CN216224075U - Additive quantitative feeding device for cleaning and finish machining production - Google Patents

Abstract

The utility model discloses an additive quantitative feeding device for cleaning and finish machining production, which comprises a shell, a driving assembly, a stirring assembly, a suction assembly and a bearing tank, wherein the shell is internally provided with a driving cavity, a stirring cavity, a standing cavity, a suction cavity and a conveying cavity from top to bottom in sequence, a partition plate is arranged between the driving cavity and the stirring cavity, a connecting port is arranged at the joint of the stirring cavity and the standing cavity, the suction cavity is respectively connected with the standing cavity and the conveying cavity, the driving assembly is arranged in the driving cavity, the stirring assembly is arranged in the stirring cavity and is connected with the driving assembly by penetrating through the partition plate, the suction assembly is arranged in the suction cavity, and the bearing tank is arranged in the conveying cavity. The utility model relates to the technical field of production and processing, in particular to an additive quantitative feeding device for cleaning and finish machining production.

Description

Additive quantitative feeding device for cleaning and finish machining production

Technical Field

The utility model relates to the technical field of production and processing, in particular to an additive quantitative feeding device for cleaning and finish machining production.

Background

The detergent is a common cleaning article in daily life, and can play roles of quickly decontaminating, sterilizing, effectively cleaning and the like so as to ensure the household sanitation and avoid the infection of germs. Various additives are required to be added in the production and processing of the liquid detergent, so that the cleaning effect of the liquid detergent is enhanced, and the use amount of the additives is required to be controlled due to toxic components in the additives; and the additive is not uniformly mixed in the process of mixing, so that the cleaning effect of the finished product is greatly reduced.

SUMMERY OF THE UTILITY MODEL

Aiming at the situation, the utility model provides the additive quantitative feeding device for the cleaning and finishing production in order to overcome the defects of the prior art.

The technical scheme adopted by the utility model is as follows: the utility model relates to an additive quantitative feeding device for cleaning and finish machining production, which comprises a shell, a driving component, a stirring component, a suction component and a bearing tank, wherein a driving cavity, a stirring cavity, a standing cavity, a suction cavity and a conveying cavity are sequentially arranged in the shell from top to bottom, a partition plate is arranged between the driving cavity and the stirring cavity, a connecting port is arranged at the joint of the stirring cavity and the standing cavity, the suction cavity is respectively connected with the standing cavity and the conveying cavity, the driving component is arranged in the driving cavity, the stirring component is arranged in the stirring cavity and is connected with the driving component by penetrating through the partition plate, the suction component is arranged in the suction cavity, the bearing tank is arranged in the conveying cavity, the stirring component comprises a rotating shaft, a driving gear, a connecting shaft, a threaded rod and stirring blades, the rotating shaft is rotatably arranged on the top wall of the driving cavity, the driving gear is arranged on the rotating shaft, and the connecting shaft is arranged on the rotating shaft in a sliding and penetrating manner, the threaded rod is arranged on the connecting shaft and penetrates through a threaded hole in the partition plate to extend into the stirring cavity, and the stirring blade is arranged at the bottom of the threaded rod.

Further, drive assembly includes driving motor one, rolling disc, lug one, catch bar, rack and stopper, driving motor one is located on the drive chamber, the rolling disc is located on driving motor one's the output shaft, lug one is located on the rolling disc and is kept away from the setting of rolling disc center, the catch bar is articulated to be located on the lug one, the stopper is located on the drive chamber, be equipped with the sliding tray on the stopper, the rack is articulated to be located on the catch bar and to slide and locate in the sliding tray, rack and drive gear meshing.

Furthermore, the top end of the connecting port close to the stirring cavity is provided with an electric sealing door in an opening and closing manner.

Furthermore, a first conical hole and a second conical hole are formed in the suction cavity, and the suction cavity is connected with the standing cavity and the conveying cavity through the first conical hole and the second conical hole respectively.

Further, the suction assembly comprises a hydraulic rod, a piston, a first sealing ball, a first limiting spring, a second sealing ball, a second limiting spring and a baffle, the hydraulic rod is arranged on the inner wall of the suction cavity, the piston is arranged on the movable end of the hydraulic rod and slides to be arranged in the suction cavity, the small end of the first conical hole is communicated with the standing cavity, the suction cavity is arranged in the first limiting spring, the first sealing ball is arranged on the first limiting spring and is located in the first conical hole, the first sealing ball is intermittently plugged on the first conical hole, the baffle is arranged in the suction cavity and is located between the piston and the first conical hole, the small end of the second conical hole is communicated with the suction cavity, the second limiting spring is arranged on the end wall of the second conical hole, the second sealing ball is arranged on the second limiting spring and is close to the small end of the second conical hole, and the second sealing ball is intermittently plugged on the second conical hole.

Furthermore, the two conical holes are located between the piston and the baffle, and a circulation hole is formed in the baffle and located below the first sealing ball.

Furthermore, a filter screen is arranged at an opening at the bottom end of the connecting port, and the mixed catalyst is filtered.

Further, a heater is arranged on the side wall of the standing cavity and used for heating the mixed catalyst in the standing cavity.

Furthermore, the shell is provided with an opening and closing door, the bearing tank can be taken out by opening the opening and closing door, and a quantitative additive is added into the raw materials.

Further, bear the tank bottom and be equipped with pressure sensor for the weight that bears on the impression bears the jar, be equipped with the feed inlet on the stirring chamber, can add the stirring chamber through the feed inlet with different additives.

The utility model with the structure has the following beneficial effects: in the using process, the stirring component can not only rotate in a reciprocating way, but also move up and down, so that the stirring effect on the mixed catalyst is improved; the standing cavity is used for standing and mixing the catalyst and heating the catalyst, so that various catalysts can be better reacted and dissolved, and the catalytic effect of the catalyst is improved; the pumping assembly can control the transmission of the mixed catalyst and prevent liquid leakage; the matching of the bearing tank and the pressure sensor can achieve the purpose of good quantitative material taking.

Drawings

FIG. 1 is a schematic view of the overall structure of an additive quantitative feeding device for cleaning and finishing production according to the present invention.

The device comprises a shell, a driving component, a stirring component, a pumping component, a bearing tank, a driving cavity, a stirring cavity, a driving cavity, a standing cavity, a stirring cavity, a driving cavity, a pumping cavity, a conveying cavity, a rotating shaft, a driving gear, a connecting shaft, a threaded rod, a stirring blade, a driving motor I, a rotating disk, a protruding block I, a driving rod, a rack, a driving rod, a limiting block, an electric sealing door, a conical hole I, a conical hole II, a hydraulic rod, a piston, a sealing ball I, a limiting spring 29, a sealing ball II, a limiting spring 31, a baffle, a filter screen, a heater, a pressure sensor, a 35 and a feeding hole.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments; 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 description of the present invention, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are merely for convenience in describing the present invention and simplifying the description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention.

As shown in figure 1, the utility model is an additive quantitative feeding device for cleaning and finish machining production, which comprises a shell 1, a driving component 2, a stirring component 3, a suction component 4 and a bearing tank 5, wherein the shell 1 is internally provided with a driving cavity 6, a stirring cavity 7, a standing cavity 8, a suction cavity 9 and a conveying cavity 10 from top to bottom in sequence, a partition plate is arranged between the driving cavity 6 and the stirring cavity 7, a connecting port is arranged at the joint of the stirring cavity 7 and the standing cavity 8, the suction cavity 9 is respectively connected with the standing cavity 8 and the conveying cavity 10, the driving component 2 is arranged in the driving cavity 6, the stirring component 3 is arranged in the stirring cavity 7 and is connected with the driving component 2 by penetrating through the partition plate, the suction component 4 is arranged in the suction cavity 9, the bearing tank 5 is arranged in the conveying cavity 10, the stirring component 3 comprises a rotating shaft 11, a driving gear 12, a connecting shaft 13, a threaded rod 14 and a stirring blade 15, the rotating shaft 11 is rotatably arranged on the top wall of the driving cavity 6, the driving gear 12 is arranged on the rotating shaft 11, the connecting shaft 13 is arranged on the rotating shaft 11 in a sliding penetrating mode, the threaded rod 14 is arranged on the connecting shaft 13 and extends into the stirring cavity 7 through the threaded hole in the partition plate, and the stirring blade 15 is arranged at the bottom of the threaded rod 14.

Wherein, drive assembly includes driving motor 16, rolling disc 17, lug 18, catch bar 19, rack 20 and stopper 21, driving motor 16 is located on drive chamber 6, rolling disc 17 is located on the output shaft of driving motor 16, lug 18 is located on rolling disc 17 and is kept away from rolling disc 17 center setting, catch bar 19 articulates and locates on lug 18, stopper 21 is located on drive chamber 6, be equipped with the sliding tray on the stopper 21, rack 20 articulates and locates on catch bar 19 and slide and locate the sliding tray, rack 20 and drive gear 12 mesh.

The top end of the connecting port close to the stirring cavity 7 is provided with an electric sealing door 22 in an opening and closing way.

The suction cavity is provided with a first conical hole 23 and a second conical hole 24, and the suction cavity 9 is respectively connected with the standing cavity 8 and the conveying cavity 10 through the first conical hole 23 and the second conical hole 24.

The suction assembly comprises a hydraulic rod 25, a piston 26, a first sealing ball 27, the device comprises a first limiting spring 28, a second sealing ball 29, a second limiting spring 30 and a baffle 31, wherein the hydraulic rod 25 is arranged on the inner wall of the suction cavity 9, the piston 26 is arranged on the movable end of the hydraulic rod 25 and is arranged in the suction cavity 9 in a sliding manner, the small end of the first conical hole 23 is communicated with the standing cavity 8, the first limiting spring 28 is arranged in the suction cavity 9, the first sealing ball 27 is arranged on the first limiting spring 28 and is positioned in the first conical hole 23, the first sealing ball 27 is intermittently plugged on the first conical hole 23, the baffle 30 is arranged in the suction cavity 9 and is positioned between the piston 26 and the first conical hole 23, the small end of the second conical hole 24 is communicated with the suction cavity 9, the second limiting spring 30 is arranged on the expanded end wall of the second conical hole 24, the second sealing ball 29 is arranged on the second limiting spring 30 and is close to the small end of the second conical hole 24, and the second sealing ball 29 is intermittently plugged on the second conical hole 24.

The second conical hole 24 is positioned between the piston 26 and the baffle plate 31, and the baffle plate 31 is provided with a flow hole which is positioned below the first sealing ball 27.

A filter screen 32 is arranged at the opening at the bottom end of the connecting port; a heater 33 is arranged on the side wall of the standing cavity 8; the shell 1 is provided with an opening and closing door; the bottom of the bearing tank 5 is provided with a pressure sensor 34; the stirring cavity 7 is provided with a feeding hole 35.

When in specific use: in the using process, different catalysts are added into the stirring cavity 7 through the feeding hole 35, at the moment, the electric sealing door 22 is sealed on the connecting port, the catalysts are positioned on the electric sealing door 22, the driving motor I16 is started, the output shaft of the driving motor I16 rotates to drive the rotating disc I17 to rotate, so as to drive the first bump I18 to rotate, the push rod 19 is hinged on the first bump I18, so that the first bump I18 rotates to push and pull the push rod 19 to move, because the rack 20 is arranged in the sliding groove in a sliding mode and is hinged on the push rod 19, the push rod 19 drives the rack 20 to reciprocate in the sliding groove, and because the rack 20 is meshed with the driving gear 12, the driving gear 12 and the rotating shaft 11 can alternatively rotate along the counterclockwise direction and the clockwise direction, because the connecting shaft 13 is arranged on the rotating shaft 11 in a sliding mode, the connecting shaft 13 can alternatively rotate along the counterclockwise direction and the clockwise direction, because the threaded rod 14 is arranged on the connecting shaft 13, the connecting shaft 13 can drive the threaded rod 14 to alternatively rotate anticlockwise and clockwise, and the threaded rod 14 penetrates through a threaded hole in the partition plate and extends into the stirring cavity 7, the threaded rod 14 can move up and down in the stirring cavity 7, and because the stirring blade 15 is arranged on the threaded rod 14, the stirring blade 15 can move up and down while rotating, so that a good stirring effect is generated on a mixed catalyst in the stirring cavity 7; after the stirring process is finished, the electric sealing door 22 is opened, so that the stirred catalyst enters the standing cavity 8 through the connecting port and the filter screen 32, and the heater 33 is opened, so that the mixed catalyst in the standing cavity 8 is fully reacted and dissolved; the hydraulic rod 25 is contracted to drive the piston 26 to move leftwards to generate pressure difference, under the action of pressure, the sealing ball I27 compresses the limit spring I28 to move downwards to be far away from the small end of the conical hole I23, the conical hole I23 is opened to enable the mixed catalyst in the standing cavity 8 to enter the suction cavity 9 through the conical hole I23 and the through hole, when the hydraulic rod 25 is contracted to the leftmost end, the suction process is finished, the hydraulic rod 25 is extended to drive the piston 26 to push the mixed catalyst to move rightwards, the pressure generated by the mixed catalyst can enable the sealing ball I27 to rise to be plugged at the small end of the conical hole I23 again, and the pressure can enable the sealing ball II 29 to compress the limit spring II 30 to fall to be far away from the small end of the conical hole II 24 to enable the conical hole II 24 to be opened, so that the mixed catalyst flows into the conveying cavity 10 through the conical hole II 24 to be contained in the bearing tank 5, when the pressure sensor 34 senses that the weight of the additive reaches the designated weight, the hydraulic rod 25 stops moving, so that the additive is quantitatively added and conveyed.

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.

While there have been shown and described what are at present considered the fundamental principles and essential features of the utility model and its advantages, it will be apparent to those skilled in the art that the utility model is not limited to the details of the foregoing exemplary embodiments, but is capable of other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the utility model being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (10)

1. The utility model provides a washing finish machining production is with additive ration material feeding unit which characterized in that: comprises a shell, a driving component, a stirring component, a suction component and a bearing tank, wherein the shell is internally provided with a driving cavity, a stirring cavity, a standing cavity, a suction cavity and a conveying cavity from top to bottom in sequence, a partition plate is arranged between the driving cavity and the stirring cavity, a connecting port is arranged at the joint of the stirring cavity and the standing cavity, the suction cavity is respectively connected with the standing cavity and the conveying cavity, the driving component is arranged in the driving cavity, the stirring component is arranged in the stirring cavity and connected with the driving component through the partition plate, the suction component is arranged in the suction cavity, the bearing tank is arranged in the conveying cavity, the stirring component comprises a rotating shaft, a driving gear, a connecting shaft, a threaded rod and stirring blades, the rotating shaft is rotatably arranged on the top wall of the driving cavity, the driving gear is arranged on the rotating shaft, the connecting shaft is slidably arranged on the rotating shaft, the threaded rod is arranged on the connecting shaft and extends into the stirring cavity through the threaded hole on the partition plate, the stirring blade is arranged at the bottom of the threaded rod.

2. The additive quantitative feeding device for cleaning and finishing production according to claim 1, wherein: the driving assembly comprises a first driving motor, a rotating disc, a first protruding block, a pushing rod, a rack and a limiting block, the first driving motor is arranged on a driving cavity, the rotating disc is arranged on an output shaft of the first driving motor, the first protruding block is arranged on the rotating disc and far away from the center of the rotating disc, the pushing rod is hinged to the first protruding block, the limiting block is arranged on the driving cavity, a sliding groove is formed in the limiting block, the rack is hinged to the pushing rod and is arranged in the sliding groove in a sliding mode, and the rack is meshed with the driving gear.

3. The additive quantitative feeding device for cleaning and finishing production according to claim 1, wherein: the top end of the connecting port close to the stirring cavity is provided with an electric sealing door in an opening and closing manner.

4. The additive quantitative feeding device for cleaning and finishing production according to claim 1, wherein: the suction cavity is provided with a first conical hole and a second conical hole, and the suction cavity is connected with the standing cavity and the conveying cavity through the first conical hole and the second conical hole respectively.

5. The additive quantitative feeding device for cleaning and finishing production according to claim 4, wherein: the suction assembly comprises a hydraulic rod, a piston, a first sealing ball, a first limiting spring, a second sealing ball, a second limiting spring and a baffle, the hydraulic rod is arranged on the inner wall of a suction cavity, the piston is arranged on the movable end of the hydraulic rod and slides to be arranged in the suction cavity, the small end of the first conical hole is communicated with the static cavity, the suction cavity is arranged in the first limiting spring, the first sealing ball is arranged on the first limiting spring and is positioned in the first conical hole, the first sealing ball is intermittently plugged on the first conical hole, the baffle is arranged in the suction cavity and is positioned between the piston and the first conical hole, the small end of the second conical hole is communicated with the suction cavity, the second limiting spring is arranged on the second expanded end wall of the second conical hole, the second sealing ball is arranged on the second limiting spring and is close to the small end of the second conical hole, and the second sealing ball is intermittently plugged on the second conical hole.

6. The additive quantitative feeding device for cleaning and finishing production of the motor vehicle as claimed in claim 5, wherein: the conical hole is located between the piston and the baffle, a circulation hole is formed in the baffle, and the circulation hole is located below the first sealing ball.

7. The additive quantitative feeding device for cleaning and finishing production according to claim 3, wherein: and a filter screen is arranged at the opening at the bottom end of the connecting port.

8. The additive quantitative feeding device for cleaning and finishing production according to claim 1, wherein: and a heater is arranged on the side wall of the standing cavity.

9. The additive quantitative feeding device for cleaning and finishing production according to claim 1, wherein: the shell is provided with an opening and closing door.

10. The additive quantitative feeding device for cleaning and finishing production according to claim 1, wherein: bear the tank bottoms portion and be equipped with pressure sensor, be equipped with the feed inlet on the stirring chamber.

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