CN114194866A - Solid material storage and quantitative feeding intelligent device - Google Patents

Abstract

The invention discloses an intelligent solid material storage and quantitative feeding device, which relates to the technical field of solid material feeding devices and comprises a barrel body, stirring blades, a quantitative rotor and a quantitative rotor kit, wherein the stirring blades are positioned inside the barrel body, the quantitative rotor is positioned on the lower side of the barrel body, the quantitative rotor kit is rotatably arranged in the quantitative rotor, a first inlet is formed in the lower side of the barrel body, a second inlet is formed in the upper end of the quantitative rotor, a first outlet is formed in the lower side of the quantitative rotor, and a second outlet is formed in the lower side of the quantitative rotor kit. During the use, when quantitative rotor external member rotated the first position from the third position, first entry and the coincidence of second entry, first export and second export disconnection, the material fell into quantitative rotor external member in from the ladle body, when quantitative rotor external member rotated the second position from the first position, first entry and second entry disconnection, first export and second export coincidence, the material left quantitative rotor external member, and the quantitative ejection of compact is realized through quantitative rotor external member to the inside material of ladle body.

Description

Solid material storage and quantitative feeding intelligent device

Technical Field

The invention relates to the technical field of solid material feeding devices, in particular to an intelligent solid material storage and quantitative feeding device.

Background

The existing solid material conveying mechanism mostly adopts a screw mechanism or a vacuum material suction mode to realize conveying and discharging. The quantitative discharging control of the screw mechanism controls the discharging amount through the volume of the screw clearance and the number of turns of the screw rotation, and the discharging precision is limited by the clearance of the helical blades. The quantitative discharging control of the vacuum suction is realized by the aid of vacuum operation time, inner diameter and length of a pipeline combination, discharging precision is difficult to control, and the quantitative discharging control device is generally suitable for finishing one-time conveying of whole packaging materials and is not suitable for high-precision intermittent discharging requirements. The screw mechanism device is bulky, and the storage part must be placed perpendicularly with the screw rod and just can realize pan feeding and spiral ejection of compact, leads to equipment fixing space demand big. The vacuum series device is composed of a vacuum pump, a pipeline combination, a filter screen and other components; the weight of the vacuum cavity and the material is in direct proportion to the volume of the vacuum pump; the problem of difficult cleaning of materials is existed.

The spiral mechanism is suitable for dry and wet solid materials and is not suitable for jelly-shaped solid materials, the jelly-shaped solid materials are easy to break through screw stirring or strong vacuum material suction, and the production process requirement of complete material feeding form cannot be met; the device combination such as vacuum pump, pipeline combination and dustproof isolation mechanism realizes the transportation of dry powdery, granular and light solid materials, and is not suitable for the transportation and discharging of non-solid materials with sticky, jelly-like and high water content.

Disclosure of Invention

Therefore, the invention provides an intelligent device for storing and quantitatively feeding solid materials, which aims to solve the problem that a spiral mechanism in the prior art is not suitable for jelly-shaped solid materials and is easy to cause the breakage of the jelly-shaped solid materials.

In order to achieve the above purpose, the invention provides the following technical scheme:

the utility model provides a solid material storage and quantitative feed intelligent device, includes ladle body, stirring paddle leaf, ration rotor and ration rotor external member, and stirring paddle leaf is located inside the ladle body, and the ration rotor is located the ladle body downside, and the ration rotor external member rotationally sets up in the ration rotor, and the ladle body downside is equipped with first entry, and the ration rotor upper end has the second entry, and the ration rotor downside has first export, and ration rotor external member downside has the second export.

Further, still include the leak protection carousel, the leak protection carousel is located the ladle body inside, and first entry is located the leak protection carousel, and first entry is the slot hole that extends along circular arc length direction, and the circular arc contained angle in slot hole place is 120 degrees.

Further, still include rotatory knife tackle, axis of rotation mounting and leak protection silica gel circle, stirring paddle connects rotatory knife tackle, and rotatory knife tackle connects the axis of rotation mounting, and the axis of rotation mounting is connected with stirring motor drive, and axis of rotation mounting downside is equipped with the leak protection carousel, and the leak protection carousel periphery is equipped with leak protection silica gel circle, leak protection silica gel circle and ladle body sliding fit.

Further, still include base shell and dial the material motor, base shell is located the ladle body downside, and stirring paddle and quantitative rotor external member are connected through gear and dial the material motor transmission, and quantitative rotor external member are located inside the base shell.

Further, still include ejection of compact motor and ejection of compact rotor, ejection of compact motor is located inside the base shell, and ejection of compact rotor is located quantitative rotor external member downside, and ejection of compact motor control ejection of compact rotor rotates, and ejection of compact rotor upper end is equipped with the third entry, and ejection of compact rotor lower extreme is equipped with the third export.

The quantitative material stirring device further comprises a control unit, an angle sensor and a position sensor, wherein the material stirring motor and the material discharging motor are respectively electrically connected with the control unit, the angle sensor is electrically connected with the quantitative rotor set, and the position sensor is electrically connected with the material discharging rotor.

And when the discharging rotor rotates to a third position, the discharging rotor touches the micro switch.

Further, ejection of compact motor passes through the rubber pad subassembly and connects the base shell, and the rubber pad subassembly includes rubber pad and rubber pad locking part, and ejection of compact motor is connected to the rubber pad, and rubber pad locking part connects the base shell, and rubber pad locking part is equipped with the recess, and the rubber pad setting is in the recess.

Further, the multifunctional nursing bed further comprises an upper cover, the upper cover is provided with a handle, and one side of the handle, which is close to the periphery of the upper cover, is provided with an upright placing surface.

The invention has the following advantages: during the use, when quantitative rotor external member rotated the first position from the third position, first entry and the coincidence of second entry, first export and second export disconnection, the material fell into quantitative rotor external member in from the ladle body, when quantitative rotor external member rotated the second position from the first position, first entry and second entry disconnection, first export and second export coincidence, the material left quantitative rotor external member, and the quantitative ejection of compact is realized through quantitative rotor external member to the inside material of ladle body. Can be applied to dry solid materials, such as granules, powder and block materials; the method is also suitable for solid materials with certain water content and viscosity and jelly-shaped, soft and solid materials with certain fluidity, and the solid materials have good compatibility.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below. It should be apparent that the drawings in the following description are merely exemplary, and that other embodiments can be derived from the drawings provided by those of ordinary skill in the art without inventive effort.

The structures, ratios, sizes, and the like shown in the present specification are only used for matching with the contents disclosed in the specification, so that those skilled in the art can understand and read the present invention, and do not limit the conditions for implementing the present invention, so that the present invention has no technical significance, and any structural modifications, changes in the ratio relationship, or adjustments of the sizes, without affecting the functions and purposes of the present invention, should still fall within the scope covered by the contents disclosed in the present invention.

FIG. 1 is a side view of an intelligent solid material storage and dosing device according to an embodiment of the present invention;

FIG. 2 is a top view of FIG. 1;

FIG. 3 is a view taken along line A-A of FIG. 2;

fig. 4 is a view from the direction B-B of fig. 2.

In the figure: 1-an upper cover assembly; 1.1-upper cover; 2.1-a barrel body; 2.2-stirring blade; 2.3-rotating knife group; 2.4-rotating shaft fixing member; 2.5-leak-proof rotary table; 2.6-leak-proof silica gel ring; 3-a base assembly; 3.1-base shell, 3.2-quantitative rotor, 3.3-quantitative rotor kit, 3.4-discharging rotor, 3.5-motor rotating piece; 3.6-motor mounting seat; 3.7-mounting a base cover plate; 3.8-a material shifting motor; 3.9-discharge motor gear; 3.10-discharge motor; 3.11-micro-gap switch; 3.12-quick plugging and unplugging the connector; 4-a rubber mat component; 4.1-rubber pad; 4.2-rubber pad locking part.

Detailed Description

The present invention is described in terms of particular embodiments, other advantages and features of the invention will become apparent to those skilled in the art from the following disclosure, and it is to be understood that the described embodiments are merely exemplary of the invention and that it is not intended to limit the invention to the particular embodiments disclosed. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the present specification, the terms "upper", "lower", "left", "right", "middle", and the like are used for clarity of description, and are not intended to limit the scope of the present invention, and changes or modifications in the relative relationship may be made without substantial changes in the technical content.

As shown in fig. 1 to 4, the embodiment of the invention provides an intelligent device for storing and quantitatively feeding solid materials, which comprises an upper cover assembly 1, a barrel assembly 2, a base assembly 3 and a rubber pad assembly 4, wherein the barrel assembly 2 comprises a barrel 2.1, a stirring blade 2.2, a rotary cutter set 2.3, a rotating shaft fixing member 2.4, a leakage-proof rotary table 2.5 and a leakage-proof silica gel ring 2.6, the base assembly 3 comprises a base shell 3.1, a quantitative rotor 3.2, a quantitative rotor kit 3.3, a discharging rotor 3.4, a motor rotating member 3.5, a motor mounting seat 3.6, a mounting seat cover plate 3.7, a material shifting motor 3.8, a discharging motor gear 3.9, a discharging motor 3.10, a microswitch 3.11 and a quick plugging and unplugging assembly 3.12, and the rubber pad assembly 4 comprises a rubber pad 4.1 and a rubber pad locking member 4.2.

As shown in fig. 1 and fig. 3, the embodiment of the present invention provides an intelligent device for storing and quantitatively feeding solid materials, which includes a barrel 2.1, a stirring blade 2.2, a quantitative rotor 3.2 and a quantitative rotor kit 3.3, wherein the stirring blade 2.2 is located inside the barrel 2.1, the quantitative rotor 3.2 is located at the lower side of the barrel 2.1, the quantitative rotor kit 3.3 is rotatably disposed inside the quantitative rotor 3.2, the lower side of the barrel 2.1 is provided with a first inlet, the upper end of the quantitative rotor 3.2 is provided with a second inlet, the lower side of the quantitative rotor 3.2 is provided with a first outlet, and the lower side of the quantitative rotor kit 3.3 is provided with a second outlet.

During the use, when quantitative rotor external member 3.3 rotated the first position from the third position, first entry and the coincidence of second entry, first export and second export disconnection, the material falls into quantitative rotor external member 3.3 in from ladle body 2.1, when quantitative rotor external member 3.3 rotated the second position from the first position, first entry and the disconnection of second entry, first export and the coincidence of second export, the material leaves quantitative rotor external member 3.3, the material of ladle body 2.1 inside realizes the ration ejection of compact through quantitative rotor external member 3.3. Can be applied to dry solid materials, such as granules, powder and block materials; the method is also suitable for solid materials with certain water content and viscosity and jelly-shaped, soft and solid materials with certain fluidity, and the solid materials have good compatibility. The quantitative rotor external member 3.3 with different heights can be replaced according to the material density and the diversity and complexity of the process, and various changes of the process formula can be easily realized.

It should be noted that the quantitative rotor assembly 3.3 further has a third position, and the first position, the second position, and the third position are sequentially arranged along the circumferential direction of rotation, and when the quantitative rotor assembly 3.3 rotates to the third position, the first inlet and the second inlet are disconnected, and the first outlet and the second outlet are disconnected.

In an alternative embodiment, as shown in fig. 4, a leakage-proof rotating disc 2.5 is further included, the leakage-proof rotating disc 2.5 is located inside the barrel body 2.1, the first inlet is located at the leakage-proof rotating disc 2.5, the first inlet is a long hole extending along the length direction of an arc, and the included angle of the arc where the long hole is located is 120 degrees. The rotation angle required for the dosing rotor assembly 3.3 to rotate from the first position to the second position is 120 degrees, and thus the rotation angle required for the dosing rotor assembly 3.3 to rotate from the second position to the third position is also 120 degrees.

In an optional embodiment, as shown in fig. 3, the portable material stirring device further includes a rotary knife group 2.3, a rotary shaft fixing part 2.4 and a leakage-proof silica gel ring 2.6, the stirring blade 2.2 is connected with the rotary knife group 2.3, the rotary knife group 2.3 is connected with the rotary shaft fixing part 2.4, the rotary shaft fixing part 2.4 is in transmission connection with a material stirring motor 3.8, a leakage-proof turntable 2.5 is arranged on the lower side of the rotary shaft fixing part 2.4, the leakage-proof silica gel ring 2.6 is arranged on the periphery of the leakage-proof turntable 2.5, and the leakage-proof silica gel ring 2.6 is in sliding fit with the barrel body 2.1. The leak-proof rotary disc 2.5 plays a role in rotary sealing.

In an alternative embodiment, as shown in fig. 3 and 4, the device further comprises a base housing 3.1 and a material stirring motor 3.8, wherein the base housing 3.1 is positioned at the lower side of the barrel body 2.1, the stirring blade 2.2 and the quantitative rotor set 3.3 are in transmission connection with the material stirring motor 3.8 through a gear, and the quantitative rotor 3.2 and the quantitative rotor set 3.3 are positioned inside the base housing 3.1.

In an alternative embodiment, as shown in fig. 4, the quantitative rotor assembly further includes a discharging motor 3.10 and a discharging rotor 3.4, the discharging motor 3.10 is located inside the base housing 3.1, the discharging rotor 3.4 is located at the lower side of the quantitative rotor assembly 3.3, the discharging motor 3.10 controls the discharging rotor 3.4 to rotate, a third inlet is provided at the upper end of the discharging rotor 3.4, a third outlet is provided at the lower end of the discharging rotor 3.4, when the discharging rotor 3.4 rotates to the second position, the third inlet at the upper end of the discharging rotor 3.4 is communicated with the second outlet at the lower side of the quantitative rotor assembly 3.3, the discharging rotor 3.4 leads out the material in the quantitative rotor assembly 3.3, when the discharging rotor 3.4 rotates to the third position, the third inlet at the upper end of the discharging rotor 3.4 is disconnected from the second outlet at the lower side of the quantitative rotor assembly 3.3, and the discharging rotor 3.4 cannot lead out the material in the quantitative rotor assembly 3.3.3.

In an optional embodiment, the stirring device further comprises a control unit, an angle sensor and a position sensor, wherein the material stirring motor 3.8 and the discharging motor 3.10 are respectively electrically connected with the control unit, the angle sensor is electrically connected with the quantitative rotor kit 3.3, the rotation angle and the position of the quantitative rotor kit 3.3 and the stirring blade 2.2 are measured, the position sensor is electrically connected with the discharging rotor 3.4, and the position sensor measures the position of the discharging rotor 3.4.

The control unit controls the material shifting motor 3.8 to drive the quantitative rotor assembly 3.3 to rotate to the first position, the second position or the third position, so that the first inlet and the second inlet are overlapped or disconnected to control the material to enter the quantitative rotor assembly 3.3, and the first outlet and the second outlet are overlapped or disconnected to control the material to leave the quantitative rotor assembly 3.3.

The control unit also controls the discharging motor 3.10 to drive the discharging rotor 3.4 to rotate to the second position or the third position so as to lead out the materials in the quantitative rotor suite 3.3.

An angle sensor, a Hall position sensor and a control circuit board are arranged in the material poking machine, so that the material poking motor can automatically rotate by 120 degrees at each starting. The design greatly simplifies the control program of the PLC or the single chip microcomputer, can be automatically executed and completed only by giving a starting signal, reduces and avoids the starting and stopping control of repeated pulse and frequency, also avoids the risk generated by the control of a multilayer logic loop, and improves the running precision of the device.

In an alternative embodiment, as shown in fig. 3, a microswitch 3.11 is further included, the discharging motor 3.10 rotates reversely to drive the discharging rotor 3.4 to rotate from the third position to the fourth position, so that the discharging rotor 3.4 touches the microswitch, and the microswitch outputs a signal, that is, the discharging rotor 3.4 is turned off.

In an alternative embodiment, as shown in fig. 3, the discharging motor 3.10 is connected to the base housing 3.1 through the rubber pad assembly 4, the rubber pad assembly 4 includes a rubber pad 4.1 and a rubber pad locking member 4.2, the rubber pad 4.1 is connected to the discharging motor 3.10, the rubber pad locking member 4.2 is connected to the base housing 3.1, the rubber pad locking member 4.2 is provided with a groove, and the rubber pad 4.1 is disposed in the groove.

In an alternative embodiment, as shown in fig. 1 and fig. 3, the multifunctional combined type electric heating furnace further comprises an upper cover assembly 1, the upper cover assembly 1 comprises an upper cover 1.1, the upper cover 1.1 is provided with a handle, one side of the handle close to the periphery of the upper cover 1.1 is provided with an upright placing surface, the upright placing surface can serve as a support, and a person can place the upper cover 1.1 on a workbench in an upright manner after taking the upper cover, so that the space is saved, and the operation is convenient. In this scheme, upper cover 1.1 body is food level PP material, and there is the buckle on upper cover 1.1 both sides, can upper cover 1.1 and the inseparable lock of ladle body 2.1. The joint of the upper cover 1.1 and the barrel body 2.1 has the fool-proof design of a boss, and the upper cover 1.1 cannot be buckled in the wrong direction.

The quantitative rotor 3.2, the quantitative rotor kit 3.3 and the discharging rotor 3.4 are all formed by injection molding, and structural parts with complex structures, multiple curved surfaces and easy assembly and disassembly can be rapidly produced in a large quantity. The quantitative rotor 3.2, the quantitative rotor kit 3.3 and the discharging rotor 3.4 can be quickly disassembled, cleaned off line and quickly reassembled; in the process of reinstalling, the electrical elements of the device are covered and locked by the plastic part shell, and even if the personnel operate improperly and wash partial moisture in the parts, the personnel do not contact the electrical elements, so that the safety of the personnel and the equipment are protected.

According to the control process, when the work order requirement is received, the discharging rotor 3.4 can be started to rotate to the discharging position to wait, and meanwhile, the material shifting motor 3.8 finishes automatic material filling of the quantitative rotor sleeve 3.3 and is in a discharging waiting state. When the whole process is executed to a work station or a working procedure of the device, the discharging action can be finished only by starting the material stirring motor for 3.8 and rotating the second 120 degrees. The working time sequence of the serial connection is changed into the working time sequence of the parallel connection, the effective working time is shortened, and the working efficiency is improved.

The feeding method of the intelligent device for solid material storage and quantitative feeding comprises the following steps:

s1: after receiving the integral work order production command, the discharging motor 3.10 pushes the discharging rotor 3.4 to a discharging opening position through gear transmission, namely, rotates from a third position to a second position;

s2: the material shifting motor 3.8 is started to rotate for the first 120 degrees, namely, the material shifting motor rotates from the third position to the first position, the rotating paddle is driven to shift solid materials into a discharge hole of the leakage-proof turntable 2.5, and the materials fall into the quantitative rotor 3.2 and the quantitative rotor kit 3.3 to wait;

s3: when the whole work order is executed to the work station of the device, the PLC, the singlechip or the industrial personal computer drives a discharging work order of the device, the material shifting motor 3.8 is started to rotate for a second 120 degrees, namely, the material shifting motor rotates from the first position to the second position to drive the quantitative rotor 3.2 to rotate to a discharging position, at the moment, the quantitative rotor 3.2 closes the inlet of the barrel body 2.1 and the inlet of the quantitative rotor 3.2, the quantitative rotor sleeve 3.3 is superposed with the discharging rotor 3.4, and materials are discharged;

s4: the kick-out motor 3.8 is started to rotate for the third 120 degrees, namely, the quantitative rotor 3.2 is driven to rotate to the standby position by rotating from the second position to the third position. At the moment, the outlet of the quantitative rotor 3.2 is in a closed state, namely, the outlet is not overlapped with the discharge hole of the leakage-proof turntable 2.5, and the materials of the barrel body 2.1 do not fall into the quantitative rotor 3.2; the material is not overlapped with the discharging rotor 3.4, and the material cannot be discharged;

s5: discharging motor 3.10 reversal drives discharging motor 3.10 gear, pushes back discharging rotor 3.4 to initial position, namely rotates to the third position from the second position, and discharging rotor 3.4 touches micro-gap switch, and micro-gap switch output signal is closing discharging rotor 3.4 promptly, and solid material ejection of compact process is accomplished.

Although the invention has been described in detail above with reference to a general description and specific examples, it will be apparent to one skilled in the art that modifications or improvements may be made thereto based on the invention. Accordingly, such modifications and improvements are intended to be within the scope of the invention as claimed.

Claims (9)

1. The utility model provides a solid material storage and ration feed intelligent device which characterized in that: including ladle body (2.1), stirring paddle leaf (2.2), quantitative rotor (3.2) and quantitative rotor external member (3.3), stirring paddle leaf (2.2) are located inside ladle body (2.1), quantitative rotor (3.2) are located ladle body (2.1) downside, quantitative rotor external member (3.3) rotationally set up in quantitative rotor (3.2), ladle body (2.1) downside is equipped with first entry, quantitative rotor (3.2) upper end has the second entry, quantitative rotor (3.2) downside has first export, quantitative rotor external member (3.3) downside has the second export.

2. The intelligent solid material storage and dosing device of claim 1, wherein: still include leak protection carousel (2.5), leak protection carousel (2.5) are located inside ladle body (2.1), first entry is located leak protection carousel (2.5), first entry is the slot hole that extends along circular arc length direction, slot hole place circular arc contained angle is 120 degrees.

3. The intelligent solid material storage and dosing device of claim 2, wherein: still include rotatory knife tackle (2.3), axis of rotation mounting (2.4) and leak protection silica gel circle (2.6), stirring paddle leaf (2.2) are connected rotatory knife tackle (2.3), rotatory knife tackle (2.3) are connected axis of rotation mounting (2.4), axis of rotation mounting (2.4) are connected with dialling material motor (3.8) transmission, axis of rotation mounting (2.4) downside is equipped with leak protection carousel (2.5), leak protection carousel (2.5) periphery is equipped with leak protection silica gel circle (2.6), prevent leak silica gel circle (2.6) with ladle body (2.1) sliding fit.

4. The intelligent solid material storage and dosing device of claim 3, wherein: still include base shell (3.1) and dial material motor (3.8), base shell (3.1) are located ladle body (2.1) downside, stirring paddle leaf (2.2) with ration rotor external member (3.3) through the gear with dial material motor (3.8) transmission and connect, ration rotor (3.2) with ration rotor external member (3.3) are located inside base shell (3.1).

5. The intelligent solid material storage and dosing device of claim 4, wherein: still include ejection of compact motor (3.10) and ejection of compact rotor (3.4), ejection of compact motor (3.10) are located inside base shell (3.1), ejection of compact rotor (3.4) are located ration rotor external member (3.3) downside, ejection of compact motor (3.10) control ejection of compact rotor (3.4) rotate, ejection of compact rotor (3.4) upper end is equipped with the third entry, ejection of compact rotor (3.4) lower extreme is equipped with the third export.

6. The intelligent solid material storage and dosing device of claim 5, wherein: the quantitative material stirring device is characterized by further comprising a control unit, an angle sensor and a position sensor, wherein the material stirring motor (3.8) and the material discharging motor (3.10) are electrically connected with the control unit respectively, the angle sensor is electrically connected with the quantitative rotor kit (3.3), and the position sensor is electrically connected with the material discharging rotor (3.4).

7. The intelligent solid material storage and dosing device of claim 6, wherein: the automatic discharging device is characterized by further comprising a microswitch (3.11), and when the discharging rotor (3.4) rotates to the third position, the discharging rotor (3.4) touches the microswitch (3.11).

8. The intelligent solid material storage and dosing device of claim 5, wherein: ejection of compact motor (3.10) are connected through rubber pad subassembly (4) base shell (3.1), rubber pad subassembly (4) are including rubber pad (4.1) and rubber pad locking part (4.2), rubber pad (4.1) are connected ejection of compact motor (3.10), rubber pad locking part (4.2) are connected base shell (3.1), rubber pad locking part (4.2) are equipped with the recess, rubber pad (4.1) set up in the recess.

9. The intelligent solid material storage and dosing device of claim 1, wherein: the novel multifunctional kitchen utensil is characterized by further comprising an upper cover (1.1), wherein a handle is arranged on the upper cover (1.1), and an upright placing surface is arranged on one side, close to the periphery of the upper cover (1.1), of the handle.

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