CN210884333U - Quantitative subpackaging device - Google Patents

Abstract

The embodiment of the application provides a quantitative subpackaging device, and relates to the technical field of processing equipment. The quantitative subpackaging device comprises a material bin for containing materials to be subpackaged; the rotating device comprises a rotating shaft and at least one rotating handle, one end of the rotating handle is arranged on the rotating shaft, and the rotating device is arranged above the material bin; at least one ladling device, the ladling device set up in the one end of changeing the handle, be used for when change rotate to the low level, the ladling device follow the material of default capacity is ladled out in the material storehouse, when change rotate to the high level, the ladling device pours the material into the discharge gate, has accomplished the quantitative partial shipment of material. This ration partial shipment device has reduced the cost of labor, improves the efficiency of material ration partial shipment.

Description

Quantitative subpackaging device

Technical Field

The application relates to the technical field of processing equipment, in particular to a quantitative subpackaging device.

Background

At present, the black soldier fly breeding technology is promoted more and more due to a plurality of advantages. The black soldier fly is a saprophytic soldier fly, can eat livestock and poultry excrement and domestic garbage, produces high-value animal protein feed, and can be recycled due to the characteristics of rapid propagation, large biomass, wide feeding range, high absorption conversion rate, easy management, low feeding cost, good animal palatability and the like.

Among the prior art, heisui river horsefly breeding bait is livestock manure and surplus rubbish in kitchen, and all adopt the manual work to carry out quantitative partial shipment to heisui river horsefly breeding bait at present, and the heisui river horsefly breeding bait that will join in marriage is uninstalled to in the middle of the transfer material basin, and the manual work of reuse is in proper order partial shipment to each breed in the middle of the basin. However, the manual installation is adopted, so that the labor cost is high and the efficiency is low; and the subpackaging process is discontinuous, the weight of each pot of black soldier fly breeding bait cannot be accurately controlled, the weight of each pot of breeding bait cannot be ensured to be equal, and the quality of the black soldier fly breeding finished products is finally influenced. In addition, harmful waste gas is dissipated in the process of quantitatively subpackaging the black soldier fly breeding bait, and the damage to the physical and mental health of close-distance operators is great.

SUMMERY OF THE UTILITY MODEL

An object of the embodiment of this application is to provide a ration partial shipment device, this ration partial shipment device can reduce the cost of labor, improves the efficiency of material ration partial shipment.

The embodiment of the application provides a quantitative subpackaging device which comprises a material bin and a material storage bin, wherein the material bin is used for containing materials to be subpackaged; the rotating device comprises a rotating shaft and at least one rotating handle, one end of the rotating handle is arranged on the rotating shaft, and the rotating device is arranged above the material bin; at least one ladling device, the ladling device set up in the one end of changeing the handle, be used for when change rotate to the low level, the ladling device follow the material of default capacity is ladled out in the material storehouse, when change rotate to the high level, the ladling device pours the material into the discharge gate to accomplish the quantitative partial shipment of material.

At above-mentioned realization in-process, this ration partial shipment device can be applied to the automatic ration partial shipment of material, for example realizes the automatic ration partial shipment to black soldier fly breeding bait. The quantitative subpackaging device comprises a material bin, a rotator and at least one material scooping device, wherein the material scooped by the material scooping device in each time has equal volume in the rotating process, so that the quantitative subpackaging in the subpackaging process is realized, the labor cost is reduced, and the quantitative subpackaging efficiency of the material is improved; on the other hand, the accurate control of the volume or the weight of each subpackaged material is realized. In addition, the bait emission waste gas is easy to be collected in a closed way, so that physical and psychological harm to workers is avoided. In addition, when the device is applied to automatic quantitative subpackage of the black soldier fly bait, the waste gas emitted by the bait is easy to collect in a sealed manner, workers do not need to directly contact the bait, and the physical and psychological harm to the workers is avoided.

Further, said device comprises 4 said scoopers, said rotator comprises 4 said rotating handles, and 4 said rotating handles are perpendicular to each other.

In the implementation process, the device comprises 4 scoopers and 4 rotating handles, wherein the 4 scoopers are respectively arranged at one end of the 4 rotating handles, so that when the rotating device rotates, the rotating device can drive the 4 scoopers to rotate; moreover, the 4 rotating handles are mutually vertical, and the working ranges of the 4 ladles are separated, so that each ladle has a sufficient working range, and the mutual influence of quantitative subpackaging of materials by the ladles is avoided; on the other hand, 4 ladles can furthest guarantee quantitative partial shipment device's partial shipment efficiency.

Furthermore, the material bin is a semicircular bin, two semicircular flat plates are arranged on two sides of the semicircular bin, the bottom of the semicircular bin is an arc-shaped bottom plate, and the material scooping device is tangent to the arc-shaped bottom plate when rotating into the material bin.

In the implementation process, the material bin is a semicircular bin, and the main structure of the material bin is two semicircular flat plates and an arc-shaped bottom plate; at rotor pivoted in-process, it is tangent with the arc bottom plate to ladle out the glassware to at quantitative partial shipment device normal operation in-process, ladle out the glassware and can carry out the partial shipment with whole materials in the material storehouse, when avoiding appearing partial shipment work end, remaining material does not have the partial shipment in addition in the material storehouse, needs the manual condition that carries out the partial shipment to take place, thereby further improves this quantitative partial shipment device's practicality.

Further, the material scooping device is in a quadrangular frustum pyramid shape, the top opening of the material scooping device is larger than the bottom of the material scooping device, and when the material scooping device rotates, one end of the top opening is tangent to the arc-shaped bottom plate.

In the above implementation, the shape of the scooper is quadrangular frustum pyramid, wherein the top opening is larger than the bottom opening, and the whole body is in an inverted trapezoidal shape when viewed from four sides of the scooper; in the quantitative subpackaging process of the quadrangular frustum pyramid shaped material scooper, on one hand, the material in the material bin can be obtained quantitatively when the material scooper rotates to a low position, and on the other hand, the material can be poured into the discharge hole completely when the material scooper rotates to a high position; and four prismatic table form ladles out the glassware and is rotating the in-process, and open-top's one end is tangent with the arc bottom plate to avoid appearing when partial shipment work finishes, remaining surplus material does not have the partial shipment in the material storehouse in addition, thereby the ration of accurate control partial shipment material at every turn, further improve this ration partial shipment device's work efficiency.

Further, the device still includes discharge hopper, discharge hopper set up in discharge gate department, ladling out the glassware and rotating extremely when discharge hopper department, the one end of ladling out the glassware with discharge hopper's one end is tangent.

In the implementation process, the discharging hopper is arranged at the discharging port and is used for helping to finish quantitative subpackaging of the materials, so that the material loss caused by spilling the materials in the process of pouring the materials into the discharging port by the scooper is avoided; when the scooping device rotates to the discharging funnel, a part of materials in the scooping device begin to be poured out, and at the moment, one end of the scooping device is tangent to one end of the discharging funnel, so that the material loss caused by the fact that the materials are not poured into the discharging funnel can be well avoided, the quantitative amount of the split charging materials at each time is accurately controlled, and the working efficiency of the quantitative split charging device is further improved.

Further, the discharge hole is formed right below the scooper when the scooper rotates to the high position, so that the scooper pours the material into the discharge hole when rotating.

In the above-mentioned realization in-process, ladling out the glassware when rotating to the high position, ladling out the glassware this moment and will all pouring out inside material, consequently set up the discharge gate in ladling out the glassware and rotating to the high position under, ladling out the glassware can pour into whole materials to the discharge gate to accomplish the quantitative partial shipment of material, avoid appearing the condition at partial shipment in-process material loss, thereby the ration of accurate control partial shipment material at every turn, improve this quantitative partial shipment device's work efficiency.

Further, the bottom of the material scooping device is provided with a fine hole.

In the implementation process, the material of the quantitative subpackaging device may contain moisture, for example, in the breeding of hermetia illucens, the feed of the hermetia illucens contains a large amount of moisture; in order to further improve the partial shipment efficiency of material, realize the quantitative accurate control to material partial shipment at every turn, be provided with the pore on the bottom of ladling out the material ware, the pore is used for going out water, can drip the material of ladling out the glassware futilely to improve this ration partial shipment device's partial shipment efficiency.

Further, the device still includes the rotation motor, the rotation motor set up in pivot department, the pivot by the rotation motor drives.

In the above-mentioned realization in-process, the rotation motor drives the rotation ware and rotates, specifically, rotates the pivot rotation in the motor drive rotation ware, and the pivot drives again and changes and to ladle out the glassware on the handle and rotate to realize the continuous type ration partial shipment of material, ensure the ration of accurate control partial shipment material at every turn on the one hand, on the other hand further improves this ration partial shipment device's work efficiency.

Further, the rotating motor includes an adjustment gear for adjusting a rotation speed of the rotating motor.

In the implementation process, the rotating motor is provided with adjusting gears, so that the rotating speed can be adjusted, for example, the rotating speed can be adjusted to three speeds, namely low, medium and high speeds; for example, for viscous materials, the material split charging rate is low, and at the moment, the material scooper can pour all the materials into the material outlet when rotating to a high position, so that the phenomenon that the materials are adhered in the material scooper is reduced; for thinner materials, the split charging speed of the materials can be properly accelerated, so that the production efficiency is improved; thereby realize that this ration partial shipment device satisfies the requirement of different materials to different partial shipment speed, improve ration partial shipment device's practicality.

Further, the device also comprises a power supply, and the power supply is used for supplying power to the rotating motor.

In the implementation process, the power supply is used for supplying power to the rotating motor, and specifically, the power supply can be connected with an external power supply, such as alternating current of 220V or 380V commercial power, so that the external power supply drives the rotating motor to operate, and the quantitative subpackaging device can continuously operate.

Additional features and advantages of the disclosure will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by the practice of the above-described techniques of the disclosure.

In order to make the aforementioned objects, features and advantages of the present application more comprehensible, preferred embodiments accompanied with figures are described in detail below.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings that are required to be used in the embodiments of the present application will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present application and therefore should not be considered as limiting the scope, and that those skilled in the art can also obtain other related drawings based on the drawings without inventive efforts.

Fig. 1 is a schematic structural diagram of a quantitative split charging device according to an embodiment of the present disclosure;

fig. 2 is a schematic structural diagram of a quantitative split charging device according to an embodiment of the present disclosure;

FIG. 3a is an axial view of a bail provided in accordance with an embodiment of the present application;

FIG. 3b is a front view of a bail as provided in the embodiments of the present application;

fig. 4 is a schematic structural view of a fine hole of a bail in accordance with an embodiment of the present disclosure.

Detailed Description

The technical solutions in the embodiments of the present application will be described below with reference to the drawings in the embodiments of the present application.

It should be noted that: like reference numbers and letters refer to like items in the following figures, and thus, once an item is defined in one figure, it need not be further defined and explained in subsequent figures. Meanwhile, in the description of the present application, the terms "first", "second", and the like are used only for distinguishing the description, and are not to be construed as indicating or implying relative importance.

The embodiment of the application provides a ration partial shipment device can be applied to the heisui river horsefly and breed, for example can carry out ration partial shipment to heisui river horsefly bait. The quantitative subpackaging device is driven by an automatic driving mechanism, and materials scooped by the material scooping device every time are equal in capacity in the rotating process, so that quantitative subpackaging in the subpackaging process is realized, manual operation is reduced, on one hand, the labor cost can be reduced, the device can be operated according to a production line, and the quantitative subpackaging efficiency of the black soldier fly breeding bait is further improved; on the other hand, the device is carrying out bait partial shipment in-process, and the waste gas that the bait gived off is easily airtight to be collected, has avoided bait waste gas to staff's physical and mental harm.

Referring to fig. 1, fig. 1 is a schematic structural diagram of a quantitative dispensing device according to an embodiment of the present disclosure. The quantitative dispensing device comprises a material bin 11, a rotator 12 and at least one scooper 13.

Illustratively, the material bin 11 is used for containing materials to be dispensed.

Optionally, when the material capacity in the material bin 11 reaches 1/2-2/3 of the total capacity of the material bin 11, the quantitative subpackaging device starts to work and operate to perform quantitative subpackaging of the materials; on one hand, if the quantitative subpackaging device starts to operate when the material capacity is low, materials need to be frequently added into the material bin 11 at the moment, and therefore the subpackaging efficiency of the quantitative subpackaging device is reduced; on the other hand, if the quantitative subpackaging device starts to operate when the material capacity is large, the situation that the material scooping device takes the animal materials to overflow the material bin 11 when rotating may occur in the operation process, so that the material loss is caused, and the material is easily subjected to the non-quantitative subpackaging. Therefore, 1/2-2/3 is set, when the material capacity in the material bin 11 reaches 1/2-2/3 of the total capacity of the material bin 11, the quantitative subpackaging device starts to work and operate, on one hand, the subpackaging efficiency can be guaranteed, and on the other hand, the quantitative subpackaging of the materials can be guaranteed at the same time.

Optionally, the material bin 11 is a semicircular bin, two semicircular flat plates are arranged on two sides of the semicircular bin, an arc-shaped bottom plate is arranged at the bottom of the semicircular bin, and the material scooping device 13 is tangent to the arc-shaped bottom plate when rotating into the material bin 11.

Illustratively, the material bin 11 is a semicircular bin, and the main structure of the material bin is two semicircular flat plates and an arc-shaped bottom plate; at rotor 12 pivoted in-process, it is tangent with the arc bottom plate in material storehouse 11 to ladle out material ware 13 to carry out the partial shipment with whole materials in the material storehouse at this ration partial shipment device normal operation in-process, ladle out material ware 13 and can avoid appearing when partial shipment work finishes, remaining residual material does not have the partial shipment in the material storehouse in addition, needs the manual work to carry out the condition emergence of partial shipment, thereby further improves this ration partial shipment device's practicality.

In a possible embodiment, the diameter of the semicircular plates of the material container 11 is 2m, the linear distance between the two semicircular plates is 1m, and the nominal capacity in the material container 11 is 1.57m³。

Alternatively, the discharge port is provided just below the bail 13 when rotated to the high position, so that the bail 13 pours the material into the discharge port when rotated.

Exemplarily, ladling out the glassware 13 when rotating to the high position, ladling out glassware 13 this moment will all pour out inside material, consequently set up the discharge gate in ladling out glassware 13 and rotating to the high position under, ladling out glassware 13 this moment then can pour into whole material to the discharge gate to accomplish the quantitative partial shipment of material, avoid appearing the condition at partial shipment in-process material loss, thereby the ration of the every turn partial shipment material of accurate control, improve this quantitative partial shipment device's work efficiency.

Illustratively, the rotator 12 includes a rotating shaft 121 and at least one rotating handle 122, one end of the rotating handle is disposed on the rotating shaft 121, and the rotator 12 is disposed above the material bin 11.

Illustratively, the rotating shaft 121 in the rotator 12 is a driving mechanism, the rotating handle 122 is a driven mechanism, and the rotating handle 122 is driven by the rotating shaft 121, so that the rotating handle 122 makes a circular motion around the center of the rotating shaft 121.

Illustratively, when the number of the rotating handle 122 is more than one, the shape and the size of each rotating handle 122 are equal, and the included angle between each two adjacent rotating handles is also equal.

Exemplarily, the rotating shaft 121 of the rotator 12 is disposed at a circular position of the arc-shaped bottom plate of the material bin 11; specifically, a straight line can be determined by the arc-shaped bottom plate of the material bin 11, the straight line is parallel to the arc-shaped bottom plate, and the straight line position is formed by the circle centers of the arc-shaped bottom plate, namely the arc-shaped bottom plate of the material bin 11 can determine the straight line formed by the circle centers of the arc-shaped bottom plate; the rotating shaft 121 is disposed at the straight line, so that when the rotating shaft 121 rotates, the center of the rotating track of the rotating handle 122 coincides with the center of the arc-shaped bottom plate of the material bin 11.

Illustratively, the material scooper 13 is disposed at one end of the rotating handle 122, and is used for scooping the material with a preset volume from the 11 material bins when the rotating handle 122 rotates to the low position, and the material scooper 13 pours the material into the material outlet when the rotating handle rotates to the high position, so as to complete the quantitative sub-packaging of the material.

Illustratively, when the scooper 13 rotates to the low position, the scooper 13 is located in the material bin 11, and when the scooper 13 continues to rotate, a predetermined volume of material is scooped from the material bin 11; when the material scooping device 13 rotates to the high position, the material scooping device 13 is located outside the material bin 11, when the material scooping device 13 continues to rotate, the material in the material scooping device 13 is poured out from the material scooping device 13 due to the gravity effect, and therefore the material is poured into the material outlet by the material scooping device 13, and the quantitative subpackaging of the material is completed.

Optionally, the quantitative dispensing device comprises 4 scoopers 13, the rotator 12 comprises 4 rotating handles 122, and the 4 rotating handles 122 are perpendicular to each other.

Illustratively, 4 scoopers 13 are respectively disposed at one end of the 4 rotating handles 122, so that when the rotator 12 rotates, the rotator 12 can drive the 4 scoopers 13 to rotate; moreover, the 4 rotating handles 122 are perpendicular to each other, so that the working ranges of the 4 scoopers 13 are differentiated, and each scooper 13 has a sufficient working range, so that the mutual influence of quantitative subpackaging of the materials of the scoopers 13 can be avoided; on the other hand, 4 scooping devices 13 can ensure the dispensing efficiency of the quantitative dispensing device to the maximum extent.

Optionally, the material scooper 13 is in the shape of a truncated quadrangular prism, the top opening of the material scooper 13 is larger than the bottom of the material scooper 13, and when the material scooper 13 rotates, one end of the top opening is tangent to the arc-shaped bottom plate of the material bin 11.

Optionally, the quantitative subpackaging device further comprises a discharge funnel, the discharge funnel is arranged at the discharge port, and when the material scooping device 13 rotates to the discharge funnel, one end of the material scooping device 13 is tangent to one end of the discharge funnel.

In a possible implementation scenario, the rotation angular velocity of the bail 13 is (pi/60)/s, i.e. every 15 seconds of rotation of the bail 13, through pi/4 (90 °), a predetermined volume of material is poured into the discharge funnel; discharging two parts of materials with preset volume every 30 seconds; at this time, the average discharge rate of the quantitative racking device was 4 times/min. For example, in black soldier fly farming, each bail 13 may hold 6 kg of bait; every 30 seconds, 2 spoons of bait are discharged for 12 kilograms of bait, and at the moment, the bait is just filled into a cultivation bait basin, and the average discharging speed is 24 kilograms/min or 2 basins/min.

In one possible implementation scenario, the scoop of the scoop 13 is of a quadrangular frustum pyramid design, with a scoop dimension of 20 × 60cm and a scoop base dimension of 10 × 30 cm.

Alternatively, the rotator 12 may be driven to rotate by a push-pull mechanism.

Optionally, the quantitative subpackaging device further comprises a rotating motor, and the rotating motor is arranged at the rotating shaft 121, so that the rotating shaft 121 is driven by the rotating motor.

Illustratively, the rotating motor drives the rotator 12 to rotate, specifically, the rotating motor drives the rotating shaft 121 in the rotator to rotate, and the rotating shaft 121 drives the rotating handle 122 and the material scooping device 13 on the rotating handle to rotate, so as to realize continuous quantitative subpackaging of materials, on one hand, the quantitative subpackaging of materials at each time is ensured to be accurately controlled, and on the other hand, the working efficiency of the quantitative subpackaging device is further improved.

Illustratively, the rotating motor drives the rotator 12 to rotate at a constant speed.

Optionally, the rotating electrical machine comprises an adjustment gear for adjusting the rotational speed of the rotating electrical machine.

Illustratively, the rotating motor is provided with a regulating gear, the rotating speed can be regulated, and for example, the rotating speed atmosphere can be divided into three speed gears, namely low, medium and high.

In one possible embodiment, the quantitative dispensing device needs to dispense materials of different consistencies. For viscous materials, the material subpackaging speed is low, and at the moment, the material scooping device 13 can pour all the materials into the discharge hole when rotating to a high position, so that the phenomenon that the materials are adhered in the material scooping device is reduced; for thinner materials, the split charging speed of the materials can be properly accelerated, so that the production efficiency is improved. Through setting up different slew velocity to realize that this ration partial shipment device satisfies different materials to the requirement of different partial shipment speed, improve ration partial shipment device's practicality.

Optionally, the quantitative racking device further comprises a power source for supplying power to the rotary motor.

The power supply is used for supplying power to the rotary motor, and particularly, the power supply can be connected with an external power supply, such as alternating current of 220V or 380V commercial power, so that the rotary motor is driven by the external power supply to operate, and the quantitative subpackaging device can continuously operate.

In a possible implementation scenario, the quantitative split charging device of the embodiment of the application can be applied to black soldier fly breeding. Specifically, heisui river horsefly breeding bait is unloaded from the blendor discharge gate, fall into in material storehouse 11, 4 of rotation motor drive revolve the clockwise at the uniform velocity rotation of axle 121 evenly distributed's ladling out material ware 13, 4 ladling out material ware 13 successively ladles out heisui river horsefly bait in the bottom of material storehouse 11, and pass through the oblique discharge hopper in material storehouse top in proper order, ladling out 13 rotatory upset in-process and evenly pour heisui river horsefly bait into discharge hopper, and discharge gate through the downward sloping is regularly, the continuous even ejection of compact of ration.

Referring to fig. 2, fig. 2 is a schematic structural diagram of a quantitative dispensing device according to an embodiment of the present disclosure. The quantitative dispensing device comprises a material bin 11, a rotator 12, at least one scooper 13 and a discharge funnel 14.

Illustratively, the material bin 11, the rotator 12 and the at least one bail 13 have been described in detail above, and are not described again to avoid repetition.

Illustratively, the discharge funnel 14 is disposed at the discharge port, and when the bail 13 rotates to the discharge funnel 14, one end of the bail 13 is tangent to one end of the discharge funnel 14.

Illustratively, the discharge funnel 14 is disposed at the discharge port to help complete the quantitative sub-packaging of the material, so as to avoid material loss caused by spilling the material during the process of pouring the material into the discharge port by the material scooper 13; when ladling out glassware 13 when rotating to discharge funnel department, ladling out a part of material in the glassware 13 and begin to pour out, the one end of ladling out the glassware this moment is tangent with discharge funnel 14's one end, can be fine avoid the material not pour into discharge funnel and the material loss that causes to the ration of every minute partial shipment material of accurate control further improves this ration partial shipment device's work efficiency.

In a possible embodiment, the bottom edge of the discharge funnel 14 forms an angle of 40 to 50 ° with the horizontal of the material container 11.

Referring to fig. 3a, fig. 3a is an axial view of a bail according to an embodiment of the present disclosure.

Referring to fig. 3b, fig. 3b is a front view of a bail according to an embodiment of the present disclosure.

Illustratively, the material scoop 13 is in the shape of a truncated pyramid, the top opening of the material scoop 13 is larger than the bottom of the material scoop 13, and when the material scoop 13 rotates, one end of the top opening is tangent to the arc-shaped bottom plate of the material bin 11.

Exemplarily, the shape of the bail 13 is quadrangular frustum of a pyramid, wherein the top opening is larger than the bottom opening, and the overall shape is inverted trapezoidal, as seen from the four sides of the bail 13; in the quantitative subpackaging process, the quadrangular frustum pyramid shaped material scooper 13 can quantitatively obtain the materials in the material bin 11 when the material scooper 13 rotates to a low position on one hand, and can completely pour the materials into the discharge hole when the material scooper 13 rotates to a high position on the other hand; and four prismatic table form ladles out glassware 13 and rotates the in-process, and open-top's one end is tangent with the arc bottom plate in material storehouse 11 to avoid appearing when partial shipment work finishes, remaining residual material does not have the partial shipment in the material storehouse 11 in addition, thereby the ration of accurate control partial shipment material at every turn, further improve this ration partial shipment device's work efficiency.

Referring to fig. 4, fig. 4 is a schematic structural view of a fine hole of a dipper according to an embodiment of the present disclosure.

Illustratively, the bottom of the scoop 13 is provided with a fine hole.

For example, since the material of the quantitative subpackaging device may contain moisture, for example, when the black soldier flies are bred, the feed of the black soldier flies contains a large amount of moisture, and the material needs to be preliminarily drained. In order to further improve the partial shipment efficiency of material, realize the quantitative accurate control to material partial shipment at every turn, be provided with the pore on the bottom of ladling out material ware 13, the pore is used for going out water, can carry out preliminary driping with the material of ladling out the glassware to improve this quantitative partial shipment device's partial shipment efficiency.

In a possible implementation scene, draining pores are uniformly distributed at the bottom of a scooping spoon of the scooping device 13, the diameter of the draining pores is 5mm, the pores are transversely distributed in 4 rows, and the distance between the pores is 1-2 cm; the pores are distributed in 3 rows longitudinally and the distance is 5-7 cm.

In a possible implementation scenario, the quantitative subpackaging device can be applied to quantitative subpackaging of livestock excrement or kitchen garbage. For example, for agricultural production, organic fertilizers have been the first choice fertilizers for the current advocated green agriculture, including human excrement, manure, compost, green manure, cake manure, biogas manure, and the like. The organic fertilizer not only can realize the recycling of waste garbage, but also has the characteristics of multiple types, wide sources, longer fertilizer efficiency and the like. The organic fertilizer contains many nutrient elements in organic state, and is difficult to be directly utilized by crops, and through the action of microorganisms, various nutrient elements are slowly released, and the nutrients are continuously supplied to the crops. The application of the organic fertilizer can improve the soil structure, coordinate water, fertilizer, gas and heat in the soil, and improve the soil fertility and the land productivity. However, the manual treatment of the organic fertilizer has low efficiency, and the organic fertilizer can generate a large amount of waste gas and odor, which greatly affects the physical and mental health of workers. Therefore, the quantitative subpackaging device can automatically complete the automatic subpackaging of the organic fertilizer, avoid the direct participation or contact of workers in the subpackaging process of the organic fertilizer, reduce the labor cost and improve the subpackaging efficiency on the one hand; on the other hand, the harm of waste gas or odor of the organic fertilizer to physical and psychological health of workers is avoided.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it should be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; such modifications and substitutions do not depart from the spirit and scope of the embodiments of the present invention.

The functional modules in the embodiments of the present application may be integrated together to form an independent part, or each module may exist separately, or two or more modules may be integrated to form an independent part.

The above description is only an example of the present application and is not intended to limit the scope of the present application, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, improvement and the like made within the spirit and principle of the present application shall be included in the protection scope of the present application. It should be noted that: like reference numbers and letters refer to like items in the following figures, and thus, once an item is defined in one figure, it need not be further defined and explained in subsequent figures.

The above description is only for the specific embodiments of the present application, but the scope of the present application is not limited thereto, and any person skilled in the art can easily conceive of the changes or substitutions within the technical scope of the present application, and shall be covered by the scope of the present application. Therefore, the protection scope of the present application shall be subject to the protection scope of the claims.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other identical elements in a process, method, article, or apparatus that comprises the element.

Claims (10)

1. A metered dose dispensing apparatus, comprising:

the material bin is used for containing materials to be subpackaged;

the rotating device comprises a rotating shaft and at least one rotating handle, one end of the rotating handle is arranged on the rotating shaft, and the rotating device is arranged above the material bin;

at least one ladling device, the ladling device set up in the one end of changeing the handle, be used for when change rotate to the low level, the ladling device follow the material of default capacity is ladled out in the material storehouse, when change rotate to the high level, the ladling device pours the material into the discharge gate to accomplish the quantitative partial shipment of material.

2. The metered dose dispensing apparatus of claim 1 wherein said apparatus comprises 4 of said scoopers and said rotator comprises 4 of said rotating handles, said 4 rotating handles being perpendicular to each other.

3. The metered dose dispensing apparatus of claim 2 wherein said hopper is a semi-circular hopper, said semi-circular hopper has two semi-circular flat plates on both sides, said semi-circular hopper has an arc bottom plate at the bottom, and said scooper is tangent to said arc bottom plate when rotating into said hopper.

4. The metered dose dispensing apparatus of claim 3 wherein said bail is rectangular frustum-shaped, said bail having a top opening larger than a bottom of said bail, said bail being rotated with an end of said top opening tangent to said arcuate floor.

5. The metered dose dispensing apparatus of claim 4 further comprising a discharge funnel, said discharge funnel being disposed at said discharge port, said bail being rotated to said discharge funnel such that one end of said bail is tangent to one end of said discharge funnel.

6. The metered dose dispensing apparatus of claim 1 wherein said discharge port is disposed directly below said bail when rotated to said raised position such that said bail dumps material into said discharge port when rotated.

7. The metered dose dispensing apparatus of claim 1 wherein the base of said bail is provided with a fine aperture.

8. A metered dose dispensing apparatus as recited in claim 1 further comprising a rotary motor disposed at said spindle, said spindle being driven by said rotary motor.

9. A metered dose dispensing apparatus as claimed in claim 8 wherein the rotary motor includes an adjustment gear for adjusting the speed of rotation of the rotary motor.

10. A metered dose dispensing apparatus as recited in claim 9 further comprising a power source for powering said rotary motor.

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