CN117323899A - Quantitative feeding device of stirring equipment - Google Patents

Abstract

The invention discloses a quantitative feeding device of stirring equipment, which comprises a stirring tank, a movable block, a rotating plate, an elastic clamping plate and a switching component, wherein the switching component is used for driving a proportioning bottle to rotate in a gap manner; the contact assembly is used for enabling the rotating plate to be in contact with the switching assembly so as to realize clearance fit and further ensuring the movement switching of the rotating plate; when the motor slowly drives the first movable plate to do circular motion and the pressing column enters the notch of the limiting ring, the sliding plate is acted to enable the pressing piece to press the proportioning bottle to finish adding of the additive, the arc plate is acted to enable the sliding block to move on the one hand, the rotating plate is enabled to be contacted with the rotating plate, after the additive is dripped, the clamping groove acts as a clamping plate, the rotating plate and the proportioning bottle are enabled to be far away from the U-shaped plate, the other proportioning bottle is cut into the corresponding position of the U-shaped plate, the next proportioning bottle is dripped in the gap, and the mode ensures the frequency and the gap interval of dripping of different proportioning bottles.

Description

Quantitative feeding device of stirring equipment

Technical Field

The invention relates to the technical field of feeding devices of stirring equipment, in particular to a quantitative feeding device of the stirring equipment.

Background

When the papermaking stirring equipment stirs the mixture of slurry and the like, additives such as chemical reactants and the like are generally added to catalyze the slurry, so that the quality of subsequent paper production is ensured.

The stirring tank has a plurality of types of additives which are required to be added, the addition of the additives has a certain sequence requirement, the conventional stirring equipment generally adds one additive completely, and then adds the other additive completely, and one additive is added at a time, so that the additive can not react with the mixed solution completely, namely the conventional feeding device can not drop the additives circularly, and the drop gap time of two adjacent additives is ensured.

For this purpose, we propose a dosing device for a stirring apparatus.

Disclosure of Invention

The invention aims to provide a quantitative feeding device of stirring equipment, which aims to solve the problems in the background technology.

In order to achieve the above purpose, the present invention provides the following technical solutions: the quantitative feeding device of the stirring equipment comprises a stirring tank with a stirring piece inside and a movable block, wherein an insertion hole in press fit with the movable block is penetrated through the stirring tank, a plurality of circumferentially distributed rotating plates are arranged on the movable block, and an elastic clamping plate for clamping a proportioning bottle is connected to the rotating plates; the switching assembly is used for driving the proportioning bottle on the rotating plate to rotate at a switching position in a gap; the contact assembly is used for enabling the rotating plate to be in contact with the switching assembly so as to realize clearance fit, and meanwhile, the moving switching of the rotating plate is further guaranteed; and the extrusion assembly is matched with the switching assembly to press the proportioning bottle.

Preferably, the switching assembly comprises a motor which is embedded and fixed with the movable block, an output shaft end part of the motor is fixedly connected with a self-rotating plate, a clamping groove is formed in the self-rotating plate, a plurality of clamping plates matched with the clamping groove are fixedly connected to the rotating plate, and the clamping plates are in abutting fit with the edges of the self-rotating plate.

Preferably, the contact assembly comprises an arc-shaped plate and a first movable plate fixedly connected with an output shaft of the motor, the end part of the first movable plate is rotationally connected with a second movable plate, two ends of the second movable plate are rotationally connected with a pressing column, a limiting ring with a notch is fixedly connected to the movable block through a connecting rod, a U-shaped plate is fixedly connected to the notch of the limiting ring, the pressing column is in sliding fit with the limiting ring and the U-shaped plate, and the pressing column is in movable fit with the arc-shaped plate through a connecting assembly.

Preferably, the connecting assembly comprises a rotating plate with a hollow inside, a plurality of connecting plates are fixedly connected to the inner wall of the limiting ring, limiting arc plates which are fixedly connected to the end parts of the connecting plates and are in sliding fit with the rotating plate, a plurality of movable grooves are formed in the rotating plate, connecting plates are fixedly connected to the connecting plates, and sleeves are fixedly connected to the end parts of the connecting plates.

Preferably, the contact assembly further comprises a sleeve plate which is fixedly connected with the arc plate and movably sleeved with the sleeve, an elastic pull rope is connected between the sleeve plate and the connecting plate in a hanging fit mode, a sliding block which is in butt press fit with the sleeve plate is slidably matched in the movable groove, a rotating column which is fixedly connected with the rotating plate is fixedly connected with the sliding block, a contact plate which is obliquely distributed is fixedly connected with the bottom of the sliding block, the contact plate is in butt press fit with the second movable plate, a rotating shaft is connected in the rotating plate in a rotating mode, and a first pressure spring which is obliquely distributed is connected between the rotating shaft and the sliding block in a hanging fit mode.

Preferably, the extrusion assembly comprises a telescopic rod fixedly connected with the U-shaped plate, a sliding plate fixedly connected with the end part of the telescopic rod and in butt press fit with the butt pressing column, a second pressure spring is connected between the sliding plate and the U-shaped plate in a hanging fit mode, the second pressure spring is wound on the outer surface of the telescopic rod, an L-shaped plate is hinged to the sliding plate, a butt pressing part in butt press fit with the proportioning bottle is fixedly connected with the end part of the L-shaped plate, a limiting groove is formed in the L-shaped plate, and a U-shaped rod fixedly connected with the U-shaped plate is in sliding fit with the limiting groove.

Preferably, the position of the connecting plate is higher than the position of the pressing column, so that position collision is avoided.

Preferably, the movable block top fixedly connected with the fixed electric telescopic link in factory shed top is convenient for lift movable block change or add the ratio bottle.

Preferably, the edge of the movable block is fixedly connected with a limit ring plate which is in abutting fit with the insertion hole, so that the movable block is ensured to be inserted into the stirring tank, additives in the proportioning bottle are convenient to enter the stirring tank, a baffle for blocking the insertion hole is movably inserted into the stirring tank, and gas in the stirring tank is prevented from overflowing when the movable block is separated from the insertion hole.

Compared with the prior art, the invention has the beneficial effects that:

1. when the motor slowly drives the first movable plate to do circular motion and the pressing column enters the notch of the limiting ring, the sliding plate is acted on one hand to enable the pressing piece to press the proportioning bottle to finish dripping of the additive, the arc plate is acted on the other hand to enable the sliding block to move, so that the rotating plate is contacted with the rotating plate, after the additive is dripped, the clamping groove is used for enabling the rotating plate and the proportioning bottle to be far away from the U-shaped plate, the other rotating plate and the proportioning bottle are cut into the corresponding positions of the U-shaped plate, and under the action of the first movable plate of the next circle, the next dripping of the additive is finished in a gap.

2. After the additive drops into the completion, first fly leaf and second fly leaf and U shaped plate are in the coincidence position, and the first fly leaf that continues to remove makes the second fly leaf rotate, and the contact plate of second fly leaf effect slope cooperates the effect of draw-in groove to the cardboard, ensures the smooth switching of this rotor plate, makes another rotor plate correspond the U shaped plate, is convenient for drop into of next bottle additive.

3. In the process of extruding the proportioning bottle by the pressing piece, the sliding block and the proportioning bottle move along the movable groove, so that the proportioning bottle can rapidly shake a small distance when being extruded, and the additive of the proportioning bottle can be more helped to drop down.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present invention;

FIG. 2 is a schematic cross-sectional view of a stirred tank of the present invention;

FIG. 3 is a schematic view showing the structure of the movable block disengaging from the insertion hole according to the present invention;

FIG. 4 is a schematic cross-sectional view of a movable block according to the present invention;

FIG. 5 is a schematic diagram of the connection structure of the motor and the motor output shaft of the present invention;

FIG. 6 is a schematic view of the bottom view of the structure of the present invention with the movable block removed;

FIG. 7 is a schematic view of the structure of the rotating plate of the present invention with the redundant arrays removed;

FIG. 8 is a schematic view of the stop collar of FIG. 7;

FIG. 9 is a schematic view of the structure of the rotating plate and U-shaped plate of the present invention;

FIG. 10 is a schematic view of the cut-away rotor plate of FIG. 8;

FIG. 11 is a schematic view of the structure of the connection assembly and the compression assembly of FIG. 10;

FIG. 12 is a schematic view of the extrusion assembly of FIG. 11 shown in an exploded view;

FIG. 13 is a bottom view of the connection assembly of the present invention;

FIG. 14 is a schematic view of the connection assembly of FIG. 12 in a disassembled configuration;

fig. 15 is a schematic view of a connection structure of the slider and the arc plate in fig. 14.

In the figure: 1-a stirring tank; 2-a movable block; 3-an insertion hole; 4-rotating the plate; 5-a motor; 6-a self-rotating plate; 7-clamping grooves; 8-clamping plates; 9-a contact assembly; 10-arc-shaped plates; 11-a first movable plate; 12-a second movable plate; 13-pressing the column; 14-limiting rings; 15-U-shaped plates; a 16-connection assembly; 17-rotating plate; 18-connecting plates; 19-limiting arc plates; 20-a movable groove; 21-connecting plates; 22-sleeve; 23-sleeve plate; 24-elastic pull ropes; 25-sliding blocks; 26-a rotating column; 27-contact plate; 28-rotating shaft; 29-a first compression spring; 30-an extrusion assembly; 31-a telescopic rod; 32-a sliding plate; 33-a second compression spring; a 34-L-shaped plate; 35-a limit groove; 36-U-shaped bar; 37-an elastic clamping plate; 38-a switching assembly; 39-an electric telescopic rod; 40-limiting collar plates; 41-baffle.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Example 1

Referring to fig. 1-7, a quantitative feeding device of a stirring device in the drawings comprises a stirring tank 1 with stirring pieces inside and a movable block 2, wherein an insertion hole 3 in pressing fit with the movable block 2 is penetrated through the stirring tank 1, a plurality of circumferentially distributed rotating plates 4 are arranged on the movable block 2, and an elastic clamping plate 37 for clamping a proportioning bottle is connected to the rotating plates 4; the automatic bottle proportioning device further comprises a switching assembly 38, wherein the switching assembly 38 is used for driving the proportioning bottle on the rotating plate 4 to rotate at a switching position in a gap; a contact assembly 9, the contact assembly 9 is used for enabling the rotating plate 4 to be in contact with the switching assembly 38 so as to realize clearance fit, and meanwhile, the movement switching of the rotating plate 4 is further ensured; the squeezing component 30, the squeezing component 30 cooperates with the switching component 38 to press the proportioning bottles, the capacity of each proportioning bottle is different, and the capacity is set in proportion to the proportioning.

Referring to fig. 8-10, the switching assembly 38 in the drawings includes a motor 5 embedded and fixed with the movable block 2, an output shaft end of the motor 5 is fixedly connected with a rotation plate 6, a clamping groove 7 is formed on the rotation plate 6, a plurality of clamping plates 8 matched with the clamping groove 7 are fixedly connected on the rotation plate 4, and the clamping plates 8 are in abutting and press fit with edges of the rotation plate 6.

Referring to fig. 8-10, the contact assembly 9 in the drawings comprises an arc-shaped plate 10 and a first movable plate 11 fixedly connected with an output shaft of the motor 5, wherein the end part of the first movable plate 11 is rotatably connected with a second movable plate 12, two ends of the second movable plate 12 are rotatably connected with a pressing post 13, a limiting ring 14 with a notch is fixedly connected to the movable block 2 through a connecting rod, a U-shaped plate 15 is fixedly connected to the notch of the limiting ring 14, the pressing post 13 is in sliding fit with the limiting ring 14 and the U-shaped plate 15, and the pressing post 13 is in movable fit with the arc-shaped plate 10 through a connecting assembly 16.

Referring to fig. 11-14, the connecting assembly 16 in the drawings includes a hollow rotating plate 17, a plurality of connecting plates 18 are fixedly connected to the inner wall of the limiting ring 14, a limiting arc plate 19 slidably matched with the rotating plate 17 is fixedly connected to the end of the connecting plates 18, a plurality of movable slots 20 are formed in the rotating plate 17, a connecting plate 21 is fixedly connected to the connecting plates 18, and a sleeve 22 is fixedly connected to the end of the connecting plate 21.

Referring to fig. 12-15, the contact assembly 9 in the drawings further includes a sleeve plate 23 fixedly connected with the arc plate 10 and movably sleeved with the sleeve 22, an elastic pull rope 24 is connected between the sleeve plate 23 and the connecting plate 21 in a hanging manner, a sliding block 25 in a sliding manner is connected with the sleeve plate 23 in a sliding manner in the movable groove 20 in a pressing manner, a rotating column 26 fixedly connected with the rotating plate 4 is fixedly connected to the sliding block 25, a contact plate 27 in an inclined manner is fixedly connected to the bottom of the sliding block 25, the contact plate 27 is in pressing manner with the second movable plate 12 in a pressing manner, a rotating shaft 28 is connected in a rotating manner to the rotating plate 17 in a hanging manner, and a first pressure spring 29 in an inclined manner is connected between the rotating shaft 28 and the sliding block 25 in a hanging manner. In this embodiment, the movable block 2 is moved up by the electric telescopic rod 39 (or manually adjusted), and is separated from the insertion hole 3, and meanwhile, the insertion hole 3 is blocked by the baffle 41, so that the gas of the catalytic reaction in the stirring tank 1 is prevented from overflowing, then a plurality of different proportioning bottles are sequentially placed on the rotating plate 4 in sequence, the proportioning bottles are fixed by the elastic clamping plate 37, then the movable block 2 is inserted into the insertion hole 3 again by the electric telescopic rod 39 (or manually adjusted), the limit ring plate 40 is propped against the insertion hole 3, and the movable block 2 is supported, and at the moment, the proportioning bottles are aligned to the inside of the stirring tank 1;

the operation of the motor 5 is controlled by the calculator, so that the motor 5 is started, and the output shaft of the motor 5 continuously and slowly rotates (a speed reducer or a low-speed motor 5 can be arranged, and the like are all conventional technologies), so that the self-rotating plate 6 and the first movable plate 11 are driven to continuously rotate;

the first movable plate 11 drives the second movable plate 12 to do circular motion, the two pressing posts 13 roll along the limiting rings 14, when the limiting rings 14 do not contact the notch position, the rotating plate 4 keeps unchanged in position and does not contact the rotating plate 6, and the rotating plate 6 which continuously rotates cannot act on the rotating plate 4;

when the first movable plate 11 rotates for a circle and approaches to the notch, one pressing column 13, close to the notch, of the two pressing columns 13 contacts the arc plate 10 firstly, on one hand, the pressing column 13 enters the U-shaped plate 15, the second movable plate 12 rotates relative to the first movable plate 11, the extrusion component 30 extrudes the proportioning bottle on the rotating plate 4 close to the U-shaped plate 15, so that the additive in the proportioning bottle at the position drops into the stirring tank 1, on the other hand, the pressing arc plate 10 enables the arc plate 10 to drive the sleeve plate 23 to move along the sleeve, the elastic pull rope 24 is pulled, the moving sleeve plate 23 contacts the sliding block 25 with a fixed position, and applies a force to the sliding block 25 along the direction of the movable groove 20, so that the sliding block 25 moves from one end of the movable groove 20 to the other end of the movable groove 20 and stabilizes the state (wherein the moving distance of the sliding block 25 in the sliding groove is small), and the inclination direction of the first pressure spring 29 changes;

the sliding block 25 moving along the movable groove 20 drives the rotating plate 4 to move and approach the self-rotating plate 6, so that the rotating plate 4 contacts the self-rotating plate 6, at the moment, the extrusion assembly 30 is completed to press the additive to drop the additive into the stirring tank 1, meanwhile, the first movable plate 11 and the second movable plate 12 are overlapped with the U-shaped plate 15 in position, one pressing column 13 is positioned at the deepest part of the U-shaped plate 15, and the second movable plate 12 contacts the contact plate 27;

on the one hand, the clamping groove 7 of the autorotation plate 6 acts on the clamping plate 8 to enable the rotating plate 4 to move, the rotating plate 17 rotates along the limiting arc plate 19, on the other hand, the continuously rotating second movable plate 12 acts on the inclined contact plate 27, the next rotating plate 4 is matched with the action of the autorotation plate 6, the sliding block 25 slides along the movable groove 20 in the direction far away from the autorotation plate 6, the first pressure spring 29 is overcome, the inclined direction of the first pressure spring 29 is changed again, the rotating plate 4 at the position rotates along with the rotating plate 17 and is separated from the position corresponding to the U-shaped plate 15, the other rotating plate 4 and the proportioning bottle are in correspondence with the position of the U-shaped plate 15 again (the pressing column 13 which is positioned in the U-shaped plate 15 before the moment is separated from the arc plate 10 is acted again, the next rotating plate 4 is not influenced, when the pressing column 13 is completely separated from the contact with the U-shaped plate 15 and the arc plate 10, the next rotating plate 4 rotates to the position corresponding to the U-shaped plate 15), the first rotating plate 11 moves down to be in a circle and is in the position again close to the rotating bottle 13, and the position corresponding to the first rotating bottle 13 is changed relative to the second rotating bottle 13 after the first rotating bottle is in the circle;

it is worth noting that the proportioning bottle (which is an elastic bottle and is filled with the air and the additive) is always in an inverted state, extrusion cannot occur due to the fact that the additive in the proportioning bottle is remained, the additive is not diluted and is generally sticky, the outlet of the proportioning bottle is smaller, the proportioning bottle is inverted and cannot drip, the sticky additive is located at the outlet of the proportioning bottle, and the additive can drip only in an extrusion mode.

Example two

Referring to fig. 11-12, the extrusion assembly 30 in the drawings includes a telescopic rod 31 fixedly connected with a U-shaped plate 15, a sliding plate 32 in abutting fit with the abutting column 13 is fixedly connected to the end of the telescopic rod 31, a second compression spring 33 is connected between the sliding plate 32 and the U-shaped plate 15 in a hanging fit manner, the second compression spring 33 is wound on the outer surface of the telescopic rod 31, an L-shaped plate 34 is hinged to the sliding plate 32, an abutting part in abutting fit with a proportioning bottle is fixedly connected to the end of the L-shaped plate 34, a limiting groove 35 is formed in the L-shaped plate 34, and a U-shaped rod 36 fixedly connected with the U-shaped plate 15 is in sliding fit with the limiting groove 35.

In this embodiment, the pressing post 13 located in front enters the U-shaped plate 15, and presses the sliding plate 32 to make the telescopic rod 31 extend and retract, and the second compression spring 33 is pressed, so that the L-shaped plate 34 rotates with the U-shaped plate 15 as the rotating shaft 28, and the pressing piece presses the proportioning bottle, so that the liquid medicine of the proportioning bottle drops into the stirring tank 1;

it is noted that, during the process of pressing the proportioning bottle by the pressing member, the sliding block 25 and the proportioning bottle move along the movable groove 20, so that the proportioning bottle is pressed and rapidly shakes a small distance, and the additive of the proportioning bottle is more facilitated to drop down.

It is noted that relational terms such as first and second, and the like are 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. Moreover, 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.

Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (9)

1. A dosing device for a stirring apparatus, comprising:

the stirring tank is characterized in that a stirring part is arranged in the stirring tank (1) and a movable block (2), an insertion hole (3) in pressing fit with the movable block (2) is formed in the stirring tank (1) in a penetrating mode, a plurality of circumferentially distributed rotating plates (4) are arranged on the movable block (2), and an elastic clamping plate (37) for clamping a proportioning bottle is connected to the rotating plates (4);

further comprises:

the switching component (38) is used for driving the proportioning bottle on the rotating plate (4) to rotate at a switching position in a gap manner;

-a contact assembly (9), the contact assembly (9) being adapted to bring the rotating plate (4) into contact with the switching assembly (38) so as to achieve a clearance fit while ensuring a switching of the movement of the rotating plate (4);

and the extrusion assembly (30) is matched with the switching assembly (38) to press the proportioning bottle.

2. A dosing device for a stirring apparatus as claimed in claim 1, wherein: the switching assembly (38) comprises a motor (5) which is embedded and fixed with the movable block (2), an output shaft end part of the motor (5) is fixedly connected with a rotation plate (6), a clamping groove (7) is formed in the rotation plate (6), a plurality of clamping plates (8) matched with the clamping groove (7) are fixedly connected to the rotation plate (4), and the clamping plates (8) are in abutting press fit with the edge of the rotation plate (6).

3. A dosing device for a stirring apparatus according to claim 2, wherein: the contact assembly (9) comprises an arc-shaped plate (10) and a first movable plate (11) fixedly connected with an output shaft of the motor (5), the end part of the first movable plate (11) is rotationally connected with a second movable plate (12), two ends of the second movable plate (12) are rotationally connected with a pressing column (13), a limiting ring (14) with a notch is fixedly connected to the movable block (2) through a connecting rod, a U-shaped plate (15) is fixedly connected to the notch of the limiting ring (14), the pressing column (13) is in sliding fit with the limiting ring (14) and the U-shaped plate (15), and the pressing column (13) is in movable fit with the arc-shaped plate (10) through a connecting assembly (16).

4. A dosing device for a stirring apparatus as claimed in claim 3, wherein: the connecting assembly (16) comprises a rotating plate (17) with a hollow inside, a plurality of connecting plates (18) are fixedly connected to the inner wall of the limiting ring (14), limiting arc plates (19) which are fixedly connected to the end parts of the connecting plates (18) and are in sliding fit with the rotating plate (17), a plurality of movable grooves (20) are formed in the rotating plate (17), connecting plates (21) are fixedly connected to the connecting plates (18), and sleeves (22) are fixedly connected to the end parts of the connecting plates (21).

5. The dosing device for a stirring apparatus of claim 4, wherein: the contact assembly (9) further comprises a sleeve plate (23) which is fixedly connected with the arc plate (10) and movably sleeved with the sleeve (22), an elastic pull rope (24) is connected between the sleeve plate (23) and the connecting plate (21) in a hanging mode, a sliding block (25) which is in pressing fit with the sleeve plate (23) in a sliding mode is arranged in the movable groove (20), a rotating column (26) which is fixedly connected with the rotating plate (4) in a connecting mode is fixedly connected to the sliding block (25), a contact plate (27) which is obliquely distributed is fixedly connected to the bottom of the sliding block (25), a rotating shaft (28) is connected with the rotating plate (17) in a rotating mode in a pressing mode, and a first pressure spring (29) which is obliquely distributed is connected between the rotating shaft (28) and the sliding block (25) in a hanging mode.

6. The dosing device of a stirring apparatus of claim 5, wherein: the extrusion assembly (30) comprises a telescopic rod (31) fixedly connected with the U-shaped plate (15), a sliding plate (32) in abutting fit with the abutting column (13) is fixedly connected with the end part of the telescopic rod (31), a second pressure spring (33) is connected between the sliding plate (32) and the U-shaped plate (15) in a hanging fit mode, the second pressure spring (33) is wound on the outer surface of the telescopic rod (31), an L-shaped plate (34) is hinged to the sliding plate (32), an abutting part in abutting fit with a proportioning bottle is fixedly connected with the end part of the L-shaped plate (34), a limiting groove (35) is formed in the L-shaped plate (34), and a U-shaped rod (36) fixedly connected with the U-shaped plate (15) is in sliding fit with the limiting groove (35).

7. The dosing device for a stirring apparatus of claim 4, wherein: the connecting plate (18) is higher than the pressing column (13).

8. A dosing device for a stirring apparatus as claimed in claim 1, wherein: an electric telescopic rod (39) fixed with the top of the factory shed is fixedly connected to the top of the movable block (2).

9. A dosing device for a stirring apparatus as claimed in claim 1, wherein: the edge of the movable block (2) is fixedly connected with a limiting ring plate (40) which is in abutting fit with the insertion hole (3), and a baffle (41) for plugging the insertion hole (3) is movably inserted on the stirring tank (1).