CN219401615U - Output device for kitchen waste solid-liquid separator - Google Patents

Abstract

The utility model discloses an output device for a kitchen waste solid-liquid separator, which comprises: the output cylinder is communicated with the output port of the solid-liquid separator, and a discharge port is formed in the side wall of one end, far away from the solid-liquid separator, of the output cylinder in a penetrating manner; the conveying shaft is sleeved in the output cylinder; the scattering column casing is sleeved on the side wall of one end, far away from the solid-liquid separator, of the conveying shaft; the blocking dispersing cylinder is arranged on one side of the dispersing column cylinder far away from the solid-liquid separator, and is sleeved on the side wall of the conveying shaft, so that the blocking dispersing cylinder can reduce the sliding speed of materials; wherein, form into the holding district that is used for holding the material between the scattered section of thick bamboo of separation and the column casing that breaks up, the scattered section of thick bamboo of separation can be followed the conveying shaft lateral wall and slided in order to adjust the width that holds the district. Through the technical scheme, the discharged garbage can not be greatly agglomerated or caked, and the operation efficiency is greatly improved.

Description

Output device for kitchen waste solid-liquid separator

Technical Field

The utility model relates to the field of garbage treatment equipment, in particular to an output device for a kitchen garbage solid-liquid separator.

Background

Along with the development of social economy and the improvement of the living standard of people, the quantity of kitchen and fruit and vegetable garbage is rapidly increased, and a horizontal or vertical solid-liquid separator is generally adopted in the prior art for carrying out solid-liquid separation on the kitchen and fruit and vegetable garbage, but the solid-liquid separator in the prior art has poor solid-liquid separation effect, dead angles exist in separation, and some kitchen and fruit and vegetable garbage are located in the device for a long time and are not easy to discharge, rot and smell.

To this problem, in prior art like the patent document of application number CN201910165857.1, it discloses a be difficult for vertical solid-liquid separator for kitchen, fruit vegetables rubbish of jam, and it is through being hemispherical structure with the extrusion piece, and kitchen, fruit vegetables rubbish after the extrusion slip out the discharge gate from the arcwall face, be difficult for forming ejection of compact dead angle.

Although the above patent document solves the problem of residue of garbage in the solid-liquid separator during the separation process, there is a limitation in discharging garbage, because kitchen and fruit and vegetable garbage are often put into a fermenter to ferment after being subjected to solid-liquid separation (for example, patent document CN201810470151.1 discloses a kitchen garbage treatment device which describes such an operation mode), but garbage is compressed into a block shape when being subjected to solid-liquid separation in the solid-liquid separator, then put into a conveying device, and then sent to the fermenter through the conveying device, and in this process, the block-shaped garbage is further compressed by the conveying device, so that the finally discharged garbage is mostly in a compact shape or block shape, and a lot of time is required for dispersion stirring to perform the fermentation operation, thereby affecting the operation efficiency.

Disclosure of Invention

Aiming at the prior art, the utility model aims to solve the problems that the discharged garbage is easy to accumulate and is in a mass shape or a block shape in the prior art, thereby providing the output device for the kitchen garbage solid-liquid separator, which can avoid mass agglomeration of garbage and improve the operation efficiency and garbage treatment effect.

In order to achieve the above object, the present utility model provides an output device for a kitchen waste solid-liquid separator, comprising:

the output cylinder is communicated with the output port of the solid-liquid separator, and a discharge port is formed in the side wall of one end, far away from the solid-liquid separator, of the output cylinder in a penetrating way;

the conveying shaft is sleeved in the output cylinder and can guide materials entering the output cylinder from the output port to be discharged;

the scattering column casing is sleeved on the side wall of one end, far away from the solid-liquid separator, of the conveying shaft, and can rotate along with the conveying shaft and scatter materials sliding along the output cylinder;

the blocking dispersing cylinder is arranged on one side, far away from the solid-liquid separator, of the dispersing column cylinder, is sleeved on the side wall of the conveying shaft and can reduce the sliding speed of materials;

the separation scattering cylinder and the scattering column cylinder are formed into a containing area for containing materials, and the separation scattering cylinder can slide along the side wall of the conveying shaft to adjust the width of the containing area.

Preferably, the output cylinder comprises a guide cylinder communicated with the output port of the solid-liquid separator, one end of the guide cylinder, which is far away from the solid-liquid separator, is connected with a scattering cylinder, and a scattering cylinder is sleeved in the scattering cylinder;

the conveying shaft comprises a shaft body sleeved in the output cylinder, a spiral sheet is sleeved on the side wall of the shaft body, the spiral sheet extends into the dispersing cylinder far away from the solid-liquid separator, and a step sleeve is sleeved on the side wall of one end of the shaft body far away from the solid-liquid separator.

Preferably, the dispersing cylinder comprises a guide section and a dispersing section which are sequentially arranged along the flow direction of the material;

the inner diameter of the guide section is equal to the outer diameter of the spiral piece, and the inner diameter of the dispersion section is larger than the inner diameter of the guide section.

Preferably, the scattering column casing comprises a mounting sleeve which is positioned in the scattering column casing and sleeved on the side wall of the step sleeve, and a plurality of scattering columns which are annularly arranged on the side wall of the mounting sleeve.

Preferably, the blocking and dispersing cylinder comprises a sliding gas ring sleeved on the side wall of the step sleeve in a sliding manner, the sliding gas ring is arranged on one side, far away from the solid-liquid separator, of the dispersing cylinder, and a plurality of deceleration columns are arranged on the side wall of the sliding gas ring.

Preferably, the spacing between adjacent ones of the deceleration columns is smaller than the spacing between adjacent ones of the fan-out columns.

Preferably, the deceleration column is disposed on a side wall of the sliding gas ring, and a center line in a thickness direction of the deceleration column and a center line in a length direction of the sliding gas ring form a set angle.

Preferably, both sides in the length direction of the deceleration column are provided with inclined planes.

Preferably, the surface of each deceleration column is provided with a through groove, at least one through groove is internally provided with a limiting cylinder, a stirring column is sleeved in the limiting cylinder in a sliding manner, and one end of each stirring column, which is close to the scattering column cylinder, is fixedly connected with the corresponding scattering column side wall of each through groove.

Preferably, the side wall of one end of the step sleeve far away from the solid-liquid separator is sleeved with an inflation ring, the surface of the inflation ring is provided with a plurality of piston columns arranged on the side wall of the step sleeve, and the movable end of each piston column is connected with the sliding gas ring.

According to the technical scheme, the scattering operation of the materials before discharge can be realized through the cooperation of the scattering column casing and the blocking scattering cylinder, when the solid-liquid separator is implemented, after the liquid separation operation of the materials is completed, the materials can enter the output cylinder, the conveying shaft can guide the materials in the output cylinder to be discharged, when the materials move towards the discharge port, the scattering column casing can be contacted with the materials firstly to enable the scattered materials to be continuously moved along with the continuous movement of the materials towards the discharge port, and when the materials contact the blocking scattering cylinder, the moving speed of the materials is reduced, namely the residence time of the materials in the containing area is prolonged, so that the scattering efficiency of the materials is improved, and meanwhile, the blocking scattering cylinder can slide along the side wall of the conveying shaft to adjust the width of the containing area, so that the scattering efficiency of the materials can be adjusted.

Additional features and advantages of the utility model will be set forth in the detailed description which follows.

Drawings

The accompanying drawings are included to provide a further understanding of the utility model, and are incorporated in and constitute a part of this specification, illustrate the utility model and together with the description serve to explain, without limitation, the utility model. In the drawings:

fig. 1 is a schematic diagram of a structure in which an output device for a kitchen waste solid-liquid separator is mounted on the solid-liquid separator;

FIG. 2 is a schematic view of a scattering cylinder according to the present utility model;

FIG. 3 is a schematic view of the structure of the inflatable ring provided by the utility model;

fig. 4 is a schematic structural view of a deceleration column provided by the present utility model;

FIG. 5 is a schematic view of the structure of a guide section provided by the present utility model;

FIG. 6 is a schematic view of the structure of the scattering cylinder provided by the utility model;

fig. 7 is a schematic structural view of a through slot according to the present utility model.

Description of the reference numerals

1-an output cylinder; 2-scattering the column casing; 3-blocking the powder cylinder; 4-a discharge port; 5-a guide cylinder; 6-a scattering cylinder; 7-a dispersing cylinder; 8-a shaft body; 9-spiral sheets; 10-a dispersion section; 11-a guide section; 12, installing a sleeve; 13-a scatter column; 14-sliding gas ring; 15-a deceleration column; 16-a through slot; 17-defining a cartridge; 18-stirring the column; 19-inflating ring; 20-piston column.

Detailed Description

The following describes specific embodiments of the present utility model in detail. It should be understood that the detailed description and specific examples, while indicating and illustrating the utility model, are not intended to limit the utility model.

As shown in fig. 1 to 7, the utility model provides an output device for a kitchen waste solid-liquid separator. The following is a further description of specific examples.

Specifically, the output device for the kitchen waste solid-liquid separator comprises:

the output cylinder 1 is connected to an output port of the solid-liquid separator, and a side wall of one end, far away from the solid-liquid separator, of the output cylinder 1 is provided with a discharge port 4;

the conveying shaft is sleeved in the output cylinder 1 and can guide materials entering the output cylinder 1 from the output port to be discharged;

the scattering column casing 2 is sleeved on the side wall of one end, far away from the solid-liquid separator, of the conveying shaft, and the scattering column casing 2 can rotate along with the conveying shaft and scatter materials sliding along the output cylinder 1;

the blocking and dispersing cylinder 3 is arranged on one side of the scattering column casing 2 far away from the solid-liquid separator, the blocking and dispersing cylinder 3 is sleeved on the side wall of the conveying shaft, and the blocking and dispersing cylinder 3 can reduce the sliding speed of materials;

wherein, the separation is scattered and is equipped with the holding district that is used for holding the material between section of thick bamboo 2 with scattering, and the separation is scattered section of thick bamboo 3 and can be followed the conveying shaft lateral wall and slided in order to adjust holding district width.

The material in the utility model refers to kitchen waste.

According to the utility model, the scattering operation of the materials before discharge can be realized through the cooperation of the scattering column casing 2 and the blocking scattering cylinder 3, when the solid-liquid separator is implemented, after the liquid separation operation of the materials is completed, the materials can enter the output cylinder 1, then the conveying shaft can guide the materials in the output cylinder 1 to be discharged, when the materials move towards the discharge port 4, the scattering column casing 2 can be contacted with the materials firstly to be scattered, then the scattered materials are pushed to move continuously along with the continuous movement of the materials towards the discharge port 4, and when the materials contact the blocking scattering cylinder 3, the moving speed of the materials is reduced, namely the residence time of the materials in the accommodating area is prolonged, so that the scattering efficiency of the materials is improved, and meanwhile, the blocking scattering cylinder 3 can slide along the side wall of the conveying shaft to adjust the width of the accommodating area, so that the scattering efficiency of the materials can be adjusted.

In order that the materials can be scattered to a certain extent rather than blocked in the accommodating area when passing through the scattering column casing 2, the output casing 1 preferably comprises a guide casing 5 connected with the output port of the solid-liquid separator, one end of the guide casing 5, which is far away from the solid-liquid separator, is connected with a scattering casing 6, and a scattering casing 7 is sleeved in the scattering casing 6;

the conveying shaft comprises a shaft body 8 sleeved in the output cylinder 1, a spiral sheet 9 is sleeved on the side wall of the shaft body 8, the spiral sheet 9 is far away from the solid-liquid separator and extends into the dispersing cylinder 7, and a step sleeve is sleeved on the side wall of one end, far away from the solid-liquid separator, of the shaft body 8.

In this embodiment, the shaft body 8 can be driven to rotate by external clicking, and the working principle of the shaft body 8 and the spiral sheet 9 is the working principle of the spiral propeller.

When the conveying shaft conveys materials, the materials can enter the guide cylinder 5 from the output port of the solid-liquid separator, and the materials entering the guide cylinder 5 can be driven by the spiral sheet 9 rotating along with the shaft body 8 to be sent into the dispersing cylinder 7.

A guide section 11 and a dispersion section 10 which are sequentially arranged in the dispersion cylinder 7 along the material flow direction;

the inner diameter of the guiding section 11 is equal to the outer diameter of the spiral piece 9, and the inner diameter of the dispersing section 10 is larger than the inner diameter of the guiding section 11.

When the material is fed into the dispersing cylinder 7, the material is fed from the guide section 11 to the dispersing section 10, and part of the material remains in the dispersing section 10 due to the large inner diameter of the dispersing section 10.

In order to realize the operation of scattering materials, the scattering column casing 2 is further defined as follows: the scattering column casing 2 comprises a mounting sleeve 12 which is positioned in the scattering and sleeved on the side wall of the step sleeve, and a plurality of scattering columns 13 are annularly arranged on the side wall of the mounting sleeve 12.

When the material remains in the dispersing section 10, the rotating shaft body 8 not only can drive the spiral sheet 9, but also can drive the step sleeve to rotate, the rotating step sleeve can drive a plurality of dispersing columns 13 on the mounting sleeve 12 to rotate, and then the rotating dispersing columns 13 can scatter the material remaining in the dispersing section 10.

As more and more material enters the dispersion section 10, the blocking barrel 3 is further defined for the purpose of blocking the flow rate of the material: the separation barrel 3 comprises a sliding gas ring 14 which is sleeved on the side wall of the step sleeve in a sliding manner, the sliding gas ring 14 is arranged on one side of the separation barrel 2 far away from the solid-liquid separator, and a plurality of deceleration columns 15 are arranged on the side wall of the sliding gas ring 14.

The spacing between adjacent deceleration columns 15 is smaller than the spacing between adjacent diffusing columns 13.

When the rotating dispersing column 13 disperses the material remained in the dispersing section 10, the sliding air ring 14 is driven by the step sleeve, so that the plurality of deceleration columns 15 rotate at the same speed and time as the dispersing column 13, that is, the dispersing column 13 and the deceleration column 15 synchronously move at the same speed, so that the material is not directly pushed into the discharge port 4 when being pushed to the region of the deceleration column 15, but is discharged after being blocked by the plurality of deceleration columns 15 and dispersed again.

Because the interval between the adjacent deceleration columns 15 is small, the time between the materials passing through the adjacent deceleration columns 15 is smaller than the time between the adjacent scattering columns 13, and the existence of the deceleration columns 15 can obstruct the flow of the materials, but the interval between the adjacent deceleration columns 15 can not appear that the materials are completely blocked and cannot move.

The deceleration column 15 is provided on the side wall of the sliding gas ring 14, and a center line in the thickness direction of the deceleration column 15 and a center line in the length direction of the sliding gas ring 14 form a set angle.

The setting angle is between 0 and 90 degrees, and fig. 6 shows a situation that the setting angle is 0 degrees, and the setting angle can enable the resistance applied by the deceleration column 15 when contacting with the material to be different, if the setting angle is 0 degrees, the resistance applied by the deceleration column 15 when contacting with the material is minimum, namely the resistance is minimum, and if the setting angle is 90 degrees (namely parallel to the axis line of the shaft body 8), the resistance applied by the deceleration column 15 when contacting with the material is maximum, namely the resistance is maximum.

Both sides in the length direction of the deceleration column 15 are provided with inclined planes. The arrangement is to break the material easily by the deceleration column 15 when contacting the deceleration column 15, and the material is not easily pushed away by the deceleration column 15, if the material is pushed away by the deceleration column 15, the deceleration column 15 is easy to bend.

In order to increase the dispersion efficiency, the speed reducing columns 15 are further optimized, specifically, the surface of each speed reducing column 15 is provided with a through groove 16, at least one through groove 16 is internally provided with a limiting cylinder 17, a stirring column 18 is sleeved in the limiting cylinder 17 in a sliding manner, and one end of each stirring column 18, which is close to the scattering column casing 2, is fixedly connected with the side wall of the scattering column 13 corresponding to each through groove 16.

In this embodiment, the specific number of the stirring columns 18 may be set according to actual requirements, four stirring columns 18 are set in the figure, and one stirring column 18 is hereinafter illustrated, and each stirring column 18 has one deceleration column 15 and one dispersing column 13 correspondingly supported.

When the speed reducing column 15 moves along with the dispersing column 13, the stirring column 18 is driven to rotate around the shaft body 8 in the accommodating area, and the stirring column 18 further disperses the materials in the accommodating area in the process of rotating, so that the dispersing efficiency of the materials is higher.

For the purpose of driving the blocking cylinder 3 to slide along the side wall of the conveying shaft to adjust the width of the accommodating area: the side wall of one end of the step sleeve, which is far away from the solid-liquid separator, is sleeved with an inflatable ring 19, the surface of the inflatable ring 19 is provided with a plurality of piston columns 20 arranged on the side wall of the step sleeve, and the movable end of each piston column 20 is connected with the sliding gas ring 14.

In this embodiment, the inflation mode of the inflation ring 19 may be selected from inflation modes of bicycle tires, and in specific implementation, the surface of the output cylinder 1 is provided with an inflation head insertion port, and the sidewall of the inflation ring 19 is provided with a plurality of insertion ports corresponding to sidewalls of bicycle tires.

(if the width of the accommodating area needs to be adjusted, the rotation of the shaft body 8 is stopped firstly, and the rotation of the shaft body 8 can be driven by an external motor, so that only the rotation of the stop motor can be used at the moment), when the gas is injected into the gas charging ring 19, all the piston columns 20 can be charged, then the movable ends of all the piston columns 20 can push the sliding gas ring 14 to slide towards one side of the solid-liquid separator along the side wall of the step sleeve at the same time, and then the sliding gas ring 14 can move together with all the deceleration columns 15, and in the process, the deceleration columns 15 provided with the limiting cylinders 17 can slide along the side wall of the stirring columns 18 along with the limiting cylinders 17, so that the length of the stirring columns 18 in the accommodating area is reduced.

When the gas in the gas-filled ring 19 is drawn out, all the piston columns 20 are exhausted, the sliding gas ring 14 slides along the side wall of the step cover towards the side far away from the solid-liquid separator, and the length of the stirring column 18 in the accommodating area is increased.

The working principle of the utility model is as follows:

when the conveying shaft conveys materials, the materials can enter the guide cylinder 5 from the output port of the solid-liquid separator, the materials entering the guide cylinder 5 can be driven by the spiral sheet 9 rotating along with the shaft body 8 to be conveyed into the dispersing cylinder 7, and when the materials are conveyed into the dispersing cylinder 7, the materials can be conveyed from the guide section 11 to the dispersing section 10, and due to the fact that the inner diameter of the dispersing section 10 is larger, part of the materials can be reserved in the dispersing section 10.

When the material remains in the dispersing section 10, the rotating shaft body 8 not only can drive the spiral sheet 9, but also can drive the step sleeve to rotate, the rotating step sleeve can drive a plurality of dispersing columns 13 on the mounting sleeve 12 to rotate, and then the rotating dispersing columns 13 can scatter the material remaining in the dispersing section 10.

When the rotating dispersing column 13 disperses the material remained in the dispersing section 10, the sliding air ring 14 is driven by the step sleeve, so that the plurality of deceleration columns 15 rotate at the same speed and time as the dispersing column 13, that is, the dispersing column 13 and the deceleration column 15 synchronously move at the same speed, so that the material is not directly pushed into the discharge port 4 when being pushed to the region of the deceleration column 15, but is discharged after being blocked by the plurality of deceleration columns 15 and dispersed again.

And when the speed reducing column 15 moves along with the dispersing column 13, the stirring column 18 is driven to rotate around the shaft body 8 in the accommodating area, and the stirring column 18 further disperses the materials in the accommodating area in the process of rotating, so that the dispersing efficiency of the materials is higher.

The preferred embodiments of the present utility model have been described in detail above, but the present utility model is not limited to the specific details of the above embodiments, and various simple modifications can be made to the technical solution of the present utility model within the scope of the technical concept of the present utility model, and all the simple modifications belong to the protection scope of the present utility model.

In addition, the specific features described in the above embodiments may be combined in any suitable manner, and in order to avoid unnecessary repetition, various possible combinations are not described further.

Moreover, any combination of the various embodiments of the utility model can be made without departing from the spirit of the utility model, which should also be considered as disclosed herein.

Claims (10)

1. The utility model provides a kitchen garbage output device for solid-liquid separator which characterized in that, kitchen garbage output device for solid-liquid separator includes:

the output cylinder (1) is communicated with an output port of the solid-liquid separator, and a discharge port (4) is formed in the side wall of one end, far away from the solid-liquid separator, of the output cylinder (1) in a penetrating manner;

the conveying shaft is sleeved in the output cylinder (1) and can guide materials entering the output cylinder (1) from an output port to be discharged;

the scattering column casing (2) is sleeved on the side wall of one end, far away from the solid-liquid separator, of the conveying shaft, and the scattering column casing (2) can rotate along with the conveying shaft and scatter materials sliding along the output cylinder (1);

the blocking dispersing cylinder (3) is arranged on one side, far away from the solid-liquid separator, of the dispersing column casing (2), the blocking dispersing cylinder (3) is sleeved on the side wall of the conveying shaft, and the blocking dispersing cylinder (3) can reduce the sliding speed of materials;

the separating and scattering cylinder (3) and the scattering cylinder (2) form a containing area for containing materials, and the separating and scattering cylinder (3) can slide along the side wall of the conveying shaft to adjust the width of the containing area.

2. The output device for the kitchen waste solid-liquid separator according to claim 1, wherein the output cylinder (1) comprises a guide cylinder (5) communicated with an output port of the solid-liquid separator, one end, far away from the solid-liquid separator, of the guide cylinder (5) is connected with a scattering cylinder (6), and a scattering cylinder (7) is sleeved in the scattering cylinder (6);

the conveying shaft comprises a shaft body (8) sleeved in the output cylinder (1), a spiral sheet (9) is sleeved on the side wall of the shaft body (8), the spiral sheet (9) is far away from the solid-liquid separator and extends into the dispersing cylinder (7), and a step sleeve is sleeved on the side wall of one end of the shaft body (8), far away from the solid-liquid separator.

3. The output device for a kitchen waste solid-liquid separator according to claim 2, characterized in that the dispersion cylinder (7) comprises a guide section (11) and a dispersion section (10) which are arranged in sequence along the material flow direction;

the inner diameter of the guiding section (11) is equal to the outer diameter of the spiral sheet (9), and the inner diameter of the dispersing section (10) is larger than the inner diameter of the guiding section (11).

4. A kitchen waste solid-liquid separator output device according to claim 2 or 3, characterized in that the scattering column casing (2) comprises a mounting sleeve (12) which is positioned in the scattering column casing (7) and is sleeved on the side wall of the step sleeve, and a plurality of scattering columns (13) which are annularly arranged on the side wall of the mounting sleeve (12).

5. The output device for the kitchen waste solid-liquid separator according to claim 4, wherein the separation dispersing cylinder (3) comprises a sliding gas ring (14) sleeved on the side wall of the step sleeve in a sliding manner, the sliding gas ring (14) is arranged on one side, far away from the solid-liquid separator, of the dispersing cylinder (2), and a plurality of deceleration columns (15) are arranged on the side wall of the sliding gas ring (14).

6. Output device for a solid-liquid separator for kitchen waste according to claim 5, characterized in that the spacing between adjacent deceleration columns (15) is smaller than the spacing between adjacent fan-out columns (13).

7. The output device for a solid-liquid separator for kitchen waste according to claim 5, wherein the deceleration column (15) is provided on a side wall of the sliding gas ring (14), and a center line in a thickness direction of the deceleration column (15) and a center line in a longitudinal direction of the sliding gas ring (14) form a set angle.

8. Output device for a solid-liquid separator for kitchen waste according to claim 6 or 7, characterized in that both sides in the length direction of the reduction column (15) are provided with inclined planes.

9. The output device for the kitchen waste solid-liquid separator according to claim 8, wherein a through groove (16) is formed in the surface of each deceleration column (15), a limiting cylinder (17) is installed in at least one through groove (16), a stirring column (18) is slidably sleeved in the limiting cylinder (17), and one end, close to the scattering column casing (2), of each stirring column (18) is fixedly connected with the side wall of the scattering column (13) corresponding to each through groove (16).

10. The output device for the kitchen waste solid-liquid separator according to claim 5, wherein an inflatable ring (19) is sleeved on the side wall of one end of the step sleeve, which is far away from the solid-liquid separator, a plurality of piston columns (20) which are arranged on the side wall of the step sleeve are arranged on the surface of the inflatable ring (19), and the movable end of each piston column (20) is connected with the sliding gas ring (14).