CN220343418U - Nutrient cereal cracker processing agency - Google Patents

Abstract

The utility model discloses a processing mechanism of nutritional cereal cracker, comprising an equipment main body, wherein the rear end of the equipment main body is provided with a material extruding mechanism, and the material extruding mechanism comprises a first shell; the novel biscuit extruder is characterized in that an extrusion cylinder is arranged in the first shell, the inner wall of the extrusion cylinder is slidably connected with a piston, the tail end of the piston is connected with a telescopic mechanism, the top end of the extrusion cylinder is respectively provided with a first feed inlet and a second feed inlet, the first feed inlet and the second feed inlet are communicated with a feed box through a guide pipe, the novel biscuit processing technology field is related to, the two feed inlets are formed in the top end of the extrusion cylinder and are connected with the bottom outlet of the feed box through two guide pipes, two feed inlets are formed in the bottom of the extrusion cylinder, the piston is used for respectively extruding and feeding two cavities which are divided by the piston in the extrusion cylinder in the process of moving in the extrusion cylinder, so that the piston can always keep extrusion operation as long as the piston moves in the extrusion cylinder, and thus the extrusion operation is coherent, and the biscuit processing efficiency is improved.

Description

Nutrient cereal cracker processing agency

Technical Field

The utility model relates to the technical field of cracker processing, in particular to a nutrient cereal cracker processing mechanism.

Background

The existing nutrient grain cracker processing mechanism generally adopts the injector principle to extrude biscuit raw materials into the grooves of the mould disc, and after materials in the needle cylinder are extruded, the piston in the needle cylinder needs to move in the opposite direction, so that the needle cylinder is filled with the materials again, and the raw material extrusion mechanism cannot perform extrusion operation when the materials are filled in the needle cylinder, so that the extrusion operation is not consistent, and the biscuit processing efficiency is low.

Disclosure of Invention

The present utility model has been developed in view of the problems associated with the prior art processing of nutritional cereal cracker products.

Therefore, the utility model aims to provide a processing mechanism for nutritional cereal cracker, which solves the problems that the existing processing mechanism for nutritional cereal cracker usually adopts the principle of an injector to extrude biscuit raw materials into a groove of a mould disc, when materials in a needle cylinder are extruded, a piston in the needle cylinder needs to move in the opposite direction, so that the materials are extracted again to fill the needle cylinder, and the extrusion operation of the raw material extrusion mechanism is not continuous because the materials are not extruded when the materials are filled in the needle cylinder, so that the processing efficiency of the biscuit is low.

In order to solve the technical problems, according to one aspect of the present utility model, the following technical solutions are provided:

the processing mechanism of the nutritional cereal cracker comprises an equipment main body, wherein the rear end of the equipment main body is provided with a material extruding mechanism, and the material extruding mechanism comprises a first shell;

the first shell is internally provided with a material extruding cylinder, the inner wall of the material extruding cylinder is connected with a piston in a sliding manner, and the tail end of the piston is connected with a telescopic mechanism;

the top of the extrusion cylinder is provided with a first feeding port and a second feeding port respectively, the first feeding port and the second feeding port are communicated with a feeding box through a guide pipe, and the bottom of the extrusion cylinder is provided with a first feeding port and a second feeding port respectively.

As a preferred embodiment of the present utility model, a nutritional cereal cracker processing facility, wherein: the first feeding port and the second feeding port are connected with a three-way feeding pipe together, and an outlet in the middle of the three-way feeding pipe is connected with an extrusion pipe.

As a preferred embodiment of the present utility model, a nutritional cereal cracker processing facility, wherein: the first feed inlet is connected with the discharge outlet at the bottom of the feed box through a first conduit, and the second feed inlet is connected with the discharge outlet at the bottom of the feed box through a second conduit.

As a preferred embodiment of the present utility model, a nutritional cereal cracker processing facility, wherein: the top of the feed box is provided with a material injection port, and the material injection port extends out of the first shell.

As a preferred embodiment of the present utility model, a nutritional cereal cracker processing facility, wherein: the telescopic mechanism comprises an electric telescopic rod and a piston rod, one end of the electric telescopic rod is detachably connected with the supporting plate, and the other end of the electric telescopic rod is detachably connected with the tail end of the extrusion cylinder;

one end of the piston rod is detachably connected with the supporting plate, and the other end of the piston rod is detachably connected with the piston.

As a preferred embodiment of the present utility model, a nutritional cereal cracker processing facility, wherein: the telescopic mechanism further comprises a stabilizing cylinder, the stabilizing cylinder is arranged at the tail end of the extruding cylinder through a bolt, and the inner wall of the extruding cylinder is connected with a piston rod in a sliding mode.

As a preferred embodiment of the present utility model, a nutritional cereal cracker processing facility, wherein: the support plate is provided with a first support seat and a second support seat, and the first support seat is connected with the electric telescopic rod through a bolt;

the second supporting seat is connected with the piston rod through a bolt.

As a preferred embodiment of the present utility model, a nutritional cereal cracker processing facility, wherein: and a third supporting seat is arranged at the tail end of the extruding cylinder, and the third supporting seat is connected with the electric telescopic rod through a bolt.

Compared with the prior art:

two feeding inlets are formed in the top end of the extrusion charging barrel, the bottom outlet of the feeding box is connected through two guide pipes, two feeding inlets are formed in the bottom of the extrusion charging barrel, the piston is used for respectively extruding and feeding two cavities which are divided by the piston in the extrusion charging barrel in the process of moving in the extrusion charging barrel, so that the piston can always keep extrusion operation as long as moving in the extrusion charging barrel, the extrusion operation is coherent, and the biscuit processing efficiency is improved.

Drawings

FIG. 1 is a schematic diagram of a structure provided by the present utility model;

FIG. 2 is a schematic view of an extrusion mechanism according to the present utility model;

FIG. 3 is a perspective view of a stabilization cartridge provided by the present utility model;

fig. 4 is a cross-sectional view of fig. 2 provided by the present utility model.

In the figure: the device comprises a device body 1, a extrusion head 2, a cylinder 3, a die plate 4, a first shell 100, a feed box 101, a material injection port 102, an extrusion cylinder 103, a first feed port 104, a second feed port 105, a second guide pipe 106, a first guide pipe 107, a piston rod 108, a support plate 109, an electric telescopic rod 110, a stabilizing cylinder 111, a third support seat 112, a first support seat 113, a second support seat 114, a second feed port 115, a first feed port 116, a three-way feed pipe 117, an extrusion pipe 118 and a piston 119.

Description of the embodiments

For the purpose of making the objects, technical solutions and advantages of the present utility model more apparent, embodiments of the present utility model will be described in further detail below with reference to the accompanying drawings.

The utility model provides a processing mechanism of nutrient cereal cracker, please refer to fig. 1-4, including the apparatus main body 1, there are mould disc 4 and support on the apparatus main body 1, mount the cylinder 3 on the support, the cylinder 3 is mounted on support through the bolt, the telescopic link of the cylinder 3 connects the extrusion head 2, the extrusion head 2 locates above the mould disc 4, install the mechanism (these structures can adopt any structure that is mature at present) to drive the mould disc 4 to rotate in the apparatus main body 1, the rear end of the apparatus main body 1 has extrusion mechanisms, the extrusion mechanism includes the first shell 100;

the first shell 100 is internally provided with a material extruding cylinder 103, the inner wall of the material extruding cylinder 103 is connected with a piston 119 in a sliding way, the piston 119 divides the inner cavity of the material extruding cylinder 103 into two inner cavities (a left inner cavity and a right inner cavity), and the tail end of the piston 119 is connected with a telescopic mechanism; a bracket 108 is arranged between the feed box 101 and the extrusion cylinder 103, and the top end and the bottom end of the bracket 108 are respectively connected with the feed box 101 and the extrusion cylinder 103 through bolts;

the top of the extrusion cylinder 103 is provided with a first feeding port 104 and a second feeding port 105 respectively, the extrusion cylinder 103 can enter a right inner cavity and a left inner cavity of the extrusion cylinder 103 respectively through the first feeding port 104 and the second feeding port 105, the first feeding port 104 and the second feeding port 105 are communicated with the feeding box 101 through a guide pipe, the bottom end of the extrusion cylinder 103 is provided with a first feeding port 116 and a second feeding port 115 respectively, valves are arranged on the first feeding port 116 and the second feeding port 115, and biscuit raw materials in the right inner cavity and the left inner cavity of the extrusion cylinder 103 can be extruded through the first feeding port 116 and the second feeding port 115 respectively.

The first feeding port 116 and the second feeding port 115 are connected with a three-way feeding pipe 117 together, and an extrusion pipe 118 is connected with an outlet in the middle of the three-way feeding pipe 117.

The first feed inlet 104 is connected with the discharge outlet at the bottom of the feed box 101 through a first conduit 107, a valve is arranged on the first conduit 107, the second feed inlet 105 is connected with the discharge outlet at the bottom of the feed box 101 through a second conduit 106, and a valve is arranged on the second conduit 106.

The top end of the feed box 101 is provided with a feed port 102, and the feed port 102 extends out of the first housing 100.

The telescopic mechanism comprises an electric telescopic rod 110 and a piston rod 108, one end of the electric telescopic rod 110 is detachably connected with the supporting plate 109, and the other end of the electric telescopic rod is detachably connected with the tail end of the extruding cylinder 103; one end of the piston rod 108 is detachably connected to the support plate 109, and the other end is detachably connected to the piston 119; the telescopic mechanism is located in the second housing 200, the second housing 200 is mounted on the first housing 100 and communicates with the inner cavity of the first housing 100, and the support plate 109 is mounted on the inner wall of the second housing 200.

The telescopic mechanism further comprises a stabilizing cylinder 111, the stabilizing cylinder 111 is arranged at the tail end of the extruding cylinder 103 through bolts, and the inner wall of the extruding cylinder 103 is connected with the piston rod 108 in a sliding manner; under the action of the stabilizing cylinder 111, the piston rod 108 can move more stably, so that the movement of the piston 119 is more stable.

The support plate 109 is provided with a first support seat 113 and a second support seat 114, the inner wall of the second support seat 114 is inserted into the piston rod 108, the inner wall of the first support seat 113 is inserted into the electric telescopic rod 110, and the first support seat 113 is connected with the electric telescopic rod 110 through bolts; the second supporting seat 114 is connected with the piston rod 108 through bolts, so that the second supporting seat 114 and the piston rod 108 are convenient to assemble and disassemble; the second support base 114 realizes the detachable connection of the support plate 109 and the piston rod 108, and the first support base 113 realizes the detachable connection of the electric telescopic rod 110 and the support plate 109, thereby facilitating the disassembly and assembly between the electric telescopic rod 110 and the support plate 109.

The end of the extruding cylinder 103 is provided with a third supporting seat 112, the inner wall of the third supporting seat 112 is inserted with an electric telescopic rod 110, and the third supporting seat 112 is connected with the electric telescopic rod 110 through bolts.

In particular use, as in the state of fig. 4 (where there is material in the left cavity of the inner cavity of the extrusion barrel 103 to the left of the piston 119); opening the valve on the first conduit 107, closing the valve on the second conduit 106, opening the valve on the second feeding port 115, and closing the valve on the first feeding port 116; the electric telescopic rod 110 contracts to drive the piston 119 to move leftwards, raw materials in a left cavity on the left side of the extruding cylinder 103 are extruded into the extruding head 2 through the second feeding port 115, the three-way feeding pipe 117 and the extruding pipe 118, and then are extruded onto the die disc 4, meanwhile, in the process that the piston 119 moves leftwards, negative pressure is formed in a right cavity on the right side of the extruding cylinder 103, and raw materials in the feeding box 101 enter a right cavity on the right side of the extruding cylinder 103 through the first guide pipe 107 and the first feeding port 104; after the raw materials in the left cavity on the left side are extruded, the valve on the first guide pipe 107 is closed, the valve on the second guide pipe 106 is opened, the valve on the second feeding port 115 is closed, the valve on the first feeding port 116 is opened, the electric telescopic rod 110 stretches to drive the piston 119 to move rightwards, at the moment, the raw materials are extruded into the extrusion head 2 through the first feeding port 116, the three-way feeding pipe 117 and the extrusion pipe 118 and then are extruded onto the die plate 4, and the left cavity on the left side forms negative pressure, and the raw materials in the feed tank 101 enter the left cavity of the extrusion cylinder 103 through the second guide pipe 106 and the second feeding port 105, so that the piston 119 can perform extrusion operation only in the moving process.

Although the utility model has been described hereinabove with reference to embodiments, various modifications thereof may be made and equivalents may be substituted for elements thereof without departing from the scope of the utility model. In particular, the features of the disclosed embodiments may be combined with each other in any manner as long as there is no structural conflict, and the exhaustive description of these combinations is not given in this specification merely for the sake of omitting the descriptions and saving resources. Therefore, it is intended that the utility model not be limited to the particular embodiment disclosed, but that the utility model will include all embodiments falling within the scope of the appended claims.

Claims (8)

1. The utility model provides a nutrition cereal cracker processing agency, includes equipment main part (1), and the rear end of equipment main part (1) is equipped with crowded material mechanism, its characterized in that: the extruding mechanism comprises a first shell (100);

a material extruding cylinder (103) is arranged in the first shell (100), the inner wall of the material extruding cylinder (103) is connected with a piston (119) in a sliding manner, and the tail end of the piston (119) is connected with a telescopic mechanism;

the top of the extrusion cylinder (103) is provided with a first feeding port (104) and a second feeding port (105) respectively, the first feeding port (104) and the second feeding port (105) are communicated with the feeding box (101) through a guide pipe, and the bottom of the extrusion cylinder (103) is provided with a first feeding port (116) and a second feeding port (115) respectively.

2. The nutritious cereal cracker processing mechanism of claim 1, wherein the first feeding port (116) and the second feeding port (115) are connected together to a three-way feeding pipe (117), and wherein the outlet in the middle of the three-way feeding pipe (117) is connected to an extrusion pipe (118).

3. A nutritious cereal cracker processing machine according to claim 1 or 2, wherein the first inlet (104) is connected to the outlet at the bottom of the feed box (101) via a first conduit (107), and the second inlet (105) is connected to the outlet at the bottom of the feed box (101) via a second conduit (106).

4. A nutritious cereal cracker processing machine according to claim 3, wherein the top end of the feed box (101) is provided with a filling opening (102), the filling opening (102) extending beyond the first housing (100).

5. A nutritious cereal cracker processing mechanism according to claim 1, wherein the telescopic mechanism comprises an electric telescopic rod (110) and a piston rod (108), wherein one end of the electric telescopic rod (110) is detachably connected to the support plate (109) and the other end is detachably connected to the end of the extrusion cylinder (103);

one end of the piston rod (108) is detachably connected with the supporting plate (109), and the other end of the piston rod is detachably connected with the piston (119).

6. The nutritious cereal cracker processing mechanism of claim 5, wherein the telescoping mechanism further comprises a stabilizing cylinder (111), wherein the stabilizing cylinder (111) is mounted at the end of the extrusion cylinder (103) by bolts, and wherein the inner wall of the extrusion cylinder (103) is slidably connected to the piston rod (108).

7. A nutritious cereal cracker processing machine according to claim 5 or 6, wherein the support plate (109) is provided with a first support seat (113) and a second support seat (114), the first support seat (113) and the electric telescopic rod (110) being connected by means of bolts;

the second supporting seat (114) is connected with the piston rod (108) through bolts.

8. A nutritious cereal cracker processing machine according to claim 1, wherein a third support (112) is mounted at the end of the extrusion cylinder (103), the third support (112) being connected to the electric telescopic rod (110) by means of a screw.