CN207121237U - A kind of rotating disc type continuous micro powder transfer device - Google Patents

Abstract

It the utility model is related to powder technology field, a kind of more particularly to rotating disc type continuous micro powder transfer device, including hopper, stirring vane in hopper, the bottom of the hopper is provided with discharge port plate, the discharge port plate is the discharging groove that discoid and circumference is provided with annular, a part for the discharge port plate is located at the outside of hopper, the hopper is provided with a breach to match with discharge port plate, the part that the discharge port plate is located at outside discharge bucket is provided with a micro actuator, the micro actuator includes the spacing valve block in insertion discharging groove and the leading screw lifter on spacing valve block, two inwall width of the width of the spacing valve block and the discharging groove match, a discharging chute is additionally provided with below the discharging groove, the charging aperture of the discharging chute is located at the front of the spacing valve block；The discharge port plate, stirring vane drive via external force rotate respectively.The utility model using rotating disc type be fed, can flexible modulation delivery rate, it is easy to use.

Description

A rotary disc type continuous micro-powder conveying device

technical field

The utility model relates to the field of powder technology, in particular to a rotary disc type continuous micro-powder conveying device.

Background technique

Granule and powder conveying and supplying devices are important production equipment or basic instruments in the granule and powder industry. Especially in fine processing and high-precision scientific research laboratories, continuous micro-quantity powder conveying and adding devices are in high demand.

The currently used feeding devices mainly include bar feeder, pendulum feeder, screw feeder and disc feeder. Among them, bar feeder, pendulum feeder and screw feeder have the advantages of simple structure and convenient maintenance. However, this type of feeder is suitable for large flow feeding, and the conveying accuracy of powder with small flow is not ideal.

The disc feeding device has simple structure, reliable operation, convenient adjustment and installation, and can realize a more uniform output of materials, and can easily adjust the output rate by adjusting the frequency of the motor. However, due to the large static friction between the disc and the bracket in a static state, a certain starting frequency is required when the feeding device is started, that is to say, there is a minimum feeding speed in the disc feeding device, which is not enough to satisfy Trace powder output requirements.

In addition, during the discharge process of the feeder, due to the adhesion, friction, bridging and other effects between the powders, the powder inside the hopper cannot move down continuously. Once a hollow is formed in the hopper, the discharge rate will increase. unevenness. Although the use of the stirring rod can reduce the occurrence of empty valleys in the hopper, since the discharge speed will change with the working conditions, if the stirring speed does not change accordingly, the compacted density of the powder in the hopper will change greatly under the action of stirring, and the powder The output mass rate of the volume thus deviates from the expected value.

Utility model content

The purpose of the utility model is to overcome the deficiencies of the prior art, meet the actual needs, and provide a rotary disc type continuous micro-powder conveying device.

In order to realize the purpose of the utility model, the technical scheme that the utility model adopts is:

A turntable type continuous micro-powder conveying device, comprising a hopper and a stirring blade located in the hopper, the bottom of the hopper is provided with a discharge plate, and the discharge plate is disc-shaped and has an annular discharge concave on the circumference A part of the discharge tray is located outside the hopper, and a gap matching the discharge tray is provided on the hopper, and a trimmer is provided on the part of the discharge tray located outside the hopper. The device includes a limit valve plate inserted into the discharge groove and a lead screw lifter located on the limit valve plate. The width of the limit valve plate matches the width of the two inner walls of the discharge groove. A discharge chute is also provided below the discharge groove, and the feed inlet of the discharge chute is located in front of the limit valve plate; the discharge plate and the stirring blade are respectively driven to rotate by external force.

The trimmer is arranged in the trim box.

A conical disk coaxial with the agitating blade and opening downward is provided above the agitating blade, and the outer diameter of the conical disk is not smaller than that of the agitating blade.

The vertical distance between the outer edge of the conical disc and the stirring blade is 0.5-2 times of the stirring diameter of the stirring blade.

The center of the conical disk is provided with a circular hole and is fitted on the upper part of the rotating shaft of the stirring blade through the circular hole. The conical disk of the utility model is in a static state during operation.

The rotating shafts of the discharge tray and the stirring blade are respectively driven to rotate by the output shafts of the first motor and the second motor, and the first motor and the second motor are respectively connected with the first frequency converter and the second frequency converter. Both the first frequency converter and the second frequency converter are connected with the controller.

The direction of rotation of the discharge tray is opposite to that of the stirring blades.

The speed of the second motor is (0.2-0.5) D ₁ /D ₂ times the speed of the first motor, where D ₁ and D ₂ are the outer diameter of the annular groove and the stirring diameter of the stirring blade, respectively.

The beneficial effects of the utility model are:

(1) The utility model adopts a turntable type feeding, and a limit valve plate that can adjust the insertion depth is set at the annular groove of the discharge tray, and the discharge rate can be further reduced or adjusted under a certain turntable operating speed condition, which can reduce the The minimum feeding speed limit brought by the starting frequency;

(2) Set stirring blades in the hopper to prevent hollows in the hopper. At the same time, the controller and frequency converter control the speed of the stirring blades to change synergistically with the speed of the discharge turntable. When hollows appear, it can effectively prevent the powder compaction density from being more uniform and make the output stable;

(3) A conical cap is set above the mixing blade to prevent the powder above the conical disk from producing gravity on the powder that is about to enter the discharge turntable near the discharge turntable, which can prevent the different filling heights in the hopper from affecting the material that is about to be discharged. The powder produces different degrees of pressure, resulting in differences in compaction density, which further ensures the uniformity of the output.

Description of drawings

Below in conjunction with accompanying drawing and embodiment example the utility model is described further.

Fig. 1 is the partial sectional structure schematic diagram of the utility model;

Fig. 2 is the enlarged schematic view of the connection between the trimmer and the first motor in Fig. 1;

Fig. 3 is a circuit control diagram of the utility model.

Among them, 1 hopper, 2 conical disc, 3 trimmer box, 4 trimmer, 41 lead screw lifter, 42 limit valve plate, 5 discharge channel, 6 discharge disc, 61 discharge groove, 7 first motor , 8 stirring blades, 9 second motors, 10 second frequency converters, 11 controllers, 12 first frequency converters.

Detailed ways

Below in conjunction with accompanying drawing and embodiment the utility model is further described:

See Figure 1-3.

The utility model discloses a turntable type continuous micro-powder conveying device, which comprises a hopper 1 and a stirring blade 8 located in the hopper 1. A discharge tray 6 is arranged at the bottom of the hopper 1, and the discharge tray 6 is a circle Disc-shaped and circumferentially provided with an annular discharge groove 61, a part of the discharge disk 6 is located outside the hopper 1, and a gap matching the discharge disk 6 is provided on the hopper 1, the discharge The part of the disc 6 located outside the discharge hopper 1 is provided with a trimmer 4, the trimmer 4 includes a limit valve plate 42 inserted into the discharge groove 61 and a lead screw lifter 41 positioned on the limit valve plate. The width of the limit valve plate 42 matches the width of the two inner walls of the discharge groove 61, and a discharge chute 5 is also provided below the discharge groove 61, and the feed port of the discharge chute 5 Located in front of the limit valve plate 42; the discharge tray 6 and the stirring blade 8 are respectively driven to rotate by external force.

The operating principle of the utility model is briefly described as follows:

The powder material is put into the hopper 1 from the top of the hopper 1, stirred by the stirring blade 8 in the hopper 1, and part of the material falls into the discharge groove 61 of the discharge tray 6. The hopper 1 is provided with a The matching gap of the disc 6 is used for the rotation of the discharge disc 6. The width of the gap is consistent with the width of this part of the discharge disc 6, and the height is consistent with the height of the discharge disc 6. Therefore, the powder is rotated by the discharge disc 6 through the gap. After sending out, it will be scraped off by the gap, that is, the upper surface of the powder in the discharge groove 61 is scraped off so that both sides of the discharge groove are even, and the excess powder remains in the hopper. The part outside the hopper 1 in the discharge groove 61 is provided with a trimmer 4 , and the trimmer 4 is arranged in the trimmer box 3 . When the powder is transported to the position of the trimmer 4, since the limit valve plate 42 is inserted into the discharge groove 61, as the discharge disc 6 rotates, the powder will overflow from the front of the limit valve plate 42 and enter The feed port of the discharge chute 5 is sent out through the discharge chute 5 to realize the transportation and supply of powder.

The limit valve plate 42 can be partially or completely inserted into the discharge groove 61 . In this embodiment, the limit valve plate 42 is inserted into 1/2 of the depth of the discharge groove 61 at the beginning, and the depth is adjusted by the lead screw lifter 41 .

Above the stirring blade 8 is provided a conical disk 2 coaxial with it and opening downward, the outer diameter of the conical disk 2 is not smaller than the outer diameter of the stirring blade 8 . A conical disc 2 is set on the 8th side of the stirring blade to prevent the powder above the conical disc 2 from exerting pressure on the powder that is about to enter the discharge disc 6 near the discharge disc 6, which can prevent the impact of different charging heights in the hopper on the upcoming The discharged powder produces different degrees of pressure, resulting in differences in compaction density, which further ensures the uniformity of the discharge.

The vertical distance between the outer edge of the conical disk 2 and the stirring blade 8 is 0.5 to 2 times the stirring diameter of the stirring blade 8, and in this embodiment it is 1 time, that is, the distance between the two is equal to the stirring diameter.

The center of the conical disk 2 is provided with a circular hole and is set on the upper part of the rotating shaft of the stirring blade 8 through the circular hole, and the conical disk 2 is in a static state.

The rotating shafts of the discharge tray 6 and the stirring blade 8 are driven to rotate by the output shafts of the first motor 7 and the second motor 9 respectively, and the first motor 7 and the second motor 9 are connected with the first frequency converter 12 and the second motor respectively. The frequency converter 10 is connected, and the first frequency converter 12 and the second frequency converter 10 are both connected with the controller 11 .

The rotation directions of the first motor 7 and the second motor 9 are opposite.

And the rotation speed of the second motor 9 is (0.2~0.5) D ₁ /D ₂ times of the rotation speed of the first motor 7 , wherein D ₁ and D ₂ are respectively the outer diameter of the annular groove 61 and the stirring diameter of the stirring blade 8 . In the example, it is 0.3D ₁ /D ₂ , D ₁ =15cm, D ₂ =30cm.

The signal from the first frequency converter 12 is transmitted to the controller 11, and the controller 11 performs calculation and judgment, and then transmits the signal to the second frequency converter 10 for storage, and at the same time, the controller 11 can recall the stored data.

When the device is in operation, firstly, the required rotational speed of the discharge tray 6 is set by adjusting the first frequency converter 12 . For example, the corresponding relationship between the first inverter 12 and the first motor 7 is 3Hz~10rad/min (that is, every time the inverter increases by 3 Hz, the speed of the first motor 7 increases by 1 revolution per second), here set the first The frequency of the frequency converter 12 is 30 Hz, and the corresponding rotating speed of the discharge tray 6 is 100 rad/min. At the same time, the signal of the first frequency converter 12 is transmitted to the controller 11, and the controller 11 controls the output frequency of the second frequency converter 10, as in this example, the corresponding relationship between the second frequency converter 10 and the second motor 9 is 4Hz~10rad/min, the rotation speed of the stirring blade 8 is 0.3D ₁ /D ₂ =0.15 times of the rotation speed of the discharge tray 6, the controller 11 sets the output frequency of the second frequency converter 10 to 100rad/min×0.15×0.4=6Hz So that the rotating speed of the stirring blade 8 is 100rad/min×0.15=15rad/min. At the same time, the controller 11 will store the settings of the first frequency converter 12 and the second frequency converter 10 and set them as initial values when starting up.

The setting of the stirring blade 8 is used to prevent the hollowing problem caused by the powder in the hopper 1 not being able to move downward continuously due to adhesion, friction, bridging and other effects. At the same time, the controller 11 and the second frequency converter 10 control the operating speed of the stirring blade 8 to change synergistically with the operating speed of the discharge tray 6, while ensuring that there is no hollowing in the hopper 1, it can effectively prevent the powder from being damaged. The stirring action that is not in harmony with the output speed makes the compacted density of the powder more uniform and the output stable.

When the discharge condition needs to change, for example, the rotating speed of the discharge tray 6 needs to be 30 rad/min, then the output frequency of the first frequency converter 12 is set to 9 Hz. Since the location of the first motor 7 is subject to a relatively large frictional effect, the start of the first motor 7 needs to meet the minimum starting frequency. For example, in this example, the starting frequency of the first motor 7 is 10 Hz, so the first motor 7 is in the first frequency converter 12 The output frequency is 9Hz and cannot run. Therefore, the first frequency converter 12 needs to keep working at the lowest frequency, namely 10 Hz. Then, move the limit valve plate 42 by operating the knob on the lead screw lifter 41, so that the depth of the limit valve plate 42 inserted into the discharge groove 61 increases: (1-9Hz/10Hz)×100%=10%, The required discharge speed can be achieved under the condition of the lowest starting frequency, which breaks through the limitation of the lower limit of the discharge rate brought by the starting frequency of the motor.

The above is only an embodiment of the utility model, and does not limit the patent scope of the utility model. All equivalent transformations made by using the specification of the utility model and the contents of the accompanying drawings or directly or indirectly used in related technical fields are all the same. Included in the patent protection scope of the present utility model.

Claims (8)

1. a kind of rotating disc type continuous micro powder transfer device, including hopper (1), the stirring vane (8) in hopper (1), It is characterized in that：The bottom of the hopper (1) is provided with discharge port plate (6), and the discharge port plate (6) is that discoid and circumference is provided with annular Discharging groove (61), the part of the discharge port plate (6) is located at the outside of hopper (1), the hopper (1) be provided with one with The breach that discharge port plate (6) matches, the discharge port plate (6) are located at the outside part of discharge bucket (1) and are provided with a micro actuator (4), The micro actuator (4) includes the spacing valve block (42) in insertion discharging groove (61) and the leading screw lifter on spacing valve block (41), the width of the spacing valve block (42) and two inwall width of the discharging groove (61) match, the discharging groove (61) discharging chute (5) is additionally provided with below, the charging aperture of the discharging chute (5) is located at the spacing valve block (42) Front；The discharge port plate (6), stirring vane (8) drive via external force rotate respectively.

2. rotating disc type continuous micro powder transfer device according to claim 1, it is characterised in that：The micro actuator (4) It is arranged in micro adjusting box (3).

3. rotating disc type continuous micro powder transfer device according to claim 1, it is characterised in that：The stirring vane (8) top is not less than the stirring provided with the conical disc (2) being coaxial therewith and Open Side Down, the external diameter of the conical disc (2) The external diameter of blade (8).

4. rotating disc type continuous micro powder transfer device according to claim 3, it is characterised in that：The conical disc (2) Outer rim and the vertical range of stirring vane (8) are 0.5~2 times that stirring vane (8) stirs diameter.

5. rotating disc type continuous micro powder transfer device according to claim 3, it is characterised in that：The conical disc (2) Center is provided with circular hole and is sleeved on the rotating shaft top of stirring vane (8) by circular hole, utility model conical disc in the process of running (2) it is in inactive state.

6. rotating disc type continuous micro powder transfer device according to claim 1, it is characterised in that：The discharge port plate (6), The rotating shaft of stirring vane (8) is driven by the output shaft of the first motor (7), the second motor (9) rotate respectively, first motor (7), the second motor (9) is connected with the first frequency converter (12), the second frequency converter (10) respectively, first frequency converter (12), Two frequency converters (10) are connected with controller (11).

A kind of 7. rotating disc type continuous micro powder transfer device according to claim 5, it is characterised in that：The discharge port plate (6) it is opposite with the rotation direction of stirring vane (8).

A kind of 8. rotating disc type continuous micro powder transfer device according to claim 6, it is characterised in that：Second motor (9) rotating speed is the first motor (7) rotating speed (0.2~0.5) D₁/D₂Times, wherein D₁、D₂Respectively annular groove (61) is outer Footpath and the stirring diameter of stirring vane (8).