CN221386125U - Ammonia sugar solution homomixer - Google Patents

Abstract

The utility model discloses an ammonia sugar solution homomixer, which comprises a machine body, a mixing component and an anti-drop component, wherein the anti-drop component comprises a lifting plate, a plurality of bases are uniformly distributed below the lifting plate, a press roller capable of pressing and limiting a bottle body on a roller is rotationally connected to each base.

Description

Ammonia sugar solution homomixer

Technical Field

The utility model relates to an ammonia sugar solution homomixer, and belongs to the technical field of homomixer equipment.

Background

When the ammonia sugar solution is uniformly mixed, a uniform mixer is generally used, the roller uniform mixer is a common uniform mixing instrument, a bottle body filled with the ammonia sugar solution is placed on a roller at present, the bottle body is rotated through rotation of the roller, so that uniform mixing of the ammonia sugar solution in the bottle body is realized, the conventional roller uniform mixer generally slowly rotates when driving the bottle body to rotate, the ammonia sugar solution is insufficiently mixed, the uniform mixing efficiency is low, but if the roller uniform mixer rotates too fast, the bottle body is easy to slip from the roller, and especially for larger bottle bodies, the probability of the bottle body slipping is higher.

Disclosure of utility model

Aiming at the problems in the prior art, the utility model provides the ammonia sugar solution homomixer, which can ensure that a press roller is pressed on a bottle body to prevent the bottle body from slipping off the roller due to too fast rotation of the roller, avoid the occurrence of mixing accidents and greatly improve the mixing efficiency of the ammonia sugar solution.

In order to achieve the above purpose, the present utility model adopts the following technical scheme: an aminosugar solution homomixer comprising:

a tray is arranged above the machine body;

The mixing component is arranged on the tray and comprises two vertical plates which are fixedly connected to the upper surface of the tray, and a plurality of rollers capable of driving the bottle body to rotate are arranged between the two vertical plates;

The anti-drop assembly is arranged above the mixing assembly and comprises a lifting plate, a plurality of bases are evenly distributed below the lifting plate, and each base is rotationally connected with a compression roller capable of pressing and limiting bottle bodies on a rolling shaft.

Preferably, the two ends of the upper surface of the base are fixedly connected with guide rods, the guide rods are slidably connected to the lifting plate, the upper ends of the guide rods penetrate through the lifting plate and are fixedly connected with stop blocks, the stop blocks can prevent the guide rods from separating from the lifting plate, and the guide rods are sleeved with springs for downwards pushing the base.

Preferably, the lifting plate is provided with sliding grooves on the front side wall and the rear side wall, the guide rod slides in the sliding grooves on the same side, the sliding grooves are slidably connected with limiting blocks for propping the side walls of the guide rod, the sliding direction of the limiting blocks is perpendicular to the sliding direction of the guide rod, the middle part of each sliding groove is provided with a support, a first screw rod is rotatably connected to each support, and the threaded ends of the first screws are meshed and connected to the side walls of the limiting blocks.

Preferably, the anti-slip rubber pad is fixedly connected to the inner side wall of the limiting block, and when the limiting block abuts against the side wall of the guide rod, the anti-slip rubber pad is in contact with the side wall of the guide rod, so that the guide rod can be abutted and fixed more stably.

Preferably, the upper surface both sides of tray all fixedly connected with pole setting, open on the both sides lateral wall of lifter plate has the guide hole, and the pole setting is pegged graft in the inside of homonymy guide hole, and the meshing is connected with screw rod two on the lateral wall of lifter plate, and screw rod two's screw thread end extends to the inside of guide hole and moves about and support tightly on the pole setting lateral wall, and screw rod two's quantity is two, and two screw rods two set up respectively in the both sides of lifter plate, and two screw rods two support tightly corresponding pole setting respectively.

Preferably, the inside of any riser is equipped with the belt, and the belt passes through motor drive rotation, and the belt is connected through the tooth and the tip of every roller bearing meshing, and the motor is fixed on the lateral wall of riser, and the belt passes through the back shaft support and rotates in the pole setting, and the output shaft of motor is connected with a back shaft transmission of back belt.

Compared with the prior art, the utility model has the advantages that the lifting plate is driven to slide downwards, the lifting plate can drive the press roller on the base to displace downwards, at the moment, one or more press rollers positioned right above the bottle body can be pressed on the bottle body, when the roller drives the bottle body to rotate, the press roller can rotate along with the bottle body, the press roller pressed on the bottle body can prevent the roller from rotating too fast to enable the bottle body to slip from the roller, the mixing accident is avoided, and when the roller drives the bottle body to rotate fast, the ammonia sugar solution in the bottle body can be mixed fast, and the mixing efficiency is improved.

Drawings

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is a schematic view of the structure of the roller, belt and motor of the present utility model;

FIG. 3 is a schematic view of the present utility model showing a press roll pressing onto a bottle;

FIG. 4 is a second schematic view of the present utility model with the press roller pressed against the bottle;

FIG. 5 is an exploded view of one part of the lifting plate, the limiting block and the screw rod of the utility model.

In the figure: 1. the machine comprises a machine body, 101, a tray, 2, a mixing component, 201, a vertical plate, 202, a roller, 3, an anti-falling component, 301, a lifting plate, 302, a base, 303, a press roller, 304, a guide rod, 305, a spring, 306, a stop block, 4, a chute, 5, a limiting block, 6, a bracket, 7, a first screw rod, 8, a vertical rod, 9, a guide hole, 10, a second screw rod, 11, a belt, 12 and a motor.

Detailed Description

The utility model is illustrated below by means of specific examples, without however limiting the utility model.

As shown in fig. 1 to 5, in the present application, an ammonia sugar solution homomixer is provided, which includes a machine body 1, and a tray 101 is arranged above the machine body 1;

The mixing component 2, the mixing component 2 is arranged on the tray 101, the mixing component 2 comprises two vertical plates 201, the two vertical plates 201 are fixedly connected to the upper surface of the tray 101, a plurality of rollers 202 capable of driving the bottle bodies to rotate are arranged between the two vertical plates 201, as shown in fig. 3, after the bottle bodies are placed on the rollers 202, the bottle bodies are supported between the two adjacent rollers 202, the plurality of rollers 202 synchronously rotate in the same direction, and when the rollers 202 rotate, the rollers 202 can rotate with the bottle bodies so as to realize mixing of the ammonia-sugar solution in the bottle bodies;

The anti-drop assembly 3 is arranged above the mixing assembly 2, the anti-drop assembly comprises a lifting plate 301, a plurality of bases 302 are uniformly distributed below the lifting plate 301, and each base 302 is rotationally connected with a compression roller 303 which can press and limit a bottle body on the roller 202;

As shown in fig. 3, after the bottle is placed on the roller 202, the lifting plate 301 is driven to slide downwards, the lifting plate 301 will displace downwards with the press roller 303 on the base 302, at this time, one or more press rollers 303 directly above the bottle will press the bottle, when the roller 202 drives the bottle to rotate, the press roller 303 can rotate along with the bottle, and the press roller 303 pressing on the bottle can prevent the roller 202 from rotating too fast to slip the bottle from the roller 202, so as to avoid mixing accidents.

As shown in fig. 4 and fig. 5, in order to further prevent the roller 202 from rotating too quickly to make the bottle slide from the roller 202, guide rods 304 are fixedly connected to the two ends of the upper surface of the base 302, the guide rods 304 are slidably connected to the lifting plate 301, the upper ends of the guide rods 304 penetrate through the lifting plate 301 and are fixedly connected with a stop block 306, the stop block 306 can prevent the guide rods 304 from separating from the lifting plate 301, the guide rods 304 are sleeved with springs 305 for downwards pushing the base 302, the springs 305 are arranged between the lifting plate 301 and the base 302, in a natural state, the springs 305 push the base 302 to the lowest position (i.e. the position where the stop block 306 is attached to the lifting plate 301), at this time, each press roller 303 is positioned on the same horizontal plane, when the bottle is pressed, the lifting plate 301 is slid downwards, at this time, when the press roller 303 is in contact with the bottle, the plurality of press rollers 303 above the bottle are pressed on different positions of the bottle, and the press roller 303 on the side walls of the bottle are compressed by different degrees, so that the plurality of press springs 305 are compressed, the press roller 202 on the side walls of the bottle, and the bottle can be further limited by the press roller 202 to slide from the lifting plate 301, and the bottle can be further separated from the bottle 301, and the bottle can be separated from the bottle slide from the roller 301, and the bottle can be further separated from the bottle by pressing the bottle, and the bottle can be evenly pressed from the bottle by the position by the press roller.

As shown in fig. 5, when the pressing roller 303 presses the bottle body, in order to fix the position of the base 302 (the pressing state of the pressing roller 303), both front and rear side walls of the lifting plate 301 are provided with sliding grooves 4, the guide rods 304 slide in the same side sliding groove 4, the sliding grooves 4 are slidably connected with limiting blocks 5 for pushing the side walls of the guide rods 304, the sliding directions of the limiting blocks 5 are perpendicular to the sliding directions of the guide rods 304, a bracket 6 is arranged in the middle of the sliding grooves 4, a first screw rod 7 is rotatably connected to the bracket 6, and the threaded ends of the first screw rod 7 are engaged with and connected to the side walls of the limiting blocks 5;

When the first screw 7 is rotated, the first screw 7 is meshed with the first screw 5, so that the first screw 7 can drive the first screw 5 to slide towards the inside of the chute 4, the inner side edge of the first screw 5 can support the side wall of the guide rod 304, and then support the guide rod 304 on the lifting plate 301, and the position of the opposite base 302 (the pressing roller 303) is fixed, so as to prevent the pressing roller 303 pressing the bottle body from moving upwards, for example: when the bottle body rotates in the arrow direction shown in fig. 4, the bottle body generates a force rolling to the left, and the pressing roller 303 pressed to the left of the bottle body may be jacked up by the excessive force, and the limiting block 5 abuts against the side wall of the guide rod 304, so that the position of the pressing roller 303 can be prevented from changing, and the bottle body can be further prevented from slipping from the roller 202.

In order to increase the stability of the limiting block 5 against the guide rod 304, an anti-slip rubber pad is fixedly connected to the inner side wall of the limiting block 5, and when the limiting block 5 is against the side wall of the guide rod 304, the anti-slip rubber pad is in contact with the side wall of the guide rod 304, so that the guide rod 304 can be more stably abutted against.

As shown in fig. 1 and 5, in order to control the lifting plate 301 to lift up and down and fix the position of the lifting plate 301, two sides of the upper surface of the tray 101 are fixedly connected with the vertical rods 8, two side walls of the lifting plate 301 are provided with guide holes 9, the vertical rods 8 are inserted into the guide holes 9 on the same side, two threaded ends of the two threaded rods 10 extend into the guide holes 9 and movably abut against the side walls of the vertical rods 8, the two threaded rods 10 are respectively arranged on two sides of the lifting plate 301, the two threaded rods 10 abut against the corresponding vertical rods 8, the two threaded rods 10 are loosened, the lifting plate 301 can slide up and down on the vertical rods 8 at the moment, and conversely, after the threaded rods 10 are screwed down, the threaded ends of the two threaded rods 10 abut against the vertical rods 8 at the moment, and the position of the lifting plate 301 is fixed.

As shown in fig. 1 and 2, in order to drive the rollers 202 to rotate, a belt 11 is disposed inside any vertical plate 201, the belt 11 is driven to rotate by a motor 12, the belt 11 is engaged with the end of each roller 202 by teeth, the motor 12 is fixed on the side wall of the vertical plate 201, the belt 11 is supported to rotate in the vertical plate 201 by a supporting shaft, an output shaft of the motor 12 is in transmission connection with a supporting shaft of the supporting belt 11, when the motor 12 is started, the motor 12 can drive each roller 202 to rotate by the belt, in addition, a control module 13 is further disposed on the front side wall of the machine body 1, the control module 13 is electrically connected with the motor 12, so that the control module 13 controls the mixing operation of the glucosamine solution, the control module 13 is a product in the prior art, and the structure and principle of the novel technical features of the utility model are not repeated.

Finally, it should be noted that the above-mentioned embodiments are only for illustrating the technical solution of the present utility model and not for limiting the technical solution of the present utility model, and although the present utility model has been described in detail with reference to the above-mentioned embodiments, it should be understood by those skilled in the art that the present utility model may be modified or equivalently replaced without departing from the spirit and scope of the present utility model, and any modification or partial replacement thereof should be included in the scope of the claims of the present utility model.

Claims (6)

1. An ammonio solution homomixer, comprising:

a machine body (1), wherein a tray (101) is arranged above the machine body (1);

The mixing component (2), the mixing component (2) is arranged on the tray (101), the mixing component (2) comprises two vertical plates (201), the two vertical plates (201) are fixedly connected to the upper surface of the tray (101), and a plurality of rollers (202) capable of driving the bottle body to rotate are arranged between the two vertical plates (201);

The anti-drop assembly (3), anti-drop assembly (3) set up in the top of mixing subassembly (2), anti-drop assembly includes lifter plate (301), the below evenly distributed of lifter plate (301) has a plurality of bases (302), all rotates on every base (302) and is connected with compression roller (303) that can press the definition to the bottle on roller bearing (202).

2. The ammonia sugar solution homomixer according to claim 1, wherein guide rods (304) are fixedly connected to two ends of the upper surface of the base (302), the guide rods (304) are slidably connected to the lifting plate (301), and springs (305) for downwards pushing the base (302) are sleeved on the guide rods (304).

3. The ammonia sugar solution homomixer according to claim 2, wherein sliding grooves (4) are formed in the front side wall and the rear side wall of the lifting plate (301), the guide rods (304) slide in the sliding grooves (4) on the same side, limiting blocks (5) used for pushing the side walls of the guide rods (304) are connected in a sliding mode in the sliding grooves (4), the sliding direction of the limiting blocks (5) is perpendicular to the sliding direction of the guide rods (304), a support (6) is arranged in the middle of the sliding grooves (4), a first screw rod (7) is connected to the support (6) in a rotating mode, and the threaded ends of the first screw rods (7) are connected to the side walls of the limiting blocks (5) in a meshed mode.

4. The ammonia sugar solution homomixer according to claim 3, wherein the inner side wall of the limiting block (5) is fixedly connected with an anti-slip rubber mat.

5. The ammonia sugar solution homomixer according to claim 2, wherein two sides of the upper surface of the tray (101) are fixedly connected with upright rods (8), guide holes (9) are formed in two side walls of the lifting plate (301), the upright rods (8) are inserted into the guide holes (9) on the same side, two threaded rods (10) are connected to the side walls of the lifting plate (301) in a meshed mode, and threaded ends of the two threaded rods (10) extend into the guide holes (9) and movably abut against the side walls of the upright rods (8).

6. The ammonia sugar solution homomixer according to claim 1, wherein a belt (11) is rotatably connected to the inside of any vertical plate (201), the belt (11) is driven to rotate by a motor (12), and the belt (11) is engaged with the end of each roller (202) by teeth.