CN219266252U - Sterile environment grain detection equipment - Google Patents

Abstract

The utility model discloses a sterile environment grain detection device, which comprises a bottom plate, wherein a transmission box is arranged on one side of the top end of the bottom plate, a shaft seat is arranged above the transmission box, bearing plates are arranged on the outer walls of two sides of the shaft seat, a material receiving frame is arranged on the top end of the bearing plate, a moisture monitoring module is arranged at the central position of the bottom of the material receiving frame, an annular limiting frame is arranged on the top end of the bottom plate on the outer side of the transmission box, limiting rods are connected with two sides of the inside of the annular limiting frame in a sliding manner, the top ends of the limiting rods extend to the outer side of the annular limiting frame and are fixedly connected with the bottom end of the bearing plate, a side supporting plate is arranged on the top end of the bottom plate on one side of the annular limiting frame, a screening machine body is arranged on the outer wall of one end, far away from the bottom plate, and a feeding port is arranged at the central position of the top end of the screening machine body. The utility model not only can filter out large-particle impurities to ensure the quality of grains in a sterile environment, but also achieves the aim of automatic feeding, and achieves the aim of double-station sequential discharging, thereby improving the discharging efficiency of grains.

Description

Sterile environment grain detection equipment

Technical Field

The utility model relates to the technical field of grain detection equipment, in particular to sterile environment grain detection equipment.

Background

The quality of grains is always the focus of people, people need to eat a large amount of grains every day, the quality of grains is related to the health of people, the grains in a sterile environment can ensure that no spoilage caused by bacteria and fungi exists, the preservation time is long, and corresponding detection equipment is needed in order to ensure the quality of the grains during production and processing.

The current check out test set can be better detect the processing to aseptic environment grain, it mainly is provided with parts such as detection case, moisture monitoring module, control panel, when using it, only need pour into aseptic environment grain into the detection case in, can carry out moisture monitoring to aseptic environment grain by the moisture monitoring module in the detection case, relevant data can feedback to control panel, for the personnel watch, can reach the purpose that detects aseptic environment grain, according to above-mentioned, although this check out test set can carry out moisture detection processing to aseptic environment grain, but the particle size to aseptic environment grain of being inconvenient for usually sieves, and then be difficult to ensure aseptic environment grain and be little granule state, trouble people often.

Disclosure of Invention

The utility model aims to provide a sterile environment grain detection device, which aims to solve the problems that the detection device can detect moisture of the sterile environment grain, but is generally inconvenient to screen the grain size of the sterile environment grain, and further the grain in a small grain state in the sterile environment is difficult to ensure.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides a sterile environment grain check out test set, includes the bottom plate, one side on bottom plate top is equipped with the transmission case, the top of transmission case is equipped with the axle bed, all be equipped with the loading board on the outer wall of axle bed both sides, connect the material frame has been placed on the top of loading board, connect the central point department of material frame bottom to install moisture monitoring module, the bottom plate top in the transmission case outside is equipped with annular spacing frame, the inside both sides of annular spacing frame all sliding connection has the gag lever post, the top of gag lever post extends to the outside of annular spacing frame and with the bottom fixed connection of loading board, the bottom plate top of annular spacing frame one side is equipped with the side stay plate, be equipped with screening organism on the outer wall of bottom plate one end is kept away from to the side stay plate, the central point department on screening organism top is equipped with the feed inlet, the bottom of feed inlet extends to the inside of screening organism, all be equipped with the locating frame on the inner wall of screening organism both sides, the inside all swing joint has the linkage piece, the one end of linkage piece extends to the outside of locating frame and is equipped with the screening frame, the bottom of screening frame is equipped with the gag lever post, the bottom plate's top of annular spacer frame is equipped with the vibrator, the vibrator is equipped with the inside vibration panel's the inside of the vibration panel, the vibration panel is connected with the inside of the control panel, the vibration panel is located the inside of the single-chip microcomputer, the vibration panel is connected with the top panel.

Preferably, a worm wheel is rotatably connected to the central position inside the transmission case, a vertical shaft is arranged at the central position of the top end of the worm wheel, and the top end of the vertical shaft extends to the outside of the transmission case and is fixedly connected with the bottom end of the shaft seat, so that the vertical shaft drives the shaft seat to rotate.

Preferably, one side inside the transmission case is rotationally connected with a worm, and the worm is meshed with the worm wheel, so that the worm wheel is driven to slowly rotate when the worm rotates.

Preferably, a discharge hole is arranged at the central position of the bottom end of the screening machine body, and the top end of the discharge hole extends to the inside of the screening machine body, so that grains screened in the screening machine body are discharged through the discharge hole.

Preferably, the top end of the bearing seat is provided with a foot rest, and the top end of the foot rest is provided with a conveyor belt so as to convey grains.

Preferably, a baffle is arranged at the edge position of the top of the conveyor belt, and a guide plate is arranged at one end of the baffle so as to limit and guide grains.

Preferably, return springs are mounted at two ends of the linkage block, and one end, away from the linkage block, of the return springs is connected with the inner wall of one end of the positioning frame, so that the screening frame is stable in vibration.

Preferably, one end of the worm is provided with a linkage shaft, one end of the linkage shaft, which is far away from the worm, extends to the outside of the transmission box and is provided with a rotary driving piece, one end of the rotary driving piece, which is far away from the linkage shaft, is connected with the top end of the bottom plate through a support, and the input end of the rotary driving piece is electrically connected with the output end of the single chip microcomputer in the control panel so as to drive the worm to rotate through the linkage shaft.

Compared with the prior art, the utility model has the beneficial effects that: the sterile environment grain detection equipment not only can filter large-particle impurities to ensure the quality of the sterile environment grains, but also achieves the purpose of automatic feeding, achieves the purpose of double-station sequential discharging, and further improves the discharging efficiency of the grains;

(1) Injecting the grain in the sterile environment into the screening frame through the feed inlet, driving the linkage block to vibrate up and down due to the vibrator, and limiting the lifting amplitude of the linkage block by the reset spring, so that the linkage block drives the screening frame to vibrate stably up and down, the grain in the screening frame is screened by the screen and falls into the bottom of the screening machine body and is discharged through the discharge port, the grain is ensured to be in a small particle state, and the impurities with large particles remain in the screening frame, so that the quality of the grain in the sterile environment is ensured;

(2) The grain in the sterile environment is injected into the top of the conveyor belt, and the conveyor belt is in a uniform running state, so that the conveyor belt transmits the grain to the feed inlet after the baffle and the guide plate shield and limit the grain, thereby achieving the purpose of automatic feeding;

(3) The worm is driven to rotate through the linkage shaft by the rotary driving piece, so that the worm drives the worm wheel to rotate slowly, the worm wheel drives the material receiving frame to rotate through the vertical shaft, the shaft seat and the bearing plate, grains discharged from the material discharging opening can be always received by the material receiving frame on the right side, the material receiving frame filled with grains on the left side is replaced, and the purpose of double-station sequential discharging can be achieved through reciprocating circulation, so that the discharging efficiency of the grains is improved.

Drawings

FIG. 1 is a schematic cross-sectional elevation view of the present utility model;

FIG. 2 is an enlarged schematic view of the structure of FIG. 1A according to the present utility model;

FIG. 3 is a schematic view of a three-dimensional structure of a conveyor belt according to the present utility model;

FIG. 4 is a schematic top view of a transmission case of the present utility model in semi-section;

fig. 5 is a schematic three-dimensional semi-sectional structure of the transmission case of the present utility model.

In the figure: 1. a bottom plate; 2. a transmission case; 3. an annular limit frame; 4. a limit rod; 5. a shaft seat; 6. a carrying plate; 7. a material receiving frame; 8. a moisture monitoring module; 9. a discharge port; 10. a screening machine body; 11. a side support plate; 12. a bearing seat; 13. a control panel; 14. a foot rest; 15. a conveyor belt; 16. a baffle; 17. a deflector; 18. a feed inlet; 19. a screening frame; 20. a screen; 21. a positioning frame; 22. a return spring; 23. a linkage block; 24. a vibrator; 25. a rotary driving member; 26. a linkage shaft; 27. a worm; 28. a worm wheel; 29. a vertical shaft.

Detailed Description

The technical solutions in the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1-5, an embodiment of the present utility model is provided: the utility model provides a sterile environment grain check out test set, includes bottom plate 1, and one side at bottom plate 1 top is equipped with transmission case 2, and the central point in transmission case 2 inside puts and rotates and be connected with worm wheel 28, and the central point at worm wheel 28 top is equipped with vertical scroll 29, and the top of vertical scroll 29 extends to transmission case 2 outside and is connected with the bottom fixed of axle bed 5;

when in use, the worm wheel 28 rotates to drive the vertical shaft 29 to rotate, so that the vertical shaft 29 drives the shaft seat 5 to rotate;

one side of the inside of the transmission case 2 is rotatably connected with a worm 27, and the worm 27 is meshed with a worm wheel 28;

when in use, the worm 27 is meshed with the worm wheel 28, so that the worm 27 drives the worm wheel 28 to slowly rotate when rotating;

one end of the worm 27 is provided with a linkage shaft 26, one end of the linkage shaft 26 away from the worm 27 extends to the outside of the transmission case 2 and is provided with a rotary driving piece 25, one end of the rotary driving piece 25 away from the linkage shaft 26 is connected with the top end of the bottom plate 1 through a support, and the input end of the rotary driving piece 25 is electrically connected with the output end of the singlechip in the control panel 13;

in use, the worm 27 is driven to rotate by opening the rotary driving member 25 through the linkage shaft 26;

the upper part of the transmission case 2 is provided with a shaft seat 5, the outer walls of two sides of the shaft seat 5 are provided with a bearing plate 6, the top end of the bearing plate 6 is provided with a material receiving frame 7, the center position of the bottom of the material receiving frame 7 is provided with a moisture monitoring module 8, the top end of a bottom plate 1 outside the transmission case 2 is provided with an annular limiting frame 3, two sides inside the annular limiting frame 3 are both connected with limiting rods 4 in a sliding manner, the top end of the limiting rod 4 extends to the outside of the annular limiting frame 3 and is fixedly connected with the bottom end of the bearing plate 6, the top end of a bottom plate 1 on one side of the annular limiting frame 3 is provided with a side supporting plate 11, the outer wall of one end of the side supporting plate 11, which is far away from the bottom plate 1, is provided with a screening machine body 10, the center position of the bottom end of the screening machine body 10 is provided with a material discharging opening 9, and the top end of the material discharging opening 9 extends to the inside the screening machine body 10;

when in use, the grain sieved in the sieving machine body 10 is discharged through the discharge opening 9 by arranging the discharge opening 9 at the bottom of the sieving machine body 10;

a feed inlet 18 is arranged at the center position of the top end of the screening machine body 10, the bottom end of the feed inlet 18 extends into the screening machine body 10, positioning frames 21 are arranged on the inner walls of the two sides of the screening machine body 10, a linkage block 23 is movably connected in each positioning frame 21, return springs 22 are arranged at the two ends of the linkage block 23, and one end, far away from the linkage block 23, of each return spring 22 is connected with the inner wall of one end of the positioning frame 21;

when the vibrating screen is used, the vibration amplitude of the linkage block 23 is limited through the reset spring 22, so that the screening frame 19 is stable when vibrating;

one end of the linkage block 23 extends to the outside of the positioning frame 21 and is provided with a screening frame 19, the bottom of the screening frame 19 is provided with a screen 20, two sides of the top of the screening machine body 10 are provided with vibrators 24, the bottom ends of the vibrators 24 are fixedly connected with the top ends of the linkage block 23, the top end of the bottom plate 1, far away from one side of the annular limiting frame 3, of the side supporting plate 11 is provided with a bearing seat 12, the top end of the bearing seat 12 is provided with a foot rest 14, and the top end of the foot rest 14 is provided with a conveying belt 15;

in use, the conveyor belt 15 is opened so as to convey grains;

a baffle 16 is arranged at the edge position of the top of the conveyor belt 15, and a guide plate 17 is arranged at one end of the baffle 16;

when in use, the baffle 16 and the guide plate 17 are arranged at the edge position and one end of the top of the conveyor belt 15 so as to limit and guide grains;

the center position of the surface of the bearing seat 12 is provided with a control panel 13, the output end of the single-chip microcomputer in the control panel 13 is electrically connected with the input end of the vibrator 24, and the input end of the single-chip microcomputer in the control panel 13 is electrically connected with the output end of the moisture monitoring module 8.

When the embodiment of the application is used, firstly, the sterile environment grains are injected to the top of the conveyor belt 15, the conveyor belt 15 is in a state of uniform operation, after the grains are shielded and limited by the baffle 16 and the guide plate 17, the conveyor belt 15 is used for transmitting the grains to the feed inlet 18 so as to achieve the purpose of automatic feeding, then the sterile environment grains are introduced into the screening frame 19 through the feed inlet 18, the vibrator 24 drives the linkage block 23 to vibrate up and down, the reset spring 22 is used for limiting the lifting amplitude of the linkage block 23, the linkage block 23 drives the screening frame 19 to vibrate up and down stably, the grains inside the screening frame 19 are screened by the screen 20 and then fall into the bottom of the screening machine body 10 and are discharged by the discharge outlet 9, so that the grains are in a small grain state, large grain impurities can be filtered, the quality of the grains can be ensured, finally, the worm 27 is driven to rotate through the linkage shaft 26 by the rotary driving piece 25, so that the worm 27 drives the worm wheel 28 to slowly rotate, the worm wheel 28 drives the material receiving frame 7 to rotate through the vertical shaft 29, the shaft seat 5 and the bearing plate 6, grains discharged from the material discharging opening 9 can be always received by the material receiving frame 7 on the right side, the material receiving frame 7 filled with grains on the left side is replaced, and the reciprocating circulation is performed, so that the aim of double-station sequential discharging can be achieved, the discharging efficiency of grains is improved, the lower end of the limiting rod 4 is driven to slide in the annular limiting frame 3 when the bearing plate 6 rotates, the rotation amplitude of the bearing plate 6 is limited, the stability when the bearing plate 6 rotates is ensured, the grain moisture received in the material receiving frame 7 is monitored and processed through the moisture monitoring module 8, and related data are fed back to the control panel 13 and displayed, the purpose of detecting the grains in the sterile environment can be achieved by watching by personnel, so that the detection equipment is used.

Claims (8)

1. The utility model provides a sterile environment grain check out test set, its characterized in that, including bottom plate (1), one side on bottom plate (1) top is equipped with transmission case (2), the top of transmission case (2) is equipped with axle bed (5), all be equipped with loading board (6) on the outer wall of axle bed (5) both sides, connect material frame (7) have been placed on the top of loading board (6), connect the central point department of material frame (7) bottom to install moisture monitoring module (8), bottom plate (1) top in transmission case (2) outside is equipped with annular spacing frame (3), all sliding connection in both sides inside annular spacing frame (3) has gag lever post (4), the top of gag lever post (4) extends to the outside of annular spacing frame (3) and with the bottom fixed connection of loading board (6), bottom plate (1) top of annular spacing frame (3) one side is equipped with side stay plate (11), be equipped with screening organism (10) on the outer wall of bottom plate (1) one end of keeping away from, the central point department of screening organism (10) top is equipped with the inside of feed inlet (18), both sides are equipped with screening organism (10) on the inside location of the inside of organism (10) of feed inlet (18), the inside all swing joint of locating frame (21) has linkage piece (23), the one end of linkage piece (23) extends to the outside of locating frame (21) and is equipped with screening frame (19), the bottom of screening frame (19) is equipped with screen cloth (20), vibrator (24) are all installed to the both sides at screening organism (10) top, the bottom and the top fixed connection of linkage piece (23) of vibrator (24), bottom plate (1) top that annular spacing frame (3) one side was kept away from to side stay plate (11) are equipped with and bear seat (12), control panel (13) are installed to the central point department on the surface of bearing seat (12), the output of control panel (13) inside singlechip and the input electric connection of vibrator (24), the input of control panel (13) inside singlechip and the output electric connection of moisture monitoring module (8).

2. The apparatus for the detection of grain in a sterile environment according to claim 1, wherein: the center position inside the transmission case (2) is rotationally connected with a worm wheel (28), the center position of the top end of the worm wheel (28) is provided with a vertical shaft (29), and the top end of the vertical shaft (29) extends to the outside of the transmission case (2) and is fixedly connected with the bottom end of the shaft seat (5).

3. The apparatus for detecting grain in a sterile environment according to claim 2, wherein: one side of the inside of the transmission case (2) is rotatably connected with a worm (27), and the worm (27) is meshed with a worm wheel (28).

4. The apparatus for the detection of grain in a sterile environment according to claim 1, wherein: the center position of screening organism (10) bottom is equipped with bin outlet (9), the top of bin outlet (9) extends to screening organism (10) inside.

5. The apparatus for the detection of grain in a sterile environment according to claim 1, wherein: the top of the bearing seat (12) is provided with a foot rest (14), and the top of the foot rest (14) is provided with a conveying belt (15).

6. The apparatus for detecting grain in a sterile environment according to claim 5, wherein: a baffle plate (16) is arranged at the edge position of the top of the conveyor belt (15), and a guide plate (17) is arranged at one end of the baffle plate (16).

7. The apparatus for the detection of grain in a sterile environment according to claim 1, wherein: and the two ends of the linkage block (23) are provided with return springs (22), and one end, far away from the linkage block (23), of each return spring (22) is connected with the inner wall of one end of the positioning frame (21).

8. A sterile environment grain detection apparatus according to claim 3, wherein: one end of the worm (27) is provided with a linkage shaft (26), one end of the linkage shaft (26) away from the worm (27) extends to the outside of the transmission box (2) and is provided with a rotary driving piece (25), one end of the rotary driving piece (25) away from the linkage shaft (26) is connected with the top end of the bottom plate (1) through a support, and the input end of the rotary driving piece (25) is electrically connected with the output end of the single chip microcomputer inside the control panel (13).

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