CN216701545U - Snowflake chicken fillet, boneless chicken fillet production line are with carrying whitewashed mechanism - Google Patents

Abstract

The utility model discloses a powder conveying and feeding mechanism for a snowflake chicken fillet and boneless chicken fillet production line, which comprises an upper mesh belt and a lower mesh belt, wherein the upper mesh belt is arranged below the discharge end of the upper mesh belt and above the lower mesh belt; the upper powder mesh belts are arranged at intervals of more than 2, the upper powder mesh belts are arranged obliquely, and the bottom end of the first-stage upper powder mesh belt close to the upper layer mesh belt is obliquely arranged between the upper layer mesh belt and the lower layer mesh belt; the bottom end of the second-stage powdering mesh belt close to the first-stage powdering mesh belt is obliquely arranged between the first-stage powdering mesh belt and the lower-layer mesh belt, so that a product output by the first-stage powdering mesh belt falls onto the second-stage powdering mesh belt. When the mechanism is used for production, the processed product can generate rolling motion, so that the whole body of the product can be uniformly wrapped with flour-wrapping raw materials such as bran and snowflake, adhesion is not easy to generate, the finished product is more attractive, and the yield of the product is improved.

Description

Snowflake chicken fillet, boneless chicken fillet production line are with carrying whitewashed mechanism

Technical Field

The utility model relates to a food processing and finishing device, in particular to a conveying and powdering mechanism for a snowflake chicken fillet and boneless chicken fillet production line.

Background

The existing powdering production line for snowflake chicken fillets and boneless chicken fillets is only provided with an upper layer of mesh belt and a lower layer of mesh belt for pushing flour-coated raw materials such as bread bran and snowflake slices to run, no vibration force is generated in the running process, after the product is placed, the flour-coated raw materials such as the bread bran and the snowflake slices cannot effectively wrap the whole body of the product, adhesion is easy to occur, powdering is not uniform, the yield is low, and the manufactured product is not attractive.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the technical problem of providing a conveying and powdering mechanism for a snowflake chicken fillet and boneless chicken fillet production line, which can enable processed products to generate rolling motion during production, so that the whole bodies of the products can be uniformly wrapped with flour-wrapping raw materials such as bran and snowflake, and the like, adhesion is not easy to generate, the finished products are more attractive, and the yield of the products is improved.

In order to solve the technical problems, the utility model adopts the following technical means:

a powder conveying and feeding mechanism for snowflake chicken fillet and boneless chicken fillet production lines comprises an upper mesh belt, a lower mesh belt and a powder feeding mesh belt, wherein the powder feeding mesh belt is arranged below the discharging end of the upper mesh belt and above the lower mesh belt; the upper powder mesh belts are arranged at intervals of more than 2, the upper powder mesh belts are arranged obliquely, and the bottom end of the first-stage upper powder mesh belt close to the upper layer mesh belt is arranged obliquely between the upper layer mesh belt and the lower layer mesh belt; the bottom end of the second powder feeding mesh belt close to the first powder feeding mesh belt is obliquely arranged between the first powder feeding mesh belt and the lower mesh belt, so that a product output by the first powder feeding mesh belt falls onto the second powder feeding mesh belt.

According to the technical scheme, the powdering net belt is arranged between the upper layer net belt and the lower layer net belt, the bottom end of the powdering net belt close to the upper layer net belt is obliquely arranged between the upper layer net belt and the lower layer net belt so as to be convenient for the powdering net belt to receive processing raw materials conveyed by the upper layer net belt, the powdering net belt drives the powdered snowflake chicken fillet and boneless chicken fillet to obliquely move upwards, and a processed product can bump and roll in the process of moving upwards; because the powdering mesh belts are arranged obliquely and at intervals, the powdering mesh belt close to the upper mesh belt conveys the product to a high position, then the product falls on the next adjacent powdering mesh belt, and the product repeatedly goes upward and is powdered; therefore, the whole body of the product can be uniformly wrapped with flour-wrapping raw materials such as flour-wrapping bran and snowflake, the product is not easy to adhere, the finished product is more attractive, and the product yield is improved.

As a further improvement to the technical scheme:

the three powdering mesh belts are respectively a first-stage powdering mesh belt, a second-stage powdering mesh belt and a third-stage powdering mesh belt.

By arranging the three powdering net belts, the three-time inclined upward powdering and powdering can achieve a better powdering effect.

The powder feeding mesh belt is fixed in the powder feeding cavity through a bearing and a shaft, and the powder feeding mesh belt motor drives the second-stage powder feeding mesh belt to move; the first powder feeding mesh belt and the third powder feeding mesh belt are in transmission connection with the second powder feeding mesh belt, and the second powder feeding mesh belt moves to drive the first powder feeding mesh belt and the third powder feeding mesh belt to move.

Through the arrangement, one powdering mesh belt motor can be used for driving three powdering mesh belts to move, the use of the motor is reduced, the control of equipment is facilitated, and the equipment cost and the size can also be reduced.

The lower mesh belt is provided with a lower mesh belt motor which drives the lower mesh belt; the upper layer mesh belt is in transmission connection with the lower layer mesh belt, and the movement of the lower layer mesh belt drives the upper layer mesh belt to move.

Through the arrangement, the lower-layer mesh belt motor can be utilized to drive the lower-layer mesh belt and the upper-layer mesh belt to move, the use of the motor is reduced, the control of equipment is facilitated, and the equipment cost and the size can also be reduced.

Drawings

FIG. 1 is a schematic view of the apparatus of the present invention.

Description of reference numerals: 1-upper screen belt driven shaft, 2-second level powdering screen belt driving shaft, 3-powdering screen belt, 4-first level powdering screen belt driven shaft, 5-second level powdering screen belt driven shaft, 6-third level powdering screen belt driving shaft, 7-third level powdering screen belt driven shaft, 8-production line cavity, 9-lower layer screen belt driven shaft, 10-lower layer screen belt, 11-lower layer screen belt driving shaft, 12-upper layer screen belt driving shaft, 13-upper layer screen belt, 14-first level powdering screen belt driving shaft.

Detailed Description

The present invention will be further described with reference to the following examples.

Referring to fig. 1, the powder conveying and feeding mechanism for the snowflake chicken fillet and boneless chicken fillet production line comprises an upper mesh belt 13, a lower mesh belt 10 and an upper powder mesh belt 3, wherein the upper mesh belt 13, the lower mesh belt 10 and the upper powder mesh belt 3 are arranged in a production line cavity 8, and the upper powder mesh belt 3 is arranged below the discharging end of the upper mesh belt 13 and above the lower mesh belt 10; the three powdering mesh belts 3 are arranged at intervals, the powdering mesh belts 3 are obliquely arranged, and the bottom end of the first-stage powdering mesh belt close to the upper-layer mesh belt 13 is obliquely arranged between the upper-layer mesh belt 13 and the lower-layer mesh belt 10; the bottom end of a second-stage powdering mesh belt close to the first-stage powdering mesh belt 13 is obliquely arranged between the first-stage powdering mesh belt and the lower-layer mesh belt 10, so that a product output by the first-stage powdering mesh belt falls onto the second-stage powdering mesh belt; the bottom end of the third powder feeding mesh belt is obliquely arranged between the second powder feeding mesh belt and the lower mesh belt 10, so that the product output by the second powder feeding mesh belt falls onto the second powder feeding mesh belt. By the rotation of the first-stage powdering net belt 3, the powdering product sequentially and repeatedly falls on the surfaces of the second-stage powdering net belt and the third-stage powdering net belt, and powder is repeatedly wrapped, so that the powdering of the product is finally uniform.

The upper net belt 13 is provided with an upper net belt driving shaft 12 and an upper net belt driven shaft 1.

The lower mesh belt (10) is provided with a lower mesh belt driven shaft (9) and a lower mesh belt driving shaft (11).

The first powder feeding net belt is provided with a first powder feeding net belt driven shaft 4 and a first powder feeding net belt driving shaft 14.

The second 5-level powdering mesh belt is provided with a second-level powdering mesh belt driven shaft 5 and a second-level powdering mesh belt driving shaft 2.

The third powder feeding net belt is provided with a third powder feeding net belt driven shaft 7 and a third powder feeding net belt driving shaft 6.

The second powder feeding net belt driving shaft 2 is connected with a powder feeding net belt motor to provide power for the second powder feeding net belt, and the second powder feeding net belt driving shaft 2 passes through the second powder feeding net belt. The first-stage powdering mesh belt driving shaft 14 and the third-stage powdering mesh belt driving shaft 6 are in transmission connection with the first-stage powdering mesh belt driving shaft 14 through a chain wheel and a chain, and power is provided by the same powdering mesh belt motor.

Similarly, the upper layer mesh belt 13 and the lower layer mesh belt 10 are driven by a lower layer mesh belt motor simultaneously.

The operation process of the conveying and powdering mechanism for the snowflake chicken fillet and boneless chicken fillet production line is as follows:

the powder feeding device is arranged at one end of the upper layer mesh belt 13 and can receive powder feeding products conveyed by the upper layer mesh belt 13. The powdering mesh belt 3 is composed of three stages of powdering mesh belts; when the upper mesh belt 13 drives one end of a powdering product, the powdering product falls on the surface of the first-stage powdering mesh belt 3, the first-stage powdering mesh belt 3 is driven by the first-stage powdering mesh belt driving shaft 14 to drive upwards, the product rolls under the action of self gravity and the lifting force of the first-stage powdering mesh belt 3, and the product is uniformly wrapped with flour wrapping raw materials such as bran and snowflake.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the scope of the present invention, which is defined in the appended claims.

Claims (4)

1. The utility model provides a snowflake chicken fillet, boneless chicken fillet production line are with carrying whitewashed mechanism, includes upper mesh belt, lower floor's mesh belt and whitewashed mesh belt, its characterized in that: the upper powder mesh belt is arranged below the discharge end of the upper layer mesh belt and above the lower layer mesh belt; the upper powder mesh belts are arranged at intervals of more than 2, the upper powder mesh belts are arranged obliquely, and the bottom end of the first-stage upper powder mesh belt close to the upper layer mesh belt is arranged obliquely between the upper layer mesh belt and the lower layer mesh belt; the bottom end of the second powder feeding mesh belt close to the first powder feeding mesh belt is obliquely arranged between the first powder feeding mesh belt and the lower mesh belt, so that a product output by the first powder feeding mesh belt falls onto the second powder feeding mesh belt.

2. The conveying and powdering mechanism for the snowflake chicken fillet and boneless chicken fillet production line as claimed in claim 1, wherein: the three powdering mesh belts are respectively a first-stage powdering mesh belt, a second-stage powdering mesh belt and a third-stage powdering mesh belt.

3. The conveying and powdering mechanism for the snowflake chicken fillet and boneless chicken fillet production line as claimed in claim 2, wherein: the powder feeding mesh belt is fixed in the powder feeding cavity through a bearing and a shaft, and the powder feeding mesh belt motor drives the second-stage powder feeding mesh belt to move; the first powder feeding mesh belt and the third powder feeding mesh belt are in transmission connection with the second powder feeding mesh belt, and the second powder feeding mesh belt moves to drive the first powder feeding mesh belt and the third powder feeding mesh belt to move.

4. The conveying and powdering mechanism for the snowflake chicken fillet and boneless chicken fillet production line as claimed in claim 1, wherein: the lower mesh belt is provided with a lower mesh belt motor which drives the lower mesh belt; the upper layer mesh belt is in transmission connection with the lower layer mesh belt, and the movement of the lower layer mesh belt drives the upper layer mesh belt to move.

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