device

Technical Field

The utility model relates to the technical field of food processing, in particular to a flour puff separating device.

Background

In the production of fine dried noodles, a large amount of dry flour, called flour puff, is sprinkled on wet fine dried noodles in order to prevent the fine dried noodles from adhering to each other.

The flour puff remained on the surface of the dried noodles can not only influence the eating of the dried noodles, but also influence the weighing precision in the packaging process of the dried noodles. Therefore, it is necessary to separate the puff on the surface of the fine dried noodles from the fine dried noodles.

Disclosure of Invention

In view of the foregoing, it is desirable to provide a puff separation device that can separate a puff on a surface of a fine dried noodle from the fine dried noodle.

In order to achieve the above purpose, the technical solution of the embodiments of the present application is implemented as follows:

the embodiment of the utility model provides a flour puff separating device for separating fine dried noodles from flour puffs, which comprises:

the accommodating box is internally provided with a conveying channel for placing the fine dried noodles;

a reciprocally movable pushing assembly coupled to the housing case to drive the housing case to reciprocally move;

the bottom wall of the conveying channel is provided with a plurality of steps along the moving direction of the fine dried noodles, the height of the top surface of each step is gradually reduced, and at least part of the pushing component is arranged in the conveying channel and used for restraining the moving range of at least part of the fine dried noodles in the moving direction of the fine dried noodles.

In some embodiments, at least part of the top surface of the step includes an inclined sub-surface and a horizontal sub-surface, the horizontal sub-surface extends along the horizontal direction, the inclined sub-surface is located upstream of the horizontal sub-surface along the moving direction of the fine dried noodles and is connected with the side surface of the step at the previous stage, and the height of the inclined sub-surface gradually decreases from upstream to downstream along the moving direction of the fine dried noodles.

In some embodiments, the pushing assembly includes a push plate at least partially positioned in the conveying channel, a top surface of the step being vertically spaced from a bottom end of the push plate to form a gap for the fine dried noodles to pass through.

In some embodiments, the number of push plates is a plurality, each push plate is disposed at intervals along the moving direction of the fine dried noodles, the push plates include a first push plate and a second push plate, the first push plate includes a straight plate portion and an arc plate portion, the straight plate portion extends along the vertical direction, the arc plate portion is located below the straight plate portion, the arc plate portion is gradually bent from top to bottom towards the downstream of the moving direction of the fine dried noodles, and the second push plate extends along the vertical direction.

In some embodiments, the first push plate is disposed upstream of the second push plate in the direction of travel of the fine dried noodles.

In some embodiments, the pushing assembly includes a moving sleeve, the top side of the conveying channel is open, the pushing plate extends into the conveying channel from the open position of the conveying channel, the moving sleeve is connected with a part of the pushing plate located outside the conveying channel, the moving sleeve moves reciprocally along the moving direction of the fine dried noodles, and the moving sleeve is connected with the containing box.

In some embodiments, the push plate is provided with a height-adjusting through groove extending along a vertical direction, the height-adjusting through groove penetrates through the push plate along a thickness direction of the push plate, and a screw penetrates through the height-adjusting through groove to be detachably connected with the moving sleeve.

In some embodiments, the moving set includes a moving plate, a connecting rod and a plurality of supports, the connecting rod with the push pedal is connected, the support extends along vertical direction, the both ends of connecting rod respectively with one the top of support is connected so that the connecting rod strides to locate the top of holding the case, the bottom of support with the moving plate is connected, the moving plate is located hold the below of case and with hold the case and be connected.

In some embodiments, a bottom wall at the end of the conveying channel is provided with a discharge port for discharging the fine dried noodles and the flour puff, the discharge port extends along a vertical direction, the moving flat plate is provided with a through hole penetrating along the vertical direction, and in the projection along the vertical direction, the projection of the discharge port is located in the projection range of the through hole.

In some embodiments, the flour puff separating device comprises a driving assembly, wherein the driving assembly is positioned below the moving flat plate and is in driving connection with the driving flat plate so as to drive the moving flat plate to reciprocate along the moving direction of the fine dried noodles.

In some embodiments, the face-puff separation device further comprises a driving assembly, the driving assembly comprises a motor, a driving rod and an adapter, the output end of the motor is fixedly connected with the adapter to drive the adapter to swing, one end of the driving rod is rotationally connected with the adapter, the rotation axis is parallel to the swing axis of the adapter, and the other end of the driving rod is rotationally connected with the pushing assembly.

In some embodiments, the adaptor is disc-shaped, the output end of the motor is connected to the central position of the adaptor, the adaptor is provided with a plurality of first mounting holes along the radial direction, one end of the driving rod is provided with a second mounting hole, and the pin passes through the second mounting hole and alternatively passes through one of the first mounting holes, so that the driving rod is rotationally connected with the adaptor.

According to the flour puff separating device, the containing box and the fine dried noodles are moved relatively, so that flour puffs on the surfaces of the fine dried noodles are separated from the fine dried noodles under the action of friction force, the residual flour puffs on the fine dried noodles are reduced, the follow-up packaging and weighing precision is improved, and meanwhile, the edible experience of users is improved; the restriction of the pushing component on the dried noodles is realized, and the height of the steps is gradually decreased, so that the dried noodles generally have a trend of downstream movement; in the process of moving the fine dried noodles, the fine dried noodles can roll down to the next step by step under the action of gravity, the effect of separating flour puff is improved, and the fine dried noodles on each step are fewer in number than the flour puff adhered to the fine dried noodles on the previous step, and the flour puff adhered to the fine dried noodles on the last step is minimum. On one hand, the dried noodles with least flour puff adhered in the conveying channel can be conveniently and intuitively screened out; on the other hand, the probability that the dried noodles positioned at the downstream in the moving direction of the dried noodles return to the upstream and are re-adhered with the separated flour puff is effectively reduced, so that the flour puff separating efficiency of the dried noodles is improved.

Drawings

FIG. 1 is a schematic view of a face-puff separation device according to an embodiment of the present utility model;

FIG. 2 is a schematic view of a containment tank and a push assembly in accordance with an embodiment of the present utility model, wherein a portion of the side walls of the containment tank are not shown;

FIG. 3 is an enlarged partial schematic view of the position A in FIG. 2;

FIG. 4 is a schematic cross-sectional view of a containment tank and a push assembly in accordance with an embodiment of the present utility model;

FIG. 5 is a partially enlarged schematic illustration of the position B in FIG. 4;

FIG. 6 is a schematic view of the force applied to the fine dried noodles by the first pushing plate during the process of restricting the movement of the fine dried noodles according to an embodiment of the present utility model, wherein the dotted arrow indicates the rolling circulation direction of the fine dried noodles;

FIG. 7 is a schematic view of a mobile plate, guide rail and drive assembly according to an embodiment of the present utility model;

fig. 8 is an enlarged partial schematic view of the position C in fig. 7.

Description of the reference numerals

A housing case 10; a conveying passage 10a; a discharge port 10b; a step 11; a top surface 11a; a side surface 11b; an inclined sub-surface 11c; a horizontal sub-surface 11d; a pushing assembly 20; a push plate 21; a height-adjusting through groove 21a; a gap 21b; a first push plate 211; a straight plate portion 2111; an arc plate portion 2112; a second push plate 212; a mobile kit 22; a moving plate 221; a through hole 221a; a connecting rod 222; a rod 2221; a connection base 2222; a bracket 223; a guide rail 23; a slider 24; a drive assembly 30; a motor 31; a drive lever 32; an adapter 33; a first mounting hole 33a; a pin 34; a mounting frame 40; a mounting space 40a; mounting the support legs 41; a baffle 42; fine dried noodles 50

Detailed Description

It should be noted that, in the case of no conflict, the embodiments and technical features in the embodiments may be combined with each other, and the detailed description in the specific embodiments should be interpreted as an explanation of the gist of the present application and should not be construed as undue limitation to the present application.

In the description of the present application, the "upper", "lower", "top", "bottom", "vertical direction" azimuth or positional relationship is based on the azimuth or positional relationship shown in fig. 2, 4, 6 and 7, the "upstream", "downstream" and "direction of movement of the fine dried noodles" azimuth or positional relationship is based on the azimuth or positional relationship shown in fig. 2, 4 and 6, and the "first", "last" azimuth or positional relationship is based on the azimuth or positional relationship shown in fig. 4, it should be understood that these azimuth terms are merely for convenience of description and simplification of description, and are not to indicate or imply that the apparatus or element referred to must have a specific azimuth, be constructed and operated in a specific azimuth, and therefore should not be construed as limiting the present application.

An embodiment of the present utility model provides a dough sheet separating apparatus for separating fine dried noodles 50 from a dough sheet, which specifically includes a receiving box 10 and a pushing assembly 20, referring to fig. 1, 2 and 4.

The accommodating box 10 is provided therein with a conveying passage 10a for placing the fine dried noodles 50.

It will be appreciated that the number of fine dried noodles 50 placed in the conveyor 10a is large, and the fine dried noodles 50 are deposited on the bottom wall of the conveyor 10a by gravity.

The pushing assembly 20 is reciprocally movable, and the pushing assembly 20 is connected with the accommodating case 10 to drive the accommodating case 10 to reciprocally move.

The fine dried noodles 50 are subjected to inertia during the reciprocating movement of the accommodating box 10, and relatively move with the accommodating box 10. The noodles 50 are reciprocally movable, i.e. from upstream to downstream in the direction of noodles movement, or from downstream to upstream in the direction of noodles movement.

It will be appreciated that the acceleration of the movement of the containing box 10 from upstream to downstream in the direction of the fine dried noodles moving is not smaller than the acceleration of the movement from downstream to upstream during the reciprocating movement, so that the fine dried noodles 50 in the conveying path 10a generally have a moving tendency from upstream to downstream during the multiple movements.

At least part of the pushing assembly 20 is disposed in the conveying path 10a for restricting a moving range of the fine dried noodles 50 along the moving direction of the fine dried noodles. The range of movement of the noodles 50 is constrained by the pushing assembly 20 during the reciprocating movement of the noodles 50.

Note that, the moving manner of the fine dried noodles 50 includes sliding and rolling.

During the reciprocating movement of the fine dried noodles 50, friction occurs between the fine dried noodles 50 and the fine dried noodles 50, between the inner wall of the conveying passage 10a and the fine dried noodles 50, and between the fine dried noodles 50 and the pushing assembly 20 due to pushing, so that the fine dried noodles adhered to the surface of the fine dried noodles 50 are subjected to the friction force. In the case where the magnitude of the component force of the friction force in the radial direction of the fine dried noodles 50 is larger than the magnitude of the adhesion force between the puff and the fine dried noodles 50, the puff is separated from the fine dried noodles 50 and deposited in the conveyance path 10a.

It is understood that the moving direction of the fine dried noodles 50 is perpendicular to the length direction of the fine dried noodles 50, so as to reduce the probability of the fine dried noodles 50 being broken by force during the moving process.

The bottom wall of the conveying channel 10a is provided with a plurality of steps 11 along the moving direction of the fine dried noodles, the height of the top surface 11a of each step 11 is gradually reduced, and the pushing component 20 is used for restricting the moving range of the fine dried noodles 50 on the top surface 11a of each step 11, so that the fine dried noodles 50 roll down from the upstream step 11 to the downstream step 11 along the moving direction of the fine dried noodles under the restriction of the pushing component 20 and the blocking of the side surface 11b of the step 11 until moving to the tail end of the conveying channel 10a.

It will be appreciated that as the noodles 50 and the pushing assembly 20 approach each other, the height of the pile of noodles 50 formed by the pushing assembly 20 will become high; when the fine dried noodles 50 and the pushing assembly 20 are far away from each other, the pushing action of the pushing assembly 20 is eliminated, the fine dried noodles 50 can collapse to a certain extent, the partially collapsed fine dried noodles 50 can move from downstream to upstream, the side surface 11b of the upper step 11 can play a certain role in blocking the fine dried noodles 50, and the probability that the fine dried noodles 50 return to the upper step 11 is reduced, so that the moving trend from upstream to downstream is generally generated in the process of moving the fine dried noodles 50 in the conveying channel 10a for multiple times.

It will be appreciated that the fine dried noodles 50 will roll during the process of rolling down from the upstream step 11 to the downstream step 11, so that the area of the fine dried noodles 50 under the action of friction force can be increased, and the effect of separating the noodles is improved.

According to the flour puff separating device disclosed by the embodiment of the utility model, the flour puff on the surface of the fine dried noodles 50 is separated from the fine dried noodles 50 under the action of friction force by relative movement between the accommodating box 10 and the fine dried noodles 50, so that the residual flour puff amount on the fine dried noodles 50 is reduced, the follow-up packaging and weighing precision is improved, and meanwhile, the eating experience of a user is improved; the constraining action of the pushing assembly 20 on the fine dried noodles 50 and the gradual decrease of the height of the step 11 lead the fine dried noodles 50 to be in a general downstream moving trend; in the process of moving the fine dried noodles 50, the fine dried noodles 50 can roll down to the next step 11 step by step under the action of gravity, the effect of separating the noodle puff is improved, and the fine dried noodles 50 on each step 11 are less in noodle puff compared with the fine dried noodles 50 on the previous step 11, and the fine dried noodles 50 on the last step 11 are least in noodle puff. On the one hand, it is convenient to intuitively screen out the dried noodles 50 having the least surface puff adhered to the conveying path 10a; on the other hand, the probability that the dried noodles 50 positioned downstream in the moving direction of the dried noodles are returned to the upstream and re-adhered to the separated flour puff is effectively reduced, thereby improving the efficiency of separating the flour puff from the dried noodles 50.

It will be appreciated that the inlet of the delivery channel 10a is located at the most upstream step 11 or upstream of the most upstream step 11, and the outlet of the delivery channel 10a is located at the most downstream step 11.

For example, referring to fig. 2 and 4, the bottom wall of the end of the conveying channel 10a is provided with a discharge port 10b for discharging the dried noodles 50 and the flour puff, and the discharge port 10b extends in the vertical direction, so that the flour puff and the dried noodles 50 which are separated can naturally fall from the discharge port 10b under the action of gravity to be discharged out of the accommodating box 10 and enter the subsequent process, and the flour puff does not need to be manually taken out of the conveying channel 10a, thereby improving the production efficiency.

It will be appreciated that the edge of the upstream side of the discharge opening 10b is beveled so that the breading and breading 50 can enter the discharge opening 10b under the force of gravity after exiting the last step 11.

The number of steps 11 is not limited, and may be one or more.

It will be appreciated that the top surface 11a of each step 11 may be the same or different in dimension along the direction of travel of the noodles. For example, referring to fig. 4, the top surface 11a of one part of the steps 11 located upstream is larger in size in the direction of noodles movement than the top surface 11a of the other part of the steps 11 located downstream, so that the noodles 50 having more surface flaps adhered thereto located upstream can be moved a longer distance to separate the surface flaps better by friction, thereby improving the separation effect of the surface flaps.

Under the action of gravity, the fine dried noodles 50 are piled on the top surface 11a of the step 11, and the specific structure form of the top surface 11a of the step 11 is beneficial to realizing the separation of the flour puff.

Illustratively, referring to fig. 4 and 5, at least part of the top surface 11a of the step 11 includes an inclined sub-surface 11c and a horizontal sub-surface 11d, the horizontal sub-surface 11d extending in the horizontal direction, the inclined sub-surface 11c being located upstream of the horizontal sub-surface 11d in the direction of fine dried noodles movement and being connected to the side surface 11b of the step 11 of the upper stage, the height of the inclined sub-surface 11c gradually decreasing from upstream to downstream in the direction of fine dried noodles movement.

Under the action of gravity, the fine dried noodles 50 on the inclined sub-surface 11c move to the horizontal sub-surface 11d, on one hand, the fine dried noodles 50 slide and roll in the moving process of the inclined sub-surface 11c, so that the flour puff on the fine dried noodles 50 can fall off under the action of friction force, and the flour puff separation effect is improved; on the other hand, the fine dried noodles 50 on the same step 11 can be more intensively stacked on the horizontal sub-surface 11d, so that the pushing assembly 20 can push more fine dried noodles 50 at the same time, and the flour puff separation effect is further improved.

The dimensions of the horizontal sub-surface 11d and the inclined sub-surface 11c in the direction of the fine dried noodles are not limited, and the ratio of the dimensions of the top surface 11a in the direction of the fine dried noodles is not limited.

Illustratively, in a part of the steps 11 located upstream, the proportion of the dimension of the horizontal sub-surface 11d in the direction of the fine dried noodles moving is smaller than the proportion of the dimension of the inclined sub-surface 11c in the direction of the fine dried noodles moving, and in another part of the steps 11 located downstream, the proportion of the dimension of the horizontal sub-surface 11d in the direction of the fine dried noodles moving is larger than the proportion of the dimension of the inclined sub-surface 11c in the direction of the fine dried noodles moving, so that the fine dried noodles 50 having more sides adhered thereon located upstream can roll on the inclined sub-surface 11c with a longer distance, further improving the effect of the face-to-face separation.

The horizontal sub-surfaces 11d of the steps 11 have substantially the same size along the direction of the fine dried noodles, so that the probability of excessive accumulation of the fine dried noodles 50 on any step 11 is reduced, and the conveying efficiency is improved.

The particular manner in which pushing assembly 20 achieves the restriction of the range of motion of fine dried noodles 50 is not limited.

Illustratively, the pushing assembly 20 includes a push plate 21, the push plate 21 being at least partially positioned in the conveying path 10a in the direction of fine dried noodles movement, a gap 21b being formed between a top surface 11a of the step 11 and a bottom end of the push plate 21 in a vertical direction at intervals for the fine dried noodles 50 to pass through.

During the downstream movement of the fine dried noodles 50, the fine dried noodles 50 located on the upstream side of the push plate 21 can move to the downstream side of the push plate 21 through the gap 21b and accumulate on the downstream side of the push plate 21; during the upstream movement of the noodles 50, the stacked noodles 50 are blocked by the push plate 21 and at least partially cannot move to the upstream side of the push plate 21 through the gap 21b. In this way, the purpose of conveying the fine dried noodles 50 step by step between the steps 11 of each stage under the action of the push plate 21 is achieved.

It will be appreciated that both sides of the push plate 21 along the moving direction of the noodles can collide with the noodles 50 to separate the noodles 50 from the puff.

It will be appreciated that the material forming the inner wall of the housing 10 and the material forming the push plate 21 are both food grade materials, such as food grade 316L stainless steel.

In some embodiments, referring to fig. 2 and 4, the number of push plates 21 is plural, each push plate 21 is disposed at intervals along the moving direction of the noodles, and the noodles 50 reciprocate in separate subchambers of the conveying channel separated by the plurality of push plates 21 and continuously collide with the push plates 21, so as to improve the noodle puff separation efficiency of the noodles 50.

In some embodiments, referring to fig. 4, the number of pushing plates 21 corresponds to the number of steps 11 one by one, so that the noodles 50 on the top surface 11a of each step 11 can be restrained by the pushing plate 21, and the noodle puff separation efficiency of the noodles 50 is improved.

It will be appreciated that the particular configuration of the push plate 21 is advantageous for achieving the separation of the puff.

Illustratively, referring to fig. 4-6, the push plate 21 includes a first push plate 211 and a second push plate 212.

The first push plate 211 includes a straight plate portion 2111 and an arc plate portion 2112, the straight plate portion 2111 extending in the vertical direction, the arc plate portion 2112 being located below the straight plate portion 2111, the arc plate portion 2112 being gradually curved downstream in the direction of fine dried noodles movement from top to bottom.

Referring to fig. 6, in the process of restraining the fine dried noodles 50 from moving, the fine dried noodles 50 blocked by the arc plate portion 2112 are subjected to a force directed obliquely upward, which can be decomposed into an acting component force upward in the vertical direction and an acting component force in the fine dried noodles moving direction, wherein the acting component force upward in the vertical direction causes the fine dried noodles 50 blocked by the arc plate portion 2112 to generate a moving tendency of upward movement; while the noodles 50 blocked by the straight plate portion 2111 are subjected to only the force in the direction of the noodles movement. Therefore, the stacked noodles 50 move upwards to the top continuously in the process of being blocked, and the noodles 50 at the top roll down to the bottom along the moving direction of the noodles, so that the noodles 50 in the process of being blocked continuously roll over and circulate in the moving process, thereby increasing friction among the noodles 50 and playing a better noodle puff separating effect.

The second push plate 212 extends in the vertical direction. That is, the second push plate 212 does not tumble the noodles 50 during the process of restraining the movement of the noodles 50.

It will be appreciated that the arrangement between the first push plate 211 and the second push plate 212 has an effect on the efficiency of the split face puff.

Specifically, referring to fig. 4, the first push plate 211 is disposed upstream of the second push plate 212 along the moving direction of the noodles, so that the noodles 50 with more noodles adhered thereon located upstream can continuously roll and circulate during the moving process, thereby increasing friction between the noodles 50 and achieving a better noodle puff separating effect; while less noodle puff is adhered to the noodles 50 after entering downstream, the movement of the noodles 50 is restricted only by the second push plate 212 to reduce the probability of the noodles 50 breaking due to tumbling.

The specific seating method of the first push plate 211 and the second push plate 212 is not limited, and for example, the second push plate 212 is directly cut from a raw material plate, and the first push plate 211 may be manufactured by bending and reforming the bottom end of the second push plate 212.

In some embodiments, referring to fig. 1, 2 and 4, the top side of the conveying channel 10a is open, and the push plate 21 extends into the conveying channel 10a from the open position of the conveying channel 10a, so that the side wall of the conveying channel 10a can limit the moving range of the fine dried noodles 50, and reduce the probability of the fine dried noodles 50 overflowing from the conveying channel 10a in the moving process; meanwhile, in the moving process of the noodles 50, the moving condition of the noodles 50 and the separating effect of the noodles puff in the conveying channel 10a can be observed from the top side, so that whether the temperatures of material clamping, bonding and the like exist or not can be judged in time, the noodles 50 needing to be subjected to noodle puff separation can be added in time, and the use efficiency of the noodle puff separation device is improved.

The fine dried noodles 50 to be subjected to the puff separation can be continuously put in from the open position above the first step 11.

In some embodiments, referring to fig. 2, the pushing assembly 20 includes a moving sleeve 22, where the moving sleeve 22 is connected to a portion of the pushing plate 21 located outside the conveying channel 10a, that is, the moving sleeve 22 is located completely outside the accommodating box 10, so as to reduce the probability of the moving sleeve 22 contacting the fine dried noodles 50, reduce the probability of the fine dried noodles 50 being broken due to the impact of the moving sleeve 22 on the fine dried noodles 50, and reduce the probability of the fine dried noodles 50 being polluted. The moving sleeve 22 moves reciprocally along the moving direction of the fine dried noodles, the moving sleeve 22 is connected with the containing box 10 to drive all the pushing plates 21 and the containing box 10 to move reciprocally synchronously relative to the moving direction of the fine dried noodles, so that interference between the pushing plates 21 and the containing box 10 is avoided, and the conveying efficiency of the fine dried noodles 50 in the conveying channel 10a is improved.

It will be appreciated that the cross-sectional dimensions of the noodles 50 are different, and therefore the size of the gap 21b needs to accommodate different sizes of noodles 50.

Illustratively, referring to fig. 3, the push plate 21 is provided with a height-adjusting through slot 21a extending in the vertical direction, the height-adjusting through slot 21a penetrates the push plate 21 in the thickness direction of the push plate 21, and a screw penetrates the height-adjusting through slot 21a to be detachably connected with the moving sleeve 22. After the screws are screwed, the edges of the heightening through grooves 21a are clamped between the screws and the moving sleeve 22, so that the position of the push plate 21 along the vertical direction is fixed; after the screws are loosened, the push plate 21 can move up and down along the vertical direction under the constraint of the inner wall of the heightening through groove 21a, so that the size of the gap 21b is adjusted, the size of the gap 21b can meet the size of the section of the fine dried noodles 50 required to be separated, or the number of layers of the fine dried noodles 50 allowed to pass through the gap 21b is adjusted, and the application range of the flour puff separating device is expanded.

The specific number of the height-adjusting grooves 21a is not limited, and may be one or a plurality.

The specific composition of the movement kit 22 is not limited.

As an example, referring to fig. 2 and 3, the moving set 22 includes a moving plate 221, a connecting rod 222 and a plurality of brackets 223, the connecting rod 222 is connected to the push plate 21, the brackets 223 extend in the vertical direction, two ends of the connecting rod 222 are respectively connected to the top end of one bracket 223 so that the connecting rod 222 spans above the accommodating box 10, so that two ends of the connecting rod 222 can be supported by the brackets 223, thereby improving the smoothness of the push plate 21 in the reciprocating process, reducing the probability of damage to the fine dried noodles 50 due to vibration of the push plate 21, and improving the efficiency of face-to-face separation, the bottom end of the bracket 223 is connected to the moving plate 221, and the brackets 223 are connected together by the moving plate 221, thereby achieving the purpose of synchronous movement of the push plate 21. The moving plate 221 is connected to the housing box 10.

It will be appreciated that the removable connection between the mobile plate 221 and the support 223 is provided for subsequent maintenance and replacement. The manner of implementing the detachable connection is not limited, for example, one of the movable plate 221 and the bracket 223 is provided with a through hole 221a, the other is provided with a threaded hole, and the screw passes through the through hole 221a to be connected with the threaded hole in a matching way.

The specific structural form of the connection lever 222 is not limited.

Referring to fig. 3, the connecting rod 222 includes a rod body 2221 and a connecting seat 2222, the rod body 2221 is cylindrical, two ends of the rod body 2221 are respectively connected with the top end of a support 223, the connecting seat 2222 is provided with a through connecting hole and a deformation groove which is communicated with the outside and the connecting hole along the radial direction of the connecting hole, the rod body 2221 is arranged in the connecting hole in a penetrating manner, a screw passes through the push plate 21 and is in threaded connection with the connecting seat 2222, the deformation groove can reduce the structural strength of the connecting hole along the radial direction, the size of the connecting hole is changed by adjusting the tightening degree of the screw, so that the inner wall of the connecting hole is attached to the surface of the rod body 2221, and the position of the connecting seat 2222 on the rod body 2221 is fixed.

The specific placement position of the movable plate 221 is not limited.

Illustratively, referring to fig. 4 and 7, the moving plate 221 is positioned below the accommodating case 10 so as to reduce the floor space of the face-puff separation device, and to improve the compactness of the face-puff separation device, advantageously to improve the fit of the face-puff separation device to the environment.

In some embodiments, referring to fig. 4 and 7, the moving plate 221 is provided with a through hole 221a penetrating in a vertical direction.

In the projection of the fine dried noodles moving direction along the vertical direction, the projection of the discharge opening 10b is located within the projection range of the through hole 221a, so that the flour puff and the fine dried noodles 50 passing through the discharge opening 10b can pass through the through hole 221a without obstruction, the discharging efficiency of the flour puff and the fine dried noodles 50 is improved, and the moving flat plate 221 is prevented from obstructing the falling of the flour puff and the fine dried noodles 50.

It will be appreciated that the face-puff separation device includes a drive assembly 30 for driving movement of the push assembly 20.

In some embodiments, referring to fig. 7, the driving assembly 30 is located below the moving plate 221 and is in driving connection with the driving plate to drive the moving plate 221 to reciprocate along the moving direction of the fine dried noodles. The movable plate 221 can play a certain shielding role on the driving assembly 30 so as to reduce adverse effects of dispersed surface puffs on the movement of the driving assembly 30, prolong the service life, and reduce the occupied area of the surface puffs separating device. By driving the moving plate 221 to move, each support 223 can be uniformly stressed, so that the stability of the process of pushing the fine dried noodles 50 by the push plate 21 is improved. The adoption of the driving component 30 is beneficial to realizing the automatic control of the face-puff separation device, and avoiding the manual direct driving of the movable flat plate 221 to reciprocate.

The specific composition of the drive assembly 30 is not limited.

As an example, referring to fig. 7 and 8, the driving assembly 30 includes a motor 31, a driving lever 32 and an adapter 33, wherein an output end of the motor 31 is fixedly connected with the adapter 33 to drive the adapter 33 to swing, one end of the driving lever 32 is rotatably connected with the adapter 33 and a rotation axis is spaced in parallel with a swing axis of the adapter 33, that is, a portion between a rotation axis position on the adapter 33 and a swing axis position on the adapter 33 forms a link, and the other end is rotatably connected with the pushing assembly 20, thereby achieving the purpose of converting the swing output by the motor 31 into the reciprocating movement of the pushing assembly 20.

It will be appreciated that the axis of rotation of the output of the motor 31, the axis of rotation of the rotational connection of the drive rod 32 to the adapter 33, and the axis of rotation of the rotational connection of the adapter 33 to the push assembly 20 are parallel.

It will be appreciated that different travel ranges of the pusher assembly 20 are required to accommodate different numbers of noodles 50 and sizes of noodles 50 in the conveyor 10a.

For example, referring to fig. 8, the adapter 33 has a disk shape, the output end of the motor 31 is connected to the center of the adapter 33, the adapter 33 is provided with a plurality of first mounting holes 33a in a radial direction, one end of the driving rod 32 is provided with a second mounting hole, and the pin 34 passes through the second mounting hole and alternatively passes through one of the first mounting holes 33a, so that the driving rod 32 is rotatably connected to the adapter 33. In this way, when the pin 34 passes through the different first mounting holes 33a, the lengths of the connecting rods formed between the rotation axis position on the adapter 33 and the swing axis on the adapter 33 are different, and under the condition that the swing angle controlled by the motor 31 is unchanged, the stroke of the reciprocating movement of the pushing assembly 20 is different, so that the application range of the face-puff separating device is enlarged.

In some embodiments, referring to fig. 1, the face-puff separation device further includes a mounting frame 40, a mounting space 40a is provided in the mounting frame 40, a top side of the mounting space 40a is opened, and the accommodating case 10 and at least part of the pushing assembly 20 are disposed in the mounting space 40 a. The mounting bracket 40 provides a mounting location for the housing case 10 and the push assembly 20 and provides some protection.

In some embodiments, referring to fig. 1, the mounting rack 40 includes a plurality of mounting legs 41 and two baffles 42, the mounting legs 41 extend along a vertical direction, the bottom ends of the mounting legs 41 are supported on the ground or other mounting planes, each baffle 42 is connected between the two mounting legs 41, the two baffles 42 are arranged at intervals to enclose and form a mounting space 40a, the motor 31 is arranged on one side of the baffle 42 away from the accommodating box 10, and the situation that the motor 31 is adversely affected by scattered surface-mounted on can be reduced through shielding of the baffles 42, and meanwhile, the motor 31 is convenient to assemble, disassemble and maintain.

In some embodiments, referring to fig. 7, the pushing assembly 20 includes a slider 24 and a guide rail 23, the guide rail 23 is disposed on the mounting frame 40, the slider 24 is fixed at the bottom of the moving plate 221, and the slider 24 is slidably engaged with the guide rail 23, so as to reduce the resistance of the pushing assembly 20 during the moving process and reduce the power consumption.

The various embodiments/implementations provided herein may be combined with one another without conflict.

The foregoing description is only of the preferred embodiments of the present application and is not intended to limit the same, but rather, various modifications and variations can be made by those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principles of the present application should be included in the protection scope of the present application.

Claims (12)

1. A flour puff separator for separating fine dried noodles from flour puffs, the flour puff separator comprising:

the accommodating box is internally provided with a conveying channel for placing the fine dried noodles;

a reciprocally movable pushing assembly coupled to the housing case to drive the housing case to reciprocally move;

the bottom wall of the conveying channel is provided with a plurality of steps along the moving direction of the fine dried noodles, the height of the top surface of each step is gradually reduced, and at least part of the pushing component is arranged in the conveying channel and used for restraining the moving range of at least part of the fine dried noodles in the moving direction of the fine dried noodles.

2. The flour puff separation device of claim 1, wherein at least a portion of the top surface of the step includes an inclined sub-surface and a horizontal sub-surface, the horizontal sub-surface extending in a horizontal direction, the inclined sub-surface being located upstream of the horizontal sub-surface in the direction of noodle travel and connected to a side surface of the step of a previous stage, the height of the inclined sub-surface gradually decreasing from upstream to downstream in the direction of noodle travel.

3. The flour puff separation device of claim 1, wherein the pushing assembly includes a push plate at least partially positioned in the delivery channel, a top surface of the step being vertically spaced from a bottom end of the push plate to form a gap for the fine dried noodles to pass through.

4. A puff separator as claimed in claim 3, wherein the number of push plates is plural, each push plate is disposed at intervals along the direction of travel of the noodles, the push plates include a first push plate including a straight plate portion extending in the vertical direction and an arc plate portion located below the straight plate portion, the arc plate portion is gradually curved from top to bottom toward the downstream of the direction of travel of the noodles, and the second push plate extends in the vertical direction.

5. The puff separation device of claim 4, wherein the first push plate is disposed upstream of the second push plate in the direction of travel of the noodles.

6. A puff separation device according to claim 3, wherein the pushing assembly includes a moving sleeve having an open top side of the transport channel, the push plate extending into the transport channel from the open top side of the transport channel, the moving sleeve being coupled to a portion of the push plate outside the transport channel, the moving sleeve being reciprocally movable in the direction of travel of the noodles, the moving sleeve being coupled to the receiving bin.

7. The dough sheet separating device according to claim 6, wherein the push plate is provided with a height-adjusting through groove extending in the vertical direction, the height-adjusting through groove penetrates through the push plate in the thickness direction of the push plate, and a screw penetrates through the height-adjusting through groove to be detachably connected with the moving sleeve.

8. The dough sheet separating device according to claim 6, wherein the moving sleeve comprises a moving plate, a connecting rod and a plurality of brackets, the connecting rod is connected with the pushing plate, the brackets extend in the vertical direction, two ends of the connecting rod are respectively connected with the top end of one bracket so that the connecting rod spans above the accommodating box, the bottom end of the bracket is connected with the moving plate, and the moving plate is located below the accommodating box and connected with the accommodating box.

9. The flour puff separator as claimed in claim 8, wherein a bottom wall of the end of the conveying passage is provided with a discharge port for discharging the fine dried noodles and the flour puff, the discharge port extends in a vertical direction, the moving plate is provided with a through hole penetrating in the vertical direction, and in a projection in the vertical direction, a projection of the discharge port is located within a projection range of the through hole.

10. The flour puff separation device of claim 8, including a drive assembly positioned below the moving plate and drivingly connected to the moving plate to drive the moving plate to reciprocate in the direction of noodle travel.

11. The dough twist separating device of claim 1, further comprising a drive assembly comprising a motor, a drive rod and an adapter, wherein an output end of the motor is fixedly connected with the adapter to drive the adapter to swing, one end of the drive rod is rotatably connected with the adapter and a rotation axis is spaced in parallel with a swing axis of the adapter, and the other end of the drive rod is rotatably connected with the pushing assembly.

12. The dough sheet separating device of claim 11, wherein the adapter is disc-shaped, the output end of the motor is connected to the center of the adapter, the adapter is provided with a plurality of first mounting holes along the radial direction, one end of the driving rod is provided with a second mounting hole, and a pin passes through the second mounting hole and alternatively passes through one of the first mounting holes, so that the driving rod is rotatably connected with the adapter.