CN110015513B - Material particle cooking device - Google Patents

Abstract

The invention discloses a material particle cooking device, relates to the technical field of material cooking, and mainly aims to reduce the labor intensity of picking materials such as calcium carbide and the like and improve the working efficiency. The main technical scheme of the invention is as follows: the material particle cooking device comprises a body, wherein a material channel is obliquely arranged in the body, the body is provided with a feeding hole communicated with an inlet of the material channel and a discharging hole positioned above an outlet of the material channel, and an installation part for installing a sample bottle is arranged at the feeding hole; the material stirring mechanism is arranged in the material channel and used for stirring materials so as to enable the materials to form a uniform and continuous material flow on the material channel; and the pushing mechanism is arranged at the outlet of the material channel in a liftable manner and is used for intermittently conveying the material falling from the material channel to the discharge hole. The invention is mainly used for cooking irregular material particles.

Description

Material particle cooking device

Technical Field

The invention relates to the technical field of material cooking, in particular to a material particle cooking device.

Background

In the testing process of various industrial products such as ore, coal and the like, the existence of impurities in a sample directly affects the final quality result, so the impurities in the sample need to be picked out before testing.

Taking calcium carbide sample test as an example, the content of silicon iron contained in calcium carbide directly affects the quality of calcium carbide, so before test, silicon iron needs to be sorted out. However, the granularity and the quality of the calcium carbide particles formed by crushing and screening the calcium carbide are not uniform, so that the calcium carbide particles are generally required to be manually sorted for the convenience of sorting silicon iron in the calcium carbide particles by using a sorting device, so that the calcium carbide particles form uniform and continuous calcium carbide flow and sequentially pass through the sorting device, the silicon iron particles can be sorted out, the labor intensity is high, and the working efficiency is low.

Disclosure of Invention

In view of this, the embodiment of the invention provides a material particle processing device, which mainly aims to reduce the labor intensity of calcium carbide and other materials sorting and improve the working efficiency.

In order to achieve the purpose, the invention mainly provides the following technical scheme:

the embodiment of the invention provides a material particle cooking device, which comprises:

the sample bottle feeding device comprises a body, wherein a material channel is obliquely arranged in the body, the body is provided with a feeding hole communicated with an inlet of the material channel and a discharging hole positioned above an outlet of the material channel, and an installation part for installing a sample bottle is arranged at the feeding hole;

the material stirring mechanism is arranged in the material channel and used for stirring materials so as to enable the materials to form a uniform and continuous material flow on the material channel;

and the pushing mechanism is arranged at the outlet of the material channel in a liftable manner and is used for intermittently conveying the material falling from the material channel to the discharge hole.

Further, the material stirring mechanism comprises a pin wheel and a motor, and the pin wheel comprises:

the hub is rotatably connected in the body through a rotating shaft;

the ejector pins are arranged on the outer peripheral surface of the hub in multiple groups, and each group of ejector pins is distributed along the axial direction of the hub;

the output shaft of the motor is connected with one end of the rotating shaft and used for driving the rotating shaft to drive the hub and the ejector pin to rotate, so that the ejector pin uniformly pulls out materials from the feeding hole to the material channel.

Furthermore, the material poking mechanism also comprises an arc-shaped guide plate arranged in the body, one end of the arc-shaped guide plate is arranged at the material inlet, the other end of the arc-shaped guide plate faces the material channel and is provided with a first gap with the material channel, and the cross section of the arc-shaped guide plate is matched with the rotating track of the thimble;

the ejector pin is elastically connected with the hub through an elastic piece;

the ejector pin can be in contact with the arc-shaped guide plate and is in a compressed state in the rotating process until the ejector pin is rotated away from the arc-shaped guide plate and extends out to the first gap, so that the material is uniformly pulled out to the material channel from the first gap by a small amount.

Furthermore, a plurality of first grooves are distributed on the outer peripheral surface of the hub;

each thimble in each group of thimbles is connected with one end of the elastic piece through a connecting plate, and the other end of the elastic piece is connected with the bottom of each first groove;

the pinwheel also comprises a plurality of sealing plates, wherein the inner surface of each sealing plate is provided with a bulge matched with the first groove, a plurality of second grooves are linearly arranged on the bulges, and the bottom of each second groove is provided with a through hole;

the sealing plate is inserted into the first groove through the protrusion, the ejector pin penetrates through the through hole, and the connecting plate and the elastic piece are accommodated in the second groove.

Furthermore, two first openings are symmetrically arranged on two opposite side walls of the body, and two slots are symmetrically arranged on end surfaces of the two opposite side walls;

two ends of the rotating shaft are respectively and rotatably connected into the two first notches;

two ends of the arc-shaped guide plate are respectively connected with an inserting plate matched with the inserting grooves, and the bottom of the inserting plate is provided with a second opening;

the arc-shaped guide plate is inserted into the slot through the inserting plate, and the second opening is rotatably connected with the rotating shaft.

Further, pushing equipment includes drive division, and with drive division is connected and is located the push pedal of material passageway exit, drive division is used for the drive the push pedal carries out the up-and-down motion to will follow the material of material passageway landing is sent to intermittently the discharge gate.

Furthermore, a guide groove arranged along the movement direction of the push plate is arranged in the body;

the push plate is slidably arranged in the guide groove and moves along the guide groove under the driving of the driving part.

Furthermore, the push plate is provided with a material pushing surface which is an inwards concave arc surface;

the discharging opening is obliquely connected with a discharging nozzle, and the inner surface of the discharging nozzle is an arc surface matched with the material pushing surface;

when the driving part drives the push plate to move upwards, the material pushing surface of the push plate is flush with the inner surface of the discharge nozzle.

Further, this material granule cooking device still includes:

the feeding nozzle is connected to the feeding hole and is funnel-shaped;

the guide body is connected to the inlet end of the feeding nozzle, the top surface and the bottom surface of the guide body are both conical surfaces, and a second gap is formed between the guide body and the feeding nozzle;

the installation department set up in the feeding mouth, and work as the sample bottle install in during the installation department, the top surface of baffle can stretch into the sample bottle, the second clearance with the sample bottle intercommunication.

By means of the technical scheme, the invention at least has the following beneficial effects:

according to the material particle cooking device provided by the embodiment of the invention, the material in the sample bottle can slide to the material channel through the feeding hole, and the material shifting mechanism can shift the material, so that the material forms a uniform and continuous material flow on the material channel and is conveyed to the discharging hole through the material pushing mechanism. Moreover, the liftable material pushing mechanism is arranged, so that the materials can be pushed out from the discharge hole according to the picking frequency suitable for the subsequent picking device, the continuous and stable material flow is realized, the material particle amount passing through the picking device at each time is limited, and the subsequent picking work is ensured to be carried out smoothly.

Drawings

Fig. 1 is a schematic structural view of a material particle processing apparatus provided in an embodiment of the present invention at a viewing angle;

FIG. 2 is a schematic view of the main body of FIG. 1;

FIG. 3 is a schematic structural view of the connection between the pin wheel and the motor of the setting mechanism in FIG. 2;

FIG. 4 is a schematic structural view of the closure plate of FIG. 3;

FIG. 5 is a schematic structural view of the body and the arc-shaped guide plate of the kick-out mechanism shown in FIG. 1 after being disassembled;

FIG. 6 is a schematic view of the main body of FIG. 1 from another perspective;

fig. 7 is a schematic structural view of a material particle processing apparatus provided in an embodiment of the present invention at another view angle;

fig. 8 is a schematic structural view of a material particle processing apparatus provided in an embodiment of the present invention at another viewing angle.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention clearer, the technical solutions in the embodiments of the present invention will be described in more detail below with reference to the accompanying drawings in the preferred embodiments of the present invention. In the drawings, the same or similar reference numerals denote the same or similar elements or elements having the same or similar functions throughout. The described embodiments are only some, but not all embodiments of the invention. The embodiments described below with reference to the drawings are illustrative and intended to be illustrative of the invention and are not to be construed as limiting the invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention. Embodiments of the present invention will be described in detail below with reference to the accompanying drawings.

In the description of the present embodiment, it is to be understood that the terms "center", "longitudinal", "lateral", "front", "back", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", etc. indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplicity of description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and therefore, should not be construed as limiting the scope of the present embodiment.

As shown in fig. 1, an embodiment of the present invention provides a material particle cooking device, including a body 1, a material channel 11 arranged obliquely is arranged in the body 1, the body 1 has a feeding port 12 communicated with an inlet of the material channel 11 and a discharging port 13 located above an outlet of the material channel 11, a mounting portion 13 for mounting a sample bottle is arranged at the feeding port 12; the material stirring mechanism 2 is arranged in the material channel 11 and used for stirring materials so as to enable the materials to form uniform and continuous material flow on the material channel 11; the pushing mechanism 3 is arranged at the outlet of the material channel 11 in a lifting manner and is used for intermittently delivering the material sliding down from the material channel 11 to the discharge hole 13. Wherein reference numeral "10" in FIG. 1 denotes a sample bottle.

The material particle cooking device is mainly used for cooking irregular material particles such as calcium carbide and the like, wherein a feed port 12 can be positioned on the top surface of a body 1, a discharge port 13 can be positioned on the side surface of the body 1, a material channel 11 can be a channel which is inclined downwards and extends to the discharge port 13 based on the feed port 12, moreover, the number of the material channels 11 can be a plurality of channels which are arranged side by side, and a plurality of discharge ports 13 can be correspondingly arranged, when a sample bottle is installed on an installation part 13, specifically, the sample bottle can be installed on the installation part 13 in an inverted mode and is communicated with the feed port 12, so that the material flows into the feed port 12 under the action of gravity and slides in each inclined material channel; the material shifting mechanism 2 is arranged in the material channels 11, and specifically can be arranged at a position close to the material inlet 12, and a material shifting mechanism 2 can be arranged in each material channel 11, when the material slides to the corresponding material channel 11 from the material inlet 12, the material shifting mechanism 2 can be started to shift the material, so that the material forms uniform and continuous material flow on the material channel 11, and the material pushing mechanism 3 can also be respectively arranged at the outlet of each material channel 11, is used for receiving the material sliding from the material channel 11 when descending, and pushes the part of the material to the material outlet 13 when ascending, thereby limiting the material particle amount passing through the picking device each time, and ensuring the smooth operation of subsequent picking work.

In an optional embodiment, the material particle cooking device may further include a controller electrically connected to the material shifting mechanism 2 and the material pushing mechanism 3, respectively, and the controller controls the material shifting mechanism 2 to shift the material and the material pushing mechanism 3 to perform a lifting motion, so that the material shifting mechanism 2 and the material pushing mechanism 3 automatically perform an intermittent motion.

According to the material particle cooking device provided by the embodiment of the invention, the material in the sample bottle can slide to the material channel through the feeding hole, and the material shifting mechanism can shift the material, so that the material forms a uniform and continuous material flow on the material channel and is conveyed to the discharging hole through the material pushing mechanism. Moreover, the liftable material pushing mechanism is arranged, so that the materials can be pushed out from the discharge hole according to the picking frequency suitable for the subsequent picking device, the continuous and stable material flow is realized, the material particle amount passing through the picking device at each time is limited, and the subsequent picking work is ensured to be carried out smoothly.

In order to achieve the material stirring and form a uniform and continuous material flow on the material channel 11, in an alternative embodiment, referring to fig. 2 and fig. 3, and in conjunction with fig. 1, the material stirring mechanism 2 may include a pin wheel 21 and a motor 22, the pin wheel 21 may include a hub 211, and the hub 211 is rotatably connected in the body 1 through a rotating shaft; the plurality of ejector pins 212 are arranged on the outer peripheral surface of the hub 211 in multiple groups, and each group of ejector pins 212 is arranged along the axial direction of the hub 211; an output shaft of the motor 22 is connected to one end of the rotating shaft, and is used for driving the rotating shaft to drive the hub 211 and the ejector pins 212 to rotate, so that the ejector pins 212 uniformly pull out the material from the feeding hole 12 to the material channel 11. When the motor 22 drives the rotating shaft to rotate, the hub 211 drives each thimble 212 to rotate, and the rotating thimble 212 stirs the material, so that the material is uniformly stirred out from the feeding hole 12 to the material channel 11 to form a material flow.

Further, in an alternative embodiment, referring to fig. 2 in combination with fig. 1, the material pushing mechanism 2 may further include an arc-shaped guide plate 23 disposed in the body 1, one end of the arc-shaped guide plate 23 is disposed at the material inlet 12, the other end of the arc-shaped guide plate 23 faces the material passage 11 and has a first gap 24 with the material passage 11, and a cross-sectional shape of the arc-shaped guide plate 23 is adapted to a rotation track of the thimble 212; thimble 212 may be elastically connected with hub 211 by elastic member 213; the thimble 212 can contact the arc-shaped guide plate 23 and be in a compressed state during the rotation process until the thimble is rotated away from the arc-shaped guide plate 23 and extends out to the first gap 24, so that the material can be uniformly pulled out from the first gap 24 to the material channel 11 by a small amount.

According to the above embodiment, by providing the arc-shaped guide plate 23 and elastically connecting the ejector pins 212 with the hub 211, the ejector pins 212 on the pin wheel 21 can rotate along the arc-shaped guide plate 23 and extend out of the first gap 24 when the arc-shaped guide plate 23 is unscrewed, so as to be inserted into the material flow gap or push against the material particles, and then a small amount of material particles are shifted out from the first gap 24 and slide down to the pushing mechanism, so that a small amount of material channels in sequence are ensured, and the material channels are not blocked and not blocked.

In an alternative embodiment, referring to fig. 3 and 4, a plurality of first grooves 2111 may be arranged on the outer circumferential surface of the hub 211 of the pinwheel 21; each of the needles 212 in each set of needles 212 is connected to one end of the elastic member 213 through a connecting plate 2121, and the other end of the elastic member 213 is connected to the bottom of each first groove 2111; the pinwheel 21 may further include a plurality of sealing plates 214, wherein a protrusion 2141 matched with the first groove 2111 is disposed on an inner surface of each sealing plate 214, a plurality of second grooves 2142 are linearly arranged on the protrusion 2141, and a through hole 2143 is disposed at a bottom of each second groove 2142; the sealing plate 214 is inserted into the first groove 2111 through the protrusion 2141, the thimble 212 passes through the through hole 2143, and the connecting plate 2121 and the elastic element 213 are accommodated in the second groove 2142, such a structural design can enable the sealing plate 214 to seal the connecting plate 2121 and the elastic element 213 of the thimble 212 in the first groove 2111, thereby ensuring reliable connection between the thimble 212 and the elastic element 213, guiding the thimble 212 to compress the elastic element 213 through the connecting plate 2121, effectively preventing the thimble 212 from being removed, and ensuring normal operation of the material shifting mechanism 2. Wherein, the elastic member 213 may be a spring.

In an alternative embodiment, referring to fig. 5 in combination with fig. 2, two first gaps 14 may be symmetrically disposed on two opposite sidewalls of the body 1, and two slots 15 are symmetrically disposed on end surfaces of the two opposite sidewalls; two ends of the rotating shaft are respectively and rotatably connected in the two first gaps 14; the two ends of the arc-shaped guide plate 23 are respectively connected with an inserting plate 231 matched with the slot 15, and the bottom of the inserting plate 231 is provided with a second notch 2311; the arc-shaped guide plate 23 is inserted into the slot 15 through the insertion plate 231, and the second notch 2311 is rotatably connected with the rotating shaft. The bottoms of the first notch 14 and the second notch 2311 can be arc-shaped; also, the cross-sectional shape of the insert plate 231 may be L-shaped.

According to the above embodiment, through designing arc baffle 23 to be connected through picture peg 231 and slot 15 interpolation on the body 1, moreover, the pivot of pinwheel 21 is fixed a position through first opening 14 and second opening 2311, make arc baffle 23 be connected for dismantling with body 1, pinwheel 21 is connected for dismantling with body 1, after this cooking device uses for a long time, can extract arc baffle 23, and take out pinwheel 21 from first opening 14, realize the clearance to pinwheel 21, arc baffle 23 and body 1, after the clearance, again assemble pinwheel 21 and arc baffle 23 in proper order, can put into use, it is more convenient to use, and convenient to assemble.

In order to achieve the simplicity of the structure and the reliability of the use, in an alternative embodiment, referring to fig. 6 and combining fig. 1 and fig. 2, the pushing mechanism 3 may include a driving portion 31 and a pushing plate 32 connected to the driving portion 31 and located at the outlet of the material channel 11, where the driving portion 31 is used to drive the pushing plate 32 to move up and down to intermittently deliver the material sliding down from the material channel 11 to the discharge port 13. That is to say, when the driving portion 31 drives the push plate 32 to move downwards, the material on the material channel 11 can slide down onto the push plate 32, and when the driving portion 31 drives the push plate 32 to move upwards, the push plate 32 moves upwards to be communicated with the material outlet 13, so that the material is intermittently pushed out of the material outlet 13, the material is pushed out according to the frequency of the subsequent picking device, and the smooth operation of the picking work is ensured.

In the above embodiment, the distance that the pushing plate 32 moves up and down (the length of the pushing plate 32) can be designed according to the particle size of the material particles, so that only the material meeting the requirement of a certain particle size is sent to the discharge port 13 in the rising process of the pushing plate 32 at each time, the material meeting the requirement of a certain particle size is discharged from the discharge port 13, and the smooth proceeding of the picking work of the subsequent picking device is further ensured. Specifically, the driving portion 31 may be a cam mechanism driven by a motor, that is, the motor 312 drives the cam 311 to rotate, the rotating cam 311 pushes the pushing plate 32 to perform an ascending and descending motion, and the operating frequency of the cam mechanism may be set according to the picking frequency of the subsequent picking device.

In an alternative embodiment, referring to fig. 6 in combination with fig. 1, the body 1 may be provided with guide grooves 15 arranged along the moving direction of the push plates 32, and of course, the number of the guide grooves 15 may be the same as that of the push plates 32, and the push plates 32 may be slidably disposed in the guide grooves 15 and moved along the guide grooves 15 by the driving of the driving portion 31. Specifically, the push plate 32 is driven by the cam to move up and down in the guide groove 15, so that the guide groove 15 plays a role in guiding the up and down movement of the push plate 32, and the normal pushing work of the push plate 32 is ensured.

In order to facilitate the pushing plate 32 of the pushing mechanism 3 to push the material to the discharging opening 13, in an alternative embodiment, referring to fig. 2 in combination with fig. 1, the pushing plate 32 may have a pushing surface 321, and the pushing surface 321 may be an inward concave arc surface; the discharge port 13 can be connected with a discharge nozzle 131 in an inclined manner, the inclined direction of the discharge nozzle 131 is the same as that of the material channel 11, and the inner surface of the discharge nozzle 131 is an arc-shaped surface matched with the material pushing surface 321; when the driving portion 31 drives the push plate 32 to move upward, the pushing surface 321 of the push plate 32 is flush with the inner surface of the discharging nozzle 131. The inner surfaces of the pushing surface 321 and the discharging nozzle 131 of the pushing plate 32 are designed to be concave arc surfaces, so that the materials entering the pushing plate 32 can be completely pushed out of the discharging nozzle 131 and cannot be scattered; moreover, when the pushing plate 32 rises, the pushing surface 321 of the pushing plate 32 is flush with the inner surface of the discharging nozzle 131, so that the material is further ensured to be completely pushed out, the clamping stagnation phenomenon cannot occur, and the pushing plate 32 of the pushing mechanism 3 is convenient to push the material to the discharging port 13.

In an alternative embodiment, referring to fig. 7 and 8 in combination with fig. 1, the material particle cooking device may further include a feeding nozzle 4, wherein the feeding nozzle 4 is connected to the feeding hole 12 and is funnel-shaped; the guide body 5 is connected to the inlet end of the feeding nozzle 4 and can be connected with the feeding nozzle 4 through connecting rods arranged at intervals, the top surface and the bottom surface of the guide body 5 are both conical surfaces, and a second gap 51 is formed between the guide body 5 and the feeding nozzle 4; the mounting portion 13 is disposed on the feeding nozzle 4, and when the sample bottle is mounted on the mounting portion 13, the top surface of the flow guiding body 5 can extend into the mouth of the sample bottle, and the second gap 51 is communicated with the sample bottle.

In the above embodiment, the feeding mouth 4 is a funnel-shaped structure, the flow guide body 5 is a structure in which the top surface and the bottom surface are both conical surfaces, and the second gap 51 is provided between the flow guide body 5 and the feeding mouth 4, it is realized that after the sample bottle is installed in the installation portion 13, a flow distribution channel and a flow guide channel are sequentially formed between the bottle opening of the sample bottle and the top surface of the flow guide body 5, between the second gap 51 and the bottom surface of the flow guide body 5 and the feeding mouth 4, so that the material can uniformly slide down through the flow distribution channel and the flow guide channel sequentially, which is convenient for the subsequent material shifting mechanism 2 to shift out the material uniformly in a small amount, and the material pushing mechanism 3 pushes out the material meeting the requirement.

In an alternative embodiment, referring to fig. 8, the mounting portion 13 may be a ring-shaped structure disposed on the inlet end face of the feeding nozzle 4 and adapted to the mouth of the sample bottle, and a screw thread adapted to the sample bottle may be disposed on the wall of the ring-shaped structure.

This material granule cooking device's specific working process can be: the sample bottle can be conveyed to a designated position by a conveying belt and then is overturned and mounted on the mounting part 13 of the sample bottle, material particles fall out of the sample bottle, are shunted by the top surface of the flow guide body 5 and the second gap 51, slide down under the flow guide effect of the space between the bottom surface of the flow guide body 5 and the discharge nozzle 131, and intensively fall to the inlet end of the material channel 11 under the guide effect of the arc-shaped guide plate 23, and continue to slide down along the material channel 11, the needle wheel 21 of the material poking mechanism 2 rotates clockwise under the drive of the motor, the thimble 212 starts to be compressed when passing through the arc-shaped guide plate 23, the thimble 212 is ejected to the first gap 24 under the action of the spring when rotating out of the guide plate, so as to be inserted into the material flow gap or eject onto the material particles, then a small amount of the material particles are poked out from the first gap 24 to slide down to the material pushing surface 321 of the push plate 32 in the material pushing mechanism 3 along with the rotation of the first gap, and the cam mechanism in the material pushing And the push plate 32 is driven to move up and down, the length of the push plate 32 can be designed according to the particle size of the material, and only the material meeting the requirement of certain particle size is discharged from the discharge port 13 in the process that the push plate 32 rises every time, so that the material meeting the requirement of certain particle size is pushed out according to the frequency suitable for the subsequent picking device, and the smooth operation of the picking work is ensured.

Finally, it should be noted that: the above examples are only intended to illustrate the technical solution of the present invention, but not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; and such modifications or substitutions do not depart from the spirit and scope of the corresponding technical solutions of the embodiments of the present invention.

Claims (8)

1. A material particle cooking device is characterized by comprising:

the sample bottle feeding device comprises a body, wherein a material channel is obliquely arranged in the body, the body is provided with a feeding hole communicated with an inlet of the material channel and a discharging hole positioned above an outlet of the material channel, and an installation part for installing a sample bottle is arranged at the feeding hole;

the material stirring mechanism is arranged in the material channel and used for stirring materials so as to enable the materials to form a uniform and continuous material flow on the material channel;

the pushing mechanism is arranged at the outlet of the material channel in a lifting manner and is used for intermittently conveying the material falling from the material channel to the discharge hole;

the kickoff constructs including the pinwheel, the pinwheel includes:

the hub is rotatably connected in the body through a rotating shaft;

the ejector pins are arranged on the outer peripheral surface of the hub in multiple groups, and each group of ejector pins is distributed along the axial direction of the hub;

the material poking mechanism further comprises an arc-shaped guide plate arranged in the body, one end of the arc-shaped guide plate is arranged at the material inlet, the other end of the arc-shaped guide plate faces the material channel and is provided with a first gap with the material channel, and the shape of the cross section of the arc-shaped guide plate is matched with the rotating track of the thimble;

the ejector pin is elastically connected with the hub through an elastic piece;

the ejector pin can be in contact with the arc-shaped guide plate and is in a compressed state in the rotating process until the ejector pin is rotated away from the arc-shaped guide plate and extends out to the first gap, so that the material is uniformly pulled out to the material channel from the first gap by a small amount.

2. The material particle cooking device according to claim 1, wherein the material-stirring mechanism includes a motor;

the output shaft of the motor is connected with one end of the rotating shaft and used for driving the rotating shaft to drive the hub and the ejector pin to rotate, so that the ejector pin uniformly pulls out materials from the feeding hole to the material channel.

3. Material particle cooking device according to claim 1,

a plurality of first grooves are distributed on the peripheral surface of the hub;

each thimble in each group of thimbles is connected with one end of the elastic piece through a connecting plate, and the other end of the elastic piece is connected with the bottom of each first groove;

the pinwheel also comprises a plurality of sealing plates, wherein the inner surface of each sealing plate is provided with a bulge matched with the first groove, a plurality of second grooves are linearly arranged on the bulges, and the bottom of each second groove is provided with a through hole;

the sealing plate is inserted into the first groove through the protrusion, the ejector pin penetrates through the through hole, and the connecting plate and the elastic piece are accommodated in the second groove.

4. Material particle cooking device according to claim 1,

two first openings are symmetrically arranged on two opposite side walls of the body, and two slots are symmetrically arranged on the end surfaces of the two opposite side walls;

two ends of the rotating shaft are respectively and rotatably connected into the two first notches;

two ends of the arc-shaped guide plate are respectively connected with an inserting plate matched with the inserting grooves, and the bottom of the inserting plate is provided with a second opening;

the arc-shaped guide plate is inserted into the slot through the inserting plate, and the second opening is rotatably connected with the rotating shaft.

5. Material particle cooking device according to claim 1,

the pushing equipment includes the drive division, and with the drive division is connected and is located the push pedal of material passageway exit, the drive division is used for the drive the push pedal carries out the up-and-down motion to will follow the material of landing on the material passageway is delivered to intermittently the discharge gate.

6. Material particle cooking device according to claim 5,

the body is internally provided with a guide groove arranged along the motion direction of the push plate;

the push plate is slidably arranged in the guide groove and moves along the guide groove under the driving of the driving part.

7. Material particle cooking device according to claim 5,

the push plate is provided with a material pushing surface which is an inwards concave arc surface;

the discharging opening is obliquely connected with a discharging nozzle, and the inner surface of the discharging nozzle is an arc surface matched with the material pushing surface;

when the driving part drives the push plate to move upwards, the material pushing surface of the push plate is flush with the inner surface of the discharge nozzle.

8. The material particle cooking device according to claim 1, further comprising:

the feeding nozzle is connected to the feeding hole and is funnel-shaped;

the guide body is connected to the inlet end of the feeding nozzle, the top surface and the bottom surface of the guide body are both conical surfaces, and a second gap is formed between the guide body and the feeding nozzle;

the installation department set up in the feeding mouth, and work as the sample bottle install in during the installation department, the top surface of baffle can stretch into the sample bottle, the second clearance with the sample bottle intercommunication.

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