CN216321876U - Reaction kettle stirring mechanism capable of accelerating material turbulence - Google Patents

Abstract

The utility model discloses a reaction kettle stirring mechanism capable of accelerating material turbulence, which comprises a bearing plate and a support column fixedly connected to the bearing plate, wherein a kettle body is fixedly connected to the support column, a motor frame is fixedly connected to the bearing plate, a motor is fixedly connected to the motor frame, the output end of the motor is fixedly connected with a rotating shaft which penetrates through the kettle body and extends into the kettle body, a disk is fixedly connected to the arc-shaped profile of the rotating shaft, two support rods are fixedly connected to the upper surface of the disk, a barrel sleeve is connected to the rotating shaft in a limiting and sliding manner, two sliding grooves are formed in the barrel sleeve and are connected with each support rod in a limiting and sliding manner through each sliding groove, a spring is sleeved on the arc-shaped profile of the rotating shaft, two ends of the spring are respectively fixedly connected with the lower surface of the barrel sleeve and the upper surface of the disk, and a connecting rod is fixedly connected to the upper surface of the barrel sleeve. The utility model achieves the effects of good stirring effect, high speed and time saving by matching the integral structure and realizing large material turbulence during stirring in the kettle body.

Description

Reaction kettle stirring mechanism capable of accelerating material turbulence

Technical Field

The utility model relates to the technical field of stirring mechanisms, in particular to a stirring mechanism of a reaction kettle, which can accelerate material turbulence.

Background

The reaction kettle is a container with physical or chemical reaction, realizes the heating, evaporation, cooling and low-speed and high-speed mixing functions required by the process through the structural design and parameter configuration of the container, is widely applied to the fields of petroleum, chemical engineering, rubber, pesticides, dyes, medicines, food and the like, and is generally made of carbon manganese steel, stainless steel and other composite materials.

Turbulence, also known as turbulence, is a state of flow of a fluid. When the flow rate is very small, the fluids flow in layers and are not mixed with each other, which is called laminar flow or candy slice; gradually increasing the flow speed, starting to generate wave-shaped oscillation on the streamline of the fluid, wherein the frequency and the amplitude of the oscillation increase along with the increase of the flow speed, and the flow condition is called transition flow; when the flow velocity increases to a great extent, the flow lines are no longer clearly distinguishable and there are many small vortices in the flow field, called turbulence, also called turbulence, flow disturbance or turbulence.

At present, most of reaction kettles only rotate for stirring in the stirring process, so that the material turbulence is small during stirring, the stirring effect is poor, the speed is low, and a large amount of time is wasted, so that the problem can be solved by a reaction kettle stirring mechanism capable of accelerating the material turbulence.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a reaction kettle stirring mechanism capable of accelerating material turbulence, which has the advantages of large material turbulence during stirring and capability of manually controlling the material turbulence, and solves the problems in the prior art.

In order to achieve the purpose, the utility model provides the following technical scheme: a reaction kettle stirring mechanism capable of accelerating material turbulence comprises a bearing plate and a supporting column fixedly connected to the bearing plate, wherein a kettle body is fixedly connected to the supporting column, a motor frame is fixedly connected to the bearing plate, a motor is fixedly connected to the motor frame, an output end of the motor is fixedly connected with a rotating shaft which penetrates through the kettle body and extends into the kettle body, a disk is fixedly connected to the arc-shaped outline of the rotating shaft, two supporting rods are fixedly connected to the upper surface of the disk, a barrel sleeve is connected to the rotating shaft in a limiting and sliding manner, two sliding grooves are formed in the barrel sleeve and are connected with each supporting rod in a limiting and sliding manner through each sliding groove, a spring is sleeved on the arc-shaped outline of the rotating shaft, two ends of the spring are respectively fixedly connected with the lower surface of the barrel sleeve and the upper surface of the disk, and a connecting rod is fixedly connected to the upper surface of the barrel sleeve, the barrel casing is coaxially and fixedly connected with two stirrers for stirring materials and liquid, and the kettle body is provided with a control mechanism for accelerating material turbulence.

Preferably, the control mechanism comprises a screw rod, a screw hole is formed in the upper surface of the kettle body and is in threaded connection with the screw rod through the screw hole, and a nut is fixedly connected to the upper surface of the screw rod.

Preferably, the control mechanism further comprises a support plate hinged to the top wall of the kettle body through a pin shaft, the upper surface of the support plate is fixedly connected with the lower surface of the screw rod, and the lower surface of the support plate is abutted to the connecting rod.

Preferably, a feed inlet for feeding is formed in the upper surface of the kettle body, and a cover body is hinged to the upper surface of the kettle body through a pin shaft.

Preferably, the lower surface of the cover body is fixedly connected with a sealing ring matched with the feeding hole.

Preferably, the side of the kettle body is fixedly communicated with a conveying pipe for discharging, and the conveying pipe is fixedly connected with a switch for controlling whether to discharge.

Compared with the prior art, the utility model has the following beneficial effects:

1. the utility model achieves the effects of good stirring effect, high speed and time saving by matching the integral structure and realizing large material turbulence during stirring in the kettle body.

2. According to the utility model, through the matching of the screw rod and the supporting plate, the effect that the material turbulence can be controlled manually by screwing the screw cap is achieved.

Drawings

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

FIG. 2 is a first cross-sectional view of the overall structure of the present invention;

FIG. 3 is a schematic cross-sectional view of the overall structure of the present invention;

fig. 4 is a schematic structural view of the disc and the support rod of the present invention.

In the figure: 1. a bearing plate; 11. a support pillar; 2. a motor; 21. a motor frame; 22. a rotating shaft; 23. a disc; 24. a support bar; 25. a spring; 3. a kettle body; 31. a barrel sleeve; 32. a stirrer; 33. a chute; 34. a connecting rod; 35. a support plate; 4. a cover body; 41. a feed inlet; 5. a delivery pipe; 51. a switch; 6. a screw; 61. and (4) a nut.

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.

The utility model provides a technical scheme that: a reaction kettle stirring mechanism capable of accelerating material turbulence comprises a bearing plate 1 and a support column 11 fixedly connected on the bearing plate 1, a kettle body 3 is fixedly connected on the support column 11, a motor frame 21 is fixedly connected on the bearing plate 1, a motor 2 is fixedly connected on the motor frame 21, an output end of the motor 2 is fixedly connected with a rotating shaft 22 which penetrates through the kettle body 3 and extends into the kettle body 3, a disc 23 is fixedly connected on an arc contour of the rotating shaft 22, two support rods 24 are fixedly connected on the upper surface of the disc 23, a barrel sleeve 31 is in limited sliding connection on the rotating shaft 22, two sliding grooves 33 are arranged on the barrel sleeve 31 and are in limited sliding connection with each support rod 24 through each sliding groove 33, a spring 25 is sleeved on the arc contour of the rotating shaft 22, two ends of the spring 25 are respectively fixedly connected with the lower surface of the barrel sleeve 31 and the upper surface of the disc 23, a connecting rod 34 is fixedly connected on the upper surface of the barrel sleeve 31, the barrel sleeve 31 is coaxially and fixedly connected with two stirrers 32 for stirring materials and liquid, and the kettle body 3 is provided with a control mechanism for accelerating material turbulence.

Refer to fig. 1, fig. 2, fig. 3 and fig. 4, reach the effect that supports whole equipment through setting up bearing plate 1, reach the effect that supports the cauldron body 3 through setting up support column 11, reach the effect that material and liquid can stir the reaction in cauldron body 3 through setting up cauldron body 3, reach the effect that supports motor 2 through setting up motor frame 21, reach axis of rotation 22 pivoted effect through setting up motor 2, rotate through setting up axis of rotation 22 and reach disc 23 and rotate two bracing pieces 24 promptly, through setting up two spout 33 and through every spout 33 and the spacing sliding connection of every bracing piece 24 on the barrel casing 31, reach the synchronous rotation of barrel casing 31 and be connecting rod 34 pivoted effect promptly, thereby rotate the effect that has reached material and liquid in the stirred tank body 3 through setting up barrel casing 31.

Further, control mechanism is including screw rod 6, and the screw has been seted up to the upper surface of the cauldron body 3 and has been passed through screw and 6 spiro unions of screw rod, and the last fixed surface of screw rod 6 is connected with nut 61, and control mechanism is still including articulating the backup pad 35 on the roof of the cauldron body 3 through the round pin axle, and the upper surface of backup pad 35 is connected with the lower fixed surface of screw rod 6, and the lower surface and the connecting rod 34 of backup pad 35 offset.

Referring to fig. 1, 3 and 4, the screw holes are formed on the upper surface of the kettle body 3 and are in threaded connection with the screw rods 6 through the screw holes, so that the screw nuts 61 can be manually screwed to control the up-and-down sliding distance of the barrel casings 31, that is, the screw nuts 61 can be manually screwed to control the turbulence of the material, when the screw rods 6 are manually screwed to the screw nuts 61, the screw rods 6 move downwards, so that the ends, connected with the support plates 35 and the screw rods 6, of the support plates 35 move downwards, so that the support plates 35 incline, and because the lower surfaces of the support plates 35 abut against the connecting rods 34, when the connecting rods 34 rotate, when the ends, connected with the support plates 35 and the screw rods 6, of the connecting rods 34 rotate, at the moment, the connecting rods 34 rotate towards the ends, connected with the support plates 35 and the screw rods 6, so that the springs 25 generate upward elastic force, so that the barrel casings 31 and the connecting rods 34 slide upwards, so reciprocal for barrel casing 31 is rotatory reciprocal up-and-down slip again promptly, and then agitator 32 is rotatory reciprocal up-and-down slip again promptly for the material turbulent flow is big and stirring speed is fast when agitator 32 is rotatory reciprocal up-and-down slip again promptly, thereby has reduced the effect of material and liquid reaction time in the cauldron body 3.

Further, the upper surface of the kettle body 3 is provided with a feeding hole 41 for feeding, and the upper surface of the kettle body 3 is hinged with a cover body 4 through a pin shaft.

Referring to fig. 1 and 2, the effect of manually putting materials and liquids through the feed port 41 is achieved by providing the feed port 41, and the effect of blocking the feed port 41 is achieved by providing the cover 4.

Further, a sealing ring matched with the feed port 41 is fixedly connected to the lower surface of the cover body 4.

Referring to fig. 1 and 2, the sealing ring matched with the feed port 41 is fixedly connected to the lower surface of the cover body 4, so that when the cover body 4 is covered, the sealing ring is matched with the feed port 41, and the sealing effect of materials and liquid during reaction in the kettle body 3 is ensured.

Further, a conveying pipe 5 for discharging is fixedly communicated with the side surface of the kettle body 3, and a switch 51 for controlling whether to discharge is fixedly connected to the conveying pipe 5.

Referring to fig. 1 and 2, the effect of flowing out the mixed liquid after the reaction is completed through the delivery pipe 5 is achieved by setting the delivery pipe 5, and the effect of manually controlling whether to discharge the mixed liquid is achieved by setting the switch 51.

The working principle is as follows: when this kind of can accelerate turbulent reation kettle stirring mechanism of material uses, open lid 4, drop into cauldron body 3 with material and liquid through feed inlet 41 afterwards in, close lid 4 afterwards, sealing washer and the cooperation of feed inlet 41 this moment have guaranteed the sealed effect of material and liquid at cauldron body 3 internal reaction.

Subsequently, the nut 61 is manually screwed to control the up-and-down sliding distance of the barrel casing 31, that is, manually, the nut 61 is screwed to control the turbulent flow of the material, and when the nut 61 is manually screwed, the screw 6 moves downward, so that the end of the support plate 35 connected with the screw 6 moves downward, and the support plate 35 tilts.

The motor 2 is started, the rotating shaft 22 rotates, so that the disk 23 rotates, namely the two supporting rods 24 rotate, the two sliding grooves 33 are formed in the barrel sleeve 31, the barrel sleeve 31 synchronously rotates, namely the connecting rod 34 rotates through the limit sliding connection of each sliding groove 33 and each supporting rod 24, the lower surface of the supporting plate 35 abuts against the connecting rod 34, when the connecting rod 34 rotates to one end where the supporting plate 35 is connected with the screw 6, the connecting rod 34 and the barrel sleeve 31 rotate and slide downwards at the moment, the connecting rod 34 continuously rotates, the connecting rod 34 rotates to one end far away from the connection of the supporting plate 35 and the screw 6 at the moment, the spring 25 generates upward elastic force, so that the barrel sleeve 31 and the connecting rod 34 slide upwards and reciprocate, the barrel sleeve 31 rotates and reciprocates and slides upwards and downwards, the stirrer 32 rotates and reciprocates and upwards and downwards, and the turbulence effect of materials is large and the stirring speed is high when the stirrer 32 rotates and reciprocates and slides upwards, thereby reducing the reaction time of the materials and the liquid in the kettle body 3.

After the mixing of the mixed liquid is completed, the switch 51 is turned on, and then the mixed liquid is discharged through the delivery pipe 5, and after the discharge, the switch 51 is turned off, resulting in an effect of sealing inside the tank body 3.

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

Claims (6)

1. The utility model provides a can accelerate reation kettle rabbling mechanism of turbulent flow of material, includes bearing plate (1) and support column (11) of fixed connection on bearing plate (1), its characterized in that: the kettle body (3) is fixedly connected to the supporting column (11), the motor frame (21) is fixedly connected to the bearing plate (1), the motor (2) is fixedly connected to the motor frame (21), the output end of the motor (2) is fixedly connected to a rotating shaft (22) which penetrates through the kettle body (3) and extends into the kettle body (3), a disc (23) is fixedly connected to the arc profile of the rotating shaft (22), two supporting rods (24) are fixedly connected to the upper surface of the disc (23), a barrel sleeve (31) is slidably connected to the rotating shaft (22), two sliding grooves (33) are formed in the barrel sleeve (31) and are connected with each supporting rod (24) in a limiting manner through each sliding groove (33), a spring (25) is sleeved on the arc profile of the rotating shaft (22), two ends of the spring (25) are respectively fixedly connected with the lower surface of the barrel sleeve (31) and the upper surface of the disc (23), the upper surface fixed connection of barrel casing (31) has connecting rod (34), coaxial fixedly connected with two agitators (32) that are used for stirring material and liquid on barrel casing (31), be equipped with the control mechanism who is used for accelerating the turbulent flow of material on the cauldron body (3).

2. The reactor mixing mechanism of claim 1, wherein the reactor mixing mechanism is configured to accelerate turbulence of a material: the control mechanism comprises a screw rod (6), a screw hole is formed in the upper surface of the kettle body (3) and is in threaded connection with the screw rod (6) through the screw hole, and a nut (61) is fixedly connected to the upper surface of the screw rod (6).

3. The stirring mechanism of a reaction kettle capable of accelerating turbulent flow of materials as claimed in claim 2, wherein: the control mechanism further comprises a support plate (35) hinged to the top wall of the kettle body (3) through a pin shaft, the upper surface of the support plate (35) is fixedly connected with the lower surface of the screw rod (6), and the lower surface of the support plate (35) is abutted to the connecting rod (34).

4. The reactor mixing mechanism of claim 1, wherein the reactor mixing mechanism is configured to accelerate turbulence of a material: the feed inlet (41) that are used for the feeding are seted up to the upper surface of cauldron body (3), the upper surface of cauldron body (3) articulates through the round pin axle has lid (4).

5. The stirring mechanism of a reaction kettle capable of accelerating turbulent flow of materials as claimed in claim 4, wherein: the lower surface of the cover body (4) is fixedly connected with a sealing ring matched with the feeding hole (41).

6. The reactor mixing mechanism of claim 1, wherein the reactor mixing mechanism is configured to accelerate turbulence of a material: the side of the kettle body (3) is fixedly communicated with a conveying pipe (5) for discharging, and the conveying pipe (5) is fixedly connected with a switch (51) for controlling whether to discharge.

Images