CN212550560U - Single crystal sugar metal detection and separation device - Google Patents

Abstract

The utility model discloses a single crystal sugar metal detection and separation device, which comprises a hopper, a blanking pipeline, a material distribution mechanism and a metal detector; the material distributing mechanism comprises a first material discharging pipeline, a second material discharging pipeline, a valve baffle and a valve driving mechanism, wherein the first material discharging pipeline and the second material discharging pipeline are connected to the lower end of the blanking pipeline, the valve driving mechanism is used for driving the valve baffle, a first material discharging opening is formed between the first material discharging pipeline and the blanking pipeline, a second material discharging opening is formed between the second material discharging pipeline and the blanking pipeline, and the valve baffle is rotatably connected to the lower end of the blanking pipeline and passes through the valve driving mechanism to drive the valve baffle to swing. The utility model discloses can make the single crystal sugar that contains metallic impurity and the single crystal sugar reposition of redundant personnel that does not contain metallic impurity, can separate the metallic impurity in the single crystal sugar through further screening back, avoid its quality that influences the product.

Description

Single crystal sugar metal detection and separation device

Technical Field

The utility model relates to a single crystal sugar production facility technical field especially relates to a single crystal sugar metal detects separator.

Background

In the production process of the monocrystalline sugar, the molasses of the monocrystalline sugar needs to be conveyed for a long distance through a metal pipeline, and in addition, a crushing or vibrating and screening process exists in the production process of the monocrystalline sugar, so that the monocrystalline sugar has a certain chance to be mixed with metal impurities. The existing technology is difficult to separate the metal impurities in the single crystal sugar, which affects the quality of the product and even causes the problem of food safety.

Disclosure of Invention

An object of the utility model is to overcome prior art's not enough, provide a novel structure can detect the metal piece that exists in the single crystal sugar product fast and detect separator with the single crystal sugar metal of its separation.

In order to realize the above purpose, the utility model discloses the technical scheme who adopts is: a single crystal sugar metal detection and separation device comprises a hopper, a blanking pipeline connected below the hopper, a material distribution mechanism arranged at the lower end of the blanking pipeline, and a metal detector arranged at the periphery of the blanking pipeline and positioned between the hopper and the material distribution mechanism; the feed mechanism including connect in first discharge pipeline and second discharge pipeline, valve baffle of blanking pipeline lower extreme and be used for driving the valve actuating mechanism of valve baffle, be formed with first discharge gate between first discharge pipeline and the blanking pipeline, be formed with the second bin outlet between second discharge pipeline and the blanking pipeline, the valve baffle rotates to be connected in blanking pipeline lower extreme and passes through valve actuating mechanism drives the valve baffle swing, works as when valve baffle swings to first gear, the valve baffle covers first discharge gate and opens the second discharge gate, works as when valve baffle swings to the second gear, the valve baffle covers the second discharge gate and opens first discharge gate.

The utility model has the advantages that: the utility model discloses a single crystal sugar metal detects separator, its metal detector of accessible detects the single crystal sugar that passes through in to the blanking pipeline. And the valve baffle is in a second gear in a normal state, the valve baffle covers the second discharge port and opens the first discharge port, and the monocrystalline sugar is discharged from the first discharge pipeline. Once the metal detector detects that the monocrystalline sugar contains metal impurities, the valve driving mechanism can drive the valve baffle plate to swing to the first gear, so that the valve baffle plate covers the first discharge port and opens the second discharge port, and the monocrystalline sugar is discharged from the second discharge pipeline. After the metal detector does not detect metal any more after a certain time, the valve driving mechanism drives the valve baffle to reset and swing to a second gear. The single crystal sugar containing metal impurities and the single crystal sugar without the metal impurities are shunted through the mode, and the metal impurities in the single crystal sugar can be separated through further screening, so that the influence on the quality of products is avoided.

Preferably, the valve driving mechanism comprises a servo motor and a first reduction gearbox, an input shaft of the first reduction gearbox is coaxially connected with the servo motor, and an output shaft of the first reduction gearbox is connected with the valve baffle. The valve baffle can be driven to reset and swing between the first gear and the second gear through the servo motor and the first reduction gearbox.

Preferably, the first discharging pipeline comprises a fixed section fixedly connected with the blanking pipeline and a swinging section rotatably connected with the fixed section, and a finished product collecting station and a backflow station are arranged in the swinging range of the swinging section. The finished product collecting station can directly collect the finished product of the monocrystalline sugar, and the backflow station can convey the monocrystalline sugar discharged from the first discharging pipeline to the hopper again for metal detection so as to avoid mixing a small amount of metal impurities in the monocrystalline sugar.

Preferably, a backflow conveying line is arranged in the backflow station, the backflow conveying line comprises an upper conveying belt, a lower conveying belt and a lifting device connected with the upper conveying belt and the lower conveying belt, the lifting device comprises a vertically extending pipe barrel, a vertical screw rod arranged in the pipe barrel and a lifting driving mechanism driving the vertical screw rod to rotate, openings respectively communicated with the upper conveying belt and the lower conveying belt are formed in the side walls of the upper end and the lower end of the pipe barrel, and the output end of the upper conveying belt extends to the upper end of the hopper. The single crystal sugar discharged from the first discharging pipeline falls into the lower conveying belt and is conveyed into the lifting device through the lower conveying belt, the vertical screw rod in the lifting device can drive the material to ascend along the pipe barrel when rotating, the material is discharged onto the upper conveying belt from the opening at the upper end, and finally the material is conveyed into the hopper through the upper conveying belt to be subjected to metal detection again.

Preferably, a first collecting box is arranged in the finished product collecting station.

Preferably, the lifting driving mechanism comprises a lifting driving motor and a second reduction gearbox, an input shaft of the second reduction gearbox is coaxially connected with the lifting driving motor, and an output shaft of the second reduction gearbox is connected with the vertical screw rod. The lifting driving motor and the second reduction gearbox can drive the vertical screw to rotate so as to drive the single crystal sugar to lift.

Preferably, the outlet of the second discharge conduit is provided with a second collection tank.

Drawings

Fig. 1 is a schematic structural diagram of the present invention.

Fig. 2 is one of the schematic partial structural diagrams of the material distributing mechanism of the present invention.

Fig. 3 is a second partial schematic structural diagram of the material distributing mechanism of the present invention.

The device comprises a hopper 1, a blanking pipeline 2, a first discharging pipeline 31, a first discharging port 311, a fixed section 312, a swinging section 313, a second discharging pipeline 32, a second discharging port 321, a second discharging port 33, a valve baffle 34, a valve driving mechanism 341, a servo motor 342, a first reduction gearbox 4, a metal detector 51, an upper conveying belt 52, a lower conveying belt 531, a pipe barrel 532, a vertical screw 533, a lifting driving mechanism 5331, a lifting driving motor 5332, a second reduction gearbox 6, a first collecting box 7 and a second collecting box 7.

Detailed Description

The claimed technical solution of the present invention will now be described in further detail with reference to the accompanying drawings and specific embodiments.

Referring to fig. 1 to 3, the single crystal sugar metal detection and separation device in this embodiment includes a hopper 1, a blanking pipe 2 connected below the hopper 1, a material distribution mechanism disposed at a lower end of the blanking pipe 2, a backflow conveying line, and a metal detector 4 disposed at a periphery of the blanking pipe 2 and between the hopper 1 and the material distribution mechanism.

The material distributing mechanism comprises a first material discharging pipeline 31 and a second material discharging pipeline 32 which are connected to the lower end of the blanking pipeline 2, a valve baffle plate 33 and a valve driving mechanism 34 for driving the valve baffle plate 33.

In this embodiment the first discharge conduit 31 is used for discharging the monocrystalline sugar free of metallic impurities and the second discharge conduit 32 is used for discharging the monocrystalline sugar containing metallic impurities. The first discharging pipeline 31 comprises a fixed section 312 fixedly connected with the blanking pipeline 2 and a swinging section 313 rotatably connected with the fixed section 312, a finished product collecting station and a backflow station are arranged in the swinging range of the swinging section 313, a first collecting box 6 is arranged in the finished product collecting station, and a backflow conveying line is arranged in the backflow station. The outlet of the second discharge conduit 32 is provided with a second collecting tank 7.

Be formed with first bin outlet 311 between first bin outlet 31 and the blanking pipeline 2, be formed with second bin outlet 321 between second bin outlet 32 and the blanking pipeline 2, valve baffle 33 rotates to be connected in blanking pipeline 2 lower extreme and passes through valve actuating mechanism 34 drives the swing of valve baffle 33, works as when valve baffle 33 swings to first gear, valve baffle 33 covers first bin outlet 311 and opens second bin outlet 321, works as when valve baffle 33 swings to the second gear, valve baffle 33 covers second bin outlet 321 and opens first bin outlet 311. The valve driving mechanism 34 comprises a servo motor 341 and a first reduction gearbox 342, an input shaft of the first reduction gearbox 342 is coaxially connected with the servo motor 341, and an output shaft of the first reduction gearbox 342 is connected with the valve baffle 33. The valve baffle 33 can be driven to reset and swing between the first gear and the second gear by the servo motor 341 and the first reduction gearbox 342.

A backflow conveying line is arranged in the backflow station, the backflow conveying line comprises an upper conveying belt 51, a lower conveying belt 52 and a lifting device for connecting the upper conveying belt 51 and the lower conveying belt 52, the lifting device comprises a vertically extending pipe barrel 531, a vertical screw rod 532 arranged in the pipe barrel 531 and a lifting driving mechanism 533 for driving the vertical screw rod 532 to rotate, openings for respectively communicating the upper conveying belt 51 with the lower conveying belt 52 are formed in the side walls of the upper end and the lower end of the pipe barrel 531, and the output end of the upper conveying belt 51 extends to the upper end of the hopper 1. The lifting driving mechanism 533 comprises a lifting driving motor 5331 and a second reduction gearbox 5332, an input shaft of the second reduction gearbox 5332 is coaxially connected with the lifting driving motor 5331, and an output shaft of the second reduction gearbox 5332 is connected with the vertical screw 532. The lifting driving motor 5331 and the second reduction gearbox 5332 can drive the vertical screw 532 to rotate so as to drive the single crystal sugar to lift.

The working principle of the device for detecting and separating the metal of the single crystal sugar in the embodiment is as follows: normally, the shutter 33 is in the second position, in which the shutter 33 covers the second discharging opening 321 and opens the first discharging opening 311, and the single crystal sugar is discharged from the first discharging pipe 31. Since the swing section 313 of the first discharge duct 31 is free to swing horizontally, it can be swung to a finished product collecting station or a return station. When the swing section 313 swings to the backflow station, the monocrystalline sugar discharged from the first discharging pipeline 31 falls into the lower conveying belt 52 and is conveyed into the lifting device through the lower conveying belt 52, the vertical screw 532 in the lifting device can drive the material to ascend along the pipe barrel 531 when rotating, the material is discharged onto the upper conveying belt 51 from the opening at the upper end, and finally the material is conveyed into the hopper 1 through the upper conveying belt 51 for metal detection again. When the swing section 313 swings to the product collection station, the single crystal sugar may be discharged into the first collection tank 6. The first collection box 6 can directly collect the finished product of the monocrystalline sugar, and the return flow conveying line can convey the monocrystalline sugar discharged from the first discharge pipeline 31 to the hopper 1 again for metal detection so as to avoid a small amount of metal impurities from being mixed in the monocrystalline sugar. The specific swinging position of the swinging section 313 can be determined according to the product requirements, the more times of metal detection of the monocrystalline sugar by the backflow conveying line is, the less probability of metal impurities is, and when the metal detection times meet the production requirements, the swinging section 313 can be swung to a finished product collecting station for collection.

Once the metal detector 4 detects that the monocrystalline sugar contains metal impurities, the shutter driving mechanism 34 drives the shutter baffle 33 to swing to the first shift position, so that the shutter baffle 33 covers the first discharge port 311 and opens the second discharge port 321, and the monocrystalline sugar is discharged from the second discharge pipe 32 to the second collection box 7.

When the metal detector 4 does not detect metal any more after a certain time, the valve driving mechanism 34 drives the valve baffle 33 to reset and swing to the second gear. The single crystal sugar containing metal impurities and the single crystal sugar without the metal impurities are shunted through the mode, and the metal impurities in the single crystal sugar can be separated through further screening, so that the influence on the quality of products is avoided.

The above-described embodiments are merely preferred embodiments of the present invention, which are not intended to limit the present invention in any way. Those skilled in the art can make further changes and modifications to the invention, or modify equivalent embodiments to equivalent variations, without departing from the scope of the invention. Therefore, the content of the technical scheme of the utility model, according to the equivalent change made by the idea of the utility model, should be covered in the protection scope of the utility model.

Claims (7)

1. The utility model provides a single crystal sugar metal detects separator, includes hopper (1), connect in blanking pipeline (2) of hopper (1) below, set up in blanking pipeline (2) lower extreme feed mechanism and set up in blanking pipeline (2) periphery and be in metal detector (4) between hopper (1) and the feed mechanism, its characterized in that: the material distributing mechanism comprises a first material discharging pipeline (31) and a second material discharging pipeline (32) which are connected to the lower end of a blanking pipeline (2), a valve baffle plate (33) and a valve driving mechanism (34) used for driving the valve baffle plate (33), a first material discharging opening (311) is formed between the first material discharging pipeline (31) and the blanking pipeline (2), a second material discharging opening (321) is formed between the second material discharging pipeline (32) and the blanking pipeline (2), the valve baffle plate (33) is rotatably connected to the lower end of the blanking pipeline (2) and drives the valve baffle plate (33) to swing through the valve driving mechanism (34), when the valve baffle plate (33) swings to a first gear, the valve baffle plate (33) covers the first material discharging opening (311) and opens the second material discharging opening (321), and when the valve baffle plate (33) swings to a second gear, the shutter baffle (33) covers the second discharge opening (321) and opens the first discharge opening (311).

2. The single crystal sugar metal detecting and separating device according to claim 1, wherein: the valve driving mechanism (34) comprises a servo motor (341) and a first reduction gearbox (342), an input shaft of the first reduction gearbox (342) is coaxially connected with the servo motor (341), and an output shaft of the first reduction gearbox (342) is connected with a valve baffle (33).

3. The single crystal sugar metal detecting and separating device according to claim 1, wherein: the first discharging pipeline (31) comprises a fixed section (312) fixedly connected with the blanking pipeline (2) and a swinging section (313) rotatably connected with the fixed section (312), and a finished product collecting station and a backflow station are arranged in the swinging range of the swinging section (313).

4. The single crystal sugar metal detection and separation device according to claim 3, wherein: be provided with the backward flow transfer chain in the backward flow station, the backward flow transfer chain is including last conveyer belt (51), lower conveyer belt (52) and connect the hoisting device who goes up conveyer belt (51) and lower conveyer belt (52), hoisting device is including vertical extension's bobbin (531), place in vertical screw rod (532) and the drive of bobbin (531) vertical screw rod (532) pivoted promote actuating mechanism (533), the lateral wall at both ends is opened respectively and is had the opening that feeds through conveyer belt (51) and lower conveyer belt (52) about bobbin (531), the output of going up conveyer belt (51) extends to hopper (1) upper end.

5. The single crystal sugar metal detection and separation device according to claim 3, wherein: and a first collecting box (6) is arranged in the finished product collecting station.

6. The single crystal sugar metal detection and separation device of claim 4, wherein: the lifting driving mechanism (533) comprises a lifting driving motor (5331) and a second reduction gearbox (5332), an input shaft of the second reduction gearbox (5332) is coaxially connected with the lifting driving motor (5331), and an output shaft of the second reduction gearbox (5332) is connected with the vertical screw (532).

7. The single crystal sugar metal detecting and separating device according to claim 1, wherein: the outlet of the second discharge pipeline (32) is provided with a second collecting box (7).

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