TWM536094U - Grain processing device and automatic system for determining grain quality - Google Patents

Abstract

A grain processing device and an automatic system for determining grain quality are provided. The automatic system for determining grain quality comprises the grain processing device, a set of weight measuring devices and a control module. The grain processing device has a first sheller, a first shell transmission structure and a particle collector. A plurality of grants is processed by the sheller to generate a plurality of first shells and a plurality of particles. The first shells and the dust are transferred by the first shell transmission structure and then the particles are collected by the particle collector. The set of the weight measuring devices measures weights of the first shells and the grants. The control module receives and analyzes the weight signals to obtain quantitative indicators of grain quality automatically.

Description

Grain processing equipment and grain quality inspection system

The present invention relates to a grain processing apparatus, and more particularly to a grain processing apparatus including a dust collecting apparatus for collecting dust generated by a grain processing process, and the grain processing apparatus can be used for a grain quality detecting system .

Taking rice processing as an example, in the processing process, the rice is first shelled, and the rice husks and rice bran are removed in order to obtain white rice, and then the white rice is screened for quality. White rice, large broken rice and small broken rice. However, in the process of shelling, a large amount of dust is generated and flew in the air at the same time, and the operator is exposed to an environment with a large amount of dust for a long time, which will have an undue influence on his health. Furthermore, in order to confirm the quality of rice, the weight of rough rice, rice bran, first-class white rice, large broken rice and small broken rice and the percentage of total grain weight are usually calculated to obtain a quantitative index. However, the dust weight may be This causes errors in the measurement of the weight of the rough and rice bran.

In view of this, the present invention provides a grain processing device and a grain quality detecting system capable of efficiently collecting dust, and has great demand and development potential in this industry.

One of the main purposes of the present invention is to provide a grain processing apparatus and a grain quality detecting system comprising the grain processing apparatus, the grain processing apparatus being provided with a dust collecting device for collecting dust generated when processing the grain, so that the grain quality detecting system can Calculate the quality of the grain more accurately.

To achieve the above object, the present invention discloses a grain processing apparatus and a grain quality detecting system comprising the grain processing apparatus, a weight measuring apparatus group and a control module. The grain processing apparatus has a first shelling machine, a first housing conveying structure, and a dust collecting device. The first sheller separates the plurality of first shells of the plurality of grains from the plurality of bodies of the grains while producing a plurality of first dusts. The first housing conveying structure is connected to the first shelling machine, and the first housing conveying structure has a first output tube, a first conduit and a first casing container, which are sequentially connected, the first output The first duct and the first casing container extend along a second axial direction, and the first casings sequentially pass through the first output pipe from the first shelling machine and After the first conduit is received in the first casing container. The dust collecting device is connected to the first duct, and the dust collecting device has a dust collecting structure and a dust collecting container. After the dust enters the first duct through the first output tube, the dust collecting structure attracts the first duct The dust in the dust is directed to the dust collecting container. The weight measuring device group respectively measures the weights of the first housing, the second housings and the bodies, and generates signals corresponding thereto; the control module is configured to receive the weight measuring device group The signal is obtained.

The weight measuring device set includes a first weight measuring device disposed at a bottom of one of the first casing containers or suspended from an outer side wall of the first conduit, and a second weight measuring device disposed in the second casing container One of the bottoms is suspended from an outer side wall of the second conduit.

In one embodiment, the processed grains are rice, the first shells are rough, the second shells are rice bran, and the bodies are white rice.

In an embodiment, the grain quality detecting system further comprises a vibrating screen rice machine, wherein the white rice is screened to produce a plurality of first-class white rice, a plurality of large broken rice and a plurality of small broken rice, and the weighing device group respectively measures the Wait for the white rice, the large broken rice and the weight of the small broken rice.

Preferably, the grain quality detecting system further comprises a base, and the grain processing device, the weight measuring device set, the control module and the vibrating screen machine are disposed on the base. And the control module is connected to a cloud server.

In one embodiment, the grain processing apparatus further includes a second shelling machine and a second shell conveying structure connected to the second shelling machine, wherein the second shell conveying structure has one of sequential connections a second output tube, a second tube and a second housing container, the second output tube extends along a third axial direction, and the second tube and the second housing container extend along a fourth axis. The second shelling machine separates the plurality of second shells of the grains from the bodies of the grains, and the second shells sequentially pass through the second output tube and the second tube from the second shelling machine. It is placed in the second casing container.

The first output tube is connected to one side of the first duct along a line direction of the first duct to communicate with the first duct, and the dust collecting structure is disposed at the top of one of the first ducts and the first The conduit is in communication, and the dust collecting container is disposed at a bottom of one of the first conduits to communicate with the first conduit.

The second output tube is disposed on a side of the second conduit along a direction of the second conduit to communicate with the second conduit, and the second casing is disposed at a bottom of the second conduit Communicating with the second conduit.

The first housing conveying structure has a first air blower, and the second housing conveying structure has a second air blower, and the wind flow generated by the first air blower and the second air blower respectively passes through the first output tube and the second After the output tube, a cyclone guiding airflow is formed in the first conduit and the second conduit to respectively transport the first housing and the second housing to the first conduit and the second conduit.

In another embodiment of the present invention, the dust collecting device is integrally disposed on the top of the first conduit.

The cyclone guiding airflow in the first conduit is axially flowed by the second axis, and a suction airflow in the first conduit is generated by the vacuuming structure, and the suction airflow flows along the second axis The cyclone-directed airflow in the second conduit is axially flowed by the fourth axis, and a suction airflow in the second conduit is generated by the vacuuming structure along the fourth axis flow.

The above objects, technical features, and advantages will be more apparent from the following description.

As shown in Fig. 1 and Fig. 2, the grain quality detecting system 1 of the present invention is a perspective view of different angles of view. The grain quality detecting system 1 comprises a grain processing device 2, a weighing device group 3, and a vibrating sieve machine. 4. A control module 5 and a base 6. In this embodiment, the quality of the rice is processed and calculated. The rice R has a second shell which is white rice, coated with white rice, and a first shell R1 which is covered with the second shell. . In other embodiments of the present invention, the grain processing apparatus 2 and the grain quality detecting system 1 can be used to process various types of cereals and to detect the quality of various cereals, which are not described herein.

Wherein, since the grain quality detecting system 1 includes a plurality of different devices, in order to facilitate the simultaneous transportation of the devices, the grain processing device 2, the weighing device group 3, the vibrating screen rice machine 4, and the control module 5 are all disposed on the base. In this way, a plurality of devices provided on the susceptor 6 can be simultaneously moved by only moving the susceptor 6, so that the time for transporting and assembling the grain quality detecting system 1 can be saved.

FIG. 3 is a schematic plan view showing the layout of the created grain quality detecting system 1. The third drawing is only used to illustrate the embodiment, that is, the size, proportion, distribution area of each component and the figure are shown. The structure is not limited by the drawing. In the present embodiment, after the rice R is poured into the grain processing device 2, the grain processing device 2 and the vibrating sieve rice machine 4 sequentially process and classify the rice R, and the weighing device group 3 measures the first shell after classification. After the weight of the body R1, the second shell and the white rice, and the total weight of the rice R, the control module 5 receives the weight data and starts the calculation to obtain a rice quality quantitative index.

First, the detailed structure of the grain processing apparatus 2 will be described. As shown in FIGS. 1 to 3, the grain processing apparatus 2 has a first shelling machine 21, a first casing conveying structure 22, and a second shelling machine. 24. A second housing transport structure 25 and a dust collecting device 23. The first sheller 21 is coupled to the first housing transport structure 22, and the second sheller 24 is coupled to the second housing transport structure 25. The first housing conveying structure 22 has a first blower 224 and a first output tube 221, a first conduit 222 and a first header container 223. The first output tube 221 is along a first axial direction. X1 extends, the first conduit 222 and the first casing container 223 extend along a second axial direction Y1, and the first axial direction X1 and the second axial direction Y1 are perpendicular to each other, as shown in FIG. 4 is the first output pipe 221 The first outlet tube 221 is connected to the side surface 222a of the first conduit 222 along the line direction of the first conduit 222, and the first header container 223 is disposed on the first conduit 222. A bottom 222c.

The second housing transport structure 25 is substantially the same as the first housing transport structure 22, and has a second blower 254 and a second output tube 251, a second conduit 252, and a second header container 253. The second output tube 251 extends along the third axial direction X2, and the second conduit 252 and the second housing container 253 extend along the fourth axial direction Y2, wherein the third axial direction X2 and the fourth axial direction Y2 are perpendicular to each other, and the second The output tube 251 is connected to the side surface 252a (not shown) of the second duct 252 along the line direction of the second duct 252, and the second casing container 253 is disposed at the bottom 252c of the second duct 252.

4 and 5 are schematic views of the first output pipe 221 and the first conduit 222, respectively. After the wind flow W generated by the first blower 224 passes through the first output pipe 221, the cyclone guiding airflow W1 is generated in the first conduit 222, that is, the wind flow W located in the first output pipe 221 flows along the first axis X1. The cyclone-directed airflow W1 located in the first duct 222 flows in the center of the second axis Y1.

Since the airflow in the second casing conveying structure 25 is the same as that of the first casing conveying structure 22, a schematic diagram is not shown. The wind flow W generated by the second blower 254 passes through the second output pipe and passes through the second conduit 252 to generate the cyclone-directed airflow W1, that is, the wind flow W located in the second output pipe 251 flows along the third axis X2. The cyclone-directed airflow W1 located in the second duct 252 flows axially about the fourth axis Y2.

The dust collecting device 23 has a dust collecting structure 231 and a dust collecting container 232. The dust collecting structure 231 has two suction tube bodies 231a disposed on a top portion 222c of the first duct 222 and a top portion 252b of the second duct 252, respectively. A set of shell containers 223 and second header containers 253 are opposite to each other, and generate a suction airflow W2 along the second axis Y1 (as shown in FIG. 5), and also generate a suction airflow W2 on the fourth axis Y2 (Fig. Not shown).

After the rice R is poured into the grain processing device 2, the grain processing device 2 first screens the immature or sick rice (commonly known as chip rice) by a wind-selective filtration method and collects the container 26 from the chip, and then the first The sheller 21 then removes the plurality of coarse grains of the remaining plurality of rice grains from the white rice of the rice grains R, and simultaneously produces a large amount of the first dust P1. The wind flow generated by the first blower 224 guides the rough (first housing R1) and the first dust P1 to the first output pipe 221, and then the wind flow W passes through the first conduit 222 to become a cyclone guide. The air flow W1 is driven to drive the rough (first housing R1) and the first dust P1 to the first conduit 222, wherein the weight of the rough (first housing R1) is heavier than the first dust P1 Therefore, through the first conduit 222, the rough (first housing R1) will be located at the periphery of the airflow, as shown in FIG. 4, and the lighter first dust P1 will be located at the center of the airflow. That is, the first dust P1 flows closer to the second axis Y1. Finally, the rough is guided by the cyclone-guided airflow W1 and its own weight, and falls into the first casing container 223. When the first dust P1 passes through the first conduit 222, it is guided by the suction airflow W2. Along the second axis Y1, it falls into the dust collecting container 232 through the suction tube body 231a. It should be noted that the positional distributions of the rough (first casing R1) and the first dust P1 of FIGS. 4 and 5 are only for illustrative purposes, and the rough (first casing R1) And the distribution pattern of the first dust P1 is not limited thereto.

After the rough shelling operation, the rice R becomes a brown rice containing both rice bran (second shell) and white rice, the brown rice passes through the second sheller 24, and the second sheller 24 grinds the brown rice by grinding. The surface is used to separate the plurality of rice bran from the plurality of white rice, and a second dust is also generated during the grinding process (not shown). The second blower 254 guides the airflow W1 to the cyclone generated by the second duct 252, wherein since the weight of the rice bran is heavier than the second dust, the rice ducts are located at the periphery of the airflow through the second duct 252. The lighter second dust will be located at the center of the airflow, that is, the second dust flows closer to the fourth axis Y2. Finally, the rice bran is guided by the cyclone-guided airflow W1 and its own weight, falling into the second casing container 253, and the second dust is guided by the suction airflow W2 when passing through the second conduit 252. Along the fourth axis Y2, it falls into the dust collecting container 232 through the suction tube body 231a.

In the present embodiment, the air blower and the dust collecting container 232 of the dust collecting device 23 are disposed on one side of the first shelling machine 21 and the second shelling machine 24. However, in other embodiments of the present creation, please refer to the sixth The grain processing device 2 may include two dust collecting devices 23, and each dust collecting device 23 is integrally disposed at the top 222b of the first conduit 222 and the top 252b of the second conduit 252, in other words, the dust collecting structure 231 of each dust collecting device 23 and Dust collection containers 232 are disposed on top of the first conduit 222 and the second conduit 252.

It should be noted that, in the foregoing embodiment, the first conduit 222 and the second conduit 252 are respectively connected to the dust collecting device, but the actual amount of the dust in the first conduit 222 and the second conduit 252 may be selected, and only one connection is selected. The dust collecting device 23 is not limited herein. Moreover, in other embodiments, the number of the first shelling machine 21, the second shelling machine 24, the first casing conveying structure 22, and the second casing conveying structure 25 may be adjusted according to the characteristics of the grain, for example. In other words, if the grain contains only one layer of the outer casing, only the first shelling machine 21 can be kept together with the first casing conveying structure 22 and the dust collecting device 23 to complete the shelling operation.

After the rice R passes through the first sheller 21 and the second sheller 25, the coarse slabs fall into the first header container 223, and the rice stalks fall into the second header container 253, and finally the obtained white rice It is dropped into the vibrating sieve rice machine 4, and through the vibrating sieve rice machine 4, the white rice can be classified into a plurality of first-class white rice, a plurality of large broken rice and a plurality of small broken rice and respectively accommodated in a third container. 41. A fourth container 42 and a fifth container 43.

The weight measuring device set 3 includes a first weight measuring device 31 disposed at the bottom of the first housing container 223, a second weight measuring device 32 disposed at the bottom of the second housing container 253, and a third weight measuring device 33. At the bottom of the third container 41, a fourth weight measuring device 34 is disposed at the bottom of the fourth container 42, and a fifth weight measuring device 35 is disposed at the bottom of the fifth container 43 to measure rough, rice bran, first, etc., respectively. The weight of the white rice, the large broken rice, and the small broken rice, the weighing device group 3 also includes a sixth weight measuring device 36. Before the rice R is processed, the basis weight of the rice R can be measured first, and the rice R is subjected to wind selection. In the present embodiment, the sixth weight measuring device 36 is disposed on the operating platform 51 of the control module 5, and the creation is performed. In other embodiments, the sixth weight measuring device 36 can be adjusted according to requirements, for example, can be disposed on one side of the grain processing device 2, and details are not described herein.

It should be noted that, in other embodiments of the present invention, as shown in FIG. 6, the first weight measuring device 31 and the second weight measuring device 32 respectively have a weight sensor M, one end of each weight sensor M. An outer side wall 222d of the first duct 222 and an outer side wall 252d of the second duct 252 are suspended, and the other ends of the weight sensors M are respectively connected to the first header container 223 and the second header container 253. Thereby, when the rough and the rice bran fall into the first header container 223 and the second header container 253, respectively, the weight sensors M sense the weight of the rough and the rice bran.

Referring to FIG. 2, the control module 5 includes an operation platform 51, a control box 52, and a display screen 53, wherein, in order to save space, the operation platform 51 is an upper surface of the control box 52, and the display screen 53 is disposed on On the operating platform 51, preferably, the display 53 can be a touch display. A computer main unit 521 and a printer 522 can be disposed inside the control box 52. Finally, as shown in FIG. 3, the weights respectively measured by the weight measuring device group 3 can be corresponding to the generated signals, and the computer host 521 of the control module 5 can be used to receive the signals measured by the weighing device group 3, and operate. The obtained signal, in detail, first obtains the rice R capacity, and the control module 5 subtracts the coarseness of the rice R basis weight and the weight of the rice multiply by the machine characteristic coefficient to obtain the brown rice weight (in order to prevent each machine) The air separation filter capacity is different. In order to make the weight value of the brown rice more accurate, it will be multiplied by a factor when calculating the weight of the brown rice. Then calculate the ratio of crude weight, brown rice weight, rice bran weight, large broken rice, small broken rice and first white rice weight, and finally obtain the quantitative index of rice R quality, and can be calculated through the printer 522 selectively. The data is printed out. In this embodiment, the computer host 521 in the control module 5 can be connected to a cloud server 7, and the obtained signals and quantized indicators can be transmitted to the cloud server 7, so that the manager can Connected to the cloud server 7 via an electronic device to obtain information about the quality of the rice R. In another embodiment of the present invention, the control module 5 can be a mobile control module, and the manager can separate the mobile control module from the grain quality detecting system 1 and selectively move the same. To other devices or devices, and load the operation information of other devices or devices into the control module 5 and upload the cloud server 7, so that the control module 5 can effectively provide information about the collection, analysis, integration and storage of the operation information. The function.

In summary, compared with the conventional grain processing device, the grain processing device of the present invention can effectively collect the dust in the work in the dust collecting device to provide a relatively good working environment and simultaneously dust. Separated from the shell of the grain so that the grain quality inspection system of the present invention can effectively calculate the weight of the shell without being disturbed by dust.

The above-described embodiments are only used to exemplify the embodiments of the present invention, and to explain the technical features of the present invention, and are not intended to limit the scope of protection of the present creation. Any change or equivalence that can be easily accomplished by those skilled in the art is within the scope of this creation. The scope of protection of this creation shall be subject to the scope of the patent application.

1‧‧‧Grain Quality Inspection System
2‧‧‧Grain processing unit
21‧‧‧First Sheller
22‧‧‧First shell conveying structure
221‧‧‧First output tube
222‧‧‧First catheter
222a‧‧‧ side
222b‧‧‧ top
222c‧‧‧ bottom
222d‧‧‧Outer side wall
223‧‧‧First set of shell containers
224‧‧‧First blower
23‧‧‧dust collection device
231‧‧‧ vacuum structure
231a‧‧‧Attracting body
232‧‧‧dust container
24‧‧‧Second Sheller
25‧‧‧Second shell conveying structure
251‧‧‧Second output tube
252‧‧‧Second catheter
252a‧‧‧ side
252b‧‧‧ top
252c‧‧‧ bottom
252d‧‧‧Outer side wall
253‧‧‧Second set of shell containers
254‧‧‧second blower
26‧‧‧Scum rice collection container
3‧‧‧Measurement device group
31‧‧‧First weighing device
32‧‧‧Second weight measuring device
33‧‧‧ Third weighing device
34‧‧‧Fourth weight measuring device
35‧‧‧ Fifth weighing device
36‧‧‧The sixth weighing device
4‧‧‧Vibrating sieve rice machine
41‧‧‧ third container
42‧‧‧fourth container
43‧‧‧ fifth container
5‧‧‧Control Module
51‧‧‧Operation platform
52‧‧‧Control box
521‧‧‧Computer host
522‧‧‧Printer
53‧‧‧ display
6‧‧‧Base
7‧‧‧Cloud Server
R‧‧‧ Rice
R1‧‧‧ first housing
P1‧‧‧First dust
X1‧‧‧first axis
Y1‧‧‧second axis
X2‧‧‧ third axis
Y2‧‧‧ fourth axis
W‧‧‧ Merry
W1‧‧‧Cyclone guided airflow
W2‧‧‧Attracting airflow
M‧‧‧ weight sensor

Fig. 1 is a perspective view showing the appearance of the created grain quality detecting system; Fig. 2 is a perspective view showing another appearance of the created grain quality detecting system; Fig. 3 is a schematic plan view of the created grain quality detecting system; A partial schematic view of the first casing conveying structure of the present grain processing device in the horizontal plane; FIG. 5 is a partial perspective view of the first casing conveying structure of the creation grain processing device; and FIG. 6 is the creation of the grain processing A partial perspective view of another embodiment of the device.

1‧‧‧Grain Quality Inspection System

2‧‧‧Grain processing unit

22‧‧‧First shell conveying structure

221‧‧‧First output tube

222‧‧‧First catheter

222a‧‧‧ side

222b‧‧‧ top

222c‧‧‧ bottom

223‧‧‧First set of shell containers

23‧‧‧dust collection device

231‧‧‧ vacuum structure

231a‧‧‧Attracting body

232‧‧‧dust container

25‧‧‧Second shell conveying structure

251‧‧‧Second output tube

252‧‧‧Second catheter

252a‧‧‧ side

252b‧‧‧ top

252c‧‧‧ bottom

253‧‧‧Second set of shell containers

3‧‧‧Measurement device group

31‧‧‧First weighing device

32‧‧‧Second weight measuring device

33‧‧‧ Third weighing device

34‧‧‧Fourth weight measuring device

35‧‧‧ Fifth weighing device

4‧‧‧Vibrating sieve rice machine

41‧‧‧ third container

42‧‧‧fourth container

43‧‧‧ fifth container

5‧‧‧Control Module

6‧‧‧Base

R‧‧‧ Rice

X1‧‧‧first axis

Y1‧‧‧second axis

X2‧‧‧ third axis

Y2‧‧‧ fourth axis

Claims (18)

A grain processing apparatus comprising: a first sheller that separates a plurality of first shells of a plurality of grains from a plurality of bodies of the grains, and simultaneously generates a plurality of first dusts; a first shell conveying structure, and the first a first housing conveying structure having a first output tube, a first conduit and a first housing container, wherein the first output tube extends along a first axial direction, the first housing conveying structure a conduit and the first housing container extend along a second axial direction, and the first housings are sequentially placed in the first output tube and the first conduit from the first sheller a set of shell containers; and a dust collecting device connected to the first duct, the dust collecting device having a dust collecting structure and a dust collecting container, the dust entering the first duct through the first output tube, The dust suction structure attracts the dust in the first conduit and is guided to the dust collection container. The grain processing apparatus of claim 1, further comprising a second shelling machine and a second shell conveying structure connected to the second shelling machine, wherein the second shell conveying structure has a Connecting a second output tube, a second conduit and a second header container, the second output tube extending along a third axial direction, the second conduit and the second housing container along a fourth axis Extendingly, the second shelling machine separates the plurality of second shells of the grains from the bodies of the grains, and the second shells sequentially pass through the second output tube from the second shelling machine and After the second conduit is received in the second casing container. The grain processing apparatus of claim 2, wherein the first output pipe is connected to one side of the first pipe along a line direction of the first pipe to communicate with the first pipe, The dust collecting structure is disposed at a top of one of the first conduits to communicate with the first conduit, and the dust collecting container is disposed at a bottom of one of the first conduits to communicate with the first conduit. The grain processing device of claim 3, wherein the second output tube is disposed on a side of the second conduit along a line direction of the second conduit to communicate with the second conduit, The second casing container is disposed at a bottom of one of the second conduits to communicate with the second conduit. The grain processing apparatus of claim 4, wherein the first housing conveying structure has a first air blower, the second housing conveying structure has a second air blower, the first air blower and the second air blower And generating, by the first output pipe and the second output pipe, a cyclone guiding airflow in the first conduit and the second conduit, respectively, to respectively respectively the first casing and the second A housing is delivered to the first conduit and the second conduit. The grain processing device of claim 5, wherein the dust collecting device is integrally disposed on the top of the first conduit. The grain processing device of claim 6, wherein the cyclone-directed airflow in the first conduit is axially flowed by the second axis, and a suction airflow in the first conduit is The suction structure is generated, the suction airflow flows along the second axis, and the cyclone guiding airflow in the second conduit flows axially with the fourth axis, and a suction airflow system in the second conduit Produced by the dust suction structure, the suction airflow flows along the fourth axis. A grain quality detecting system comprising: a grain processing apparatus, comprising: a first shelling machine, separating a plurality of first shells of a plurality of grains from a plurality of bodies of the grains, and simultaneously generating a plurality of first dusts; The first conveying structure has a first output pipe, a first pipe and a first casing container, and the first output pipe is along the first casing a first axial extension, the first conduit and the first housing container extend along a second axial direction, and the first housings sequentially pass the first output tube and the first from the first shelling machine After the conduit is received in the first casing container; and a dust collecting device is connected to the first conduit, the dust collecting device has a dust collecting structure and a dust collecting container, and the dust passes through the first output pipe and After the first conduit, the dust suction structure attracts the dust in the first conduit and leads to the dust collecting container; a weight measuring device group respectively measures the grain, the first shell, the Waiting for the weight of the second housing and the bodies Number; and a control module for receiving the measured signal of the weighing device group. The grain quality detecting system of claim 8, wherein the weight measuring device set comprises a first weight measuring device disposed at a bottom of the first casing container or suspended from an outer side wall of the first conduit. And a second weight measuring device is disposed at a bottom of one of the second casing containers or suspended from an outer sidewall of the second conduit. The grain quality detecting system according to claim 9 further comprises a vibrating screen rice machine for screening the white rice for a plurality of first-class white rice, a plurality of large broken rice and a plurality of small broken rice, the weighing device The group separately measures the weight of the first-class white rice, the large broken rice and the small broken rice. The grain quality detecting system of claim 10, further comprising a base, the grain processing device, the weight measuring device group, the control module and the vibrating screen machine being disposed on the base. The grain quality detecting system of claim 11, wherein the control module is connected to a cloud server. The grain quality detecting system of claim 12, wherein the grain processing device further comprises a second shelling machine and a second shell conveying structure connected to the second shelling machine, wherein the second shell conveying structure The housing conveying structure has a second output pipe, a second conduit and a second casing container sequentially connected to each other, the second output pipe has a third axial extension, the second conduit and the second casing container Extending along a fourth axial direction, the second shelling machine separates the plurality of second shells of the grains from the bodies of the grains, and the second shells sequentially pass through the second sheller After the second output tube and the second conduit are received in the second housing container. The grain quality detecting system of claim 13, wherein the first output pipe is connected to one side of the first pipe along a line direction of the first pipe to communicate with the first pipe. The dust collecting structure is disposed at a top of one of the first conduits to communicate with the first conduit, and the dust collecting container is disposed at a bottom of one of the first conduits to communicate with the first conduit. The grain quality detecting system of claim 14, wherein the second output pipe is disposed on a side of the second pipe along a line direction of the second pipe to communicate with the second pipe. The second casing container is disposed at a bottom of one of the second conduits to communicate with the second conduit. The grain quality detecting system of claim 15, wherein the first casing conveying structure has a first air blower, the second casing conveying structure has a second air blower, the first air blower and the second The wind flow generated by the air blower forms a cyclone guiding airflow in the first conduit and the second conduit through the first output pipe and the second output pipe, respectively, to respectively respectively the first casing and the first A second housing is delivered to the first conduit and the second conduit. The grain quality detecting system of claim 16, wherein the dust collecting device is integrally disposed on the top of the first conduit. The grain quality detecting system of claim 17, wherein the cyclone guiding airflow in the first duct is axially flowing with the second axis, and a suction airflow system in the first duct Produced by the vacuuming structure, the suction airflow flows along the second axis, and the cyclone guiding airflow in the second conduit flows axially with the fourth axis, and a suction airflow in the second conduit It is generated by the dust suction structure, and the suction airflow flows along the fourth axis.