CN220969721U - Rotary dispensing assembly - Google Patents

Abstract

The utility model discloses a rotary dispensing assembly, relates to the technical field of dispensing, and aims to solve the problem that a dispensing head is difficult to spread glue on the inner peripheral wall of a groove. The utility model is provided with a valve body mounting plate; the bottom surface of the valve body mounting plate is provided with a synchronous wheel motor mounting plate; the rotating module comprises a motor, the motor is arranged on the top surface of the synchronous wheel motor mounting plate, the driving end of the motor penetrates through the synchronous wheel motor mounting plate, and a first rotating wheel is arranged at the driving end of the motor; the side of the valve body mounting plate is provided with a transportation module filled with liquid. When the valve body mounting plate moves to a proper position, the motor is started, and the motor drives the high-voltage connector to rotate through the second rotating wheel and the first rotating wheel; meanwhile, the colloid mixed liquid passing through the static mixing tube flows out from the rubber outlet tube, and the rubber outlet tube sprays colloid on the inner surface of the die under the drive of the high-pressure joint, so that the colloid can be uniformly smeared on the die.

Description

Rotary dispensing assembly

Technical Field

The utility model relates to the technical field of dispensing, in particular to a rotary dispensing assembly.

Background

The glue dispensing machine is also called a glue spreader, a glue dripping machine, a glue beating machine, a glue filling machine and the like, and is specially used for controlling fluid. And an automated machine that drops, coats, or otherwise internally applies the fluid to the surface of the product. The dispensing machine is mainly used for precisely dispensing, injecting, coating and dripping glue, paint and other liquid in the product process to the precise position of each product, and can be used for realizing dotting, line drawing, circular or arc. The dispensing component is a component which is arranged on the dispensing machine and realizes the dispensing function.

The dispensing assembly of the present dispensing machine is used for dispensing through a single pipeline. The glue dispensing mode can make the glue difficult to uniformly spread in the product. Particularly in the technical field of new energy, a cylindrical groove is formed in a die for containing a new energy battery, and the traditional dispensing head is difficult to smear glue on the inner peripheral wall of the groove. In addition, the traditional dispensing mode is that after dispensing of the dispensing head in one groove is finished, the dispensing head needs to be lifted, then moves into the next groove, then moves downwards and performs dispensing, and the process is time-consuming and low in efficiency.

Disclosure of utility model

In order to solve the technical problems, the utility model provides a rotary dispensing assembly

The technical scheme of the utility model is as follows: the rotary dispensing assembly is characterized by comprising a valve body mounting plate which is vertically arranged; the bottom surface of the valve body mounting plate is provided with a synchronous wheel motor mounting plate; rotating the module; the rotating module comprises a motor, the motor is arranged on the top surface of the synchronous wheel motor mounting plate, the driving end of the motor penetrates through the synchronous wheel motor mounting plate, and a first rotating wheel is arranged at the driving end of the motor; and a connector; the side surface of the valve body mounting plate is provided with a transportation module filled with liquid, the liquid outlet end of the transportation module penetrates out of the synchronous wheel motor mounting plate, and the connector is rotationally connected with the liquid outlet end; a second rotating wheel is arranged on the peripheral wall of the connector; the second rotating wheel is connected with the first rotating wheel through a synchronous belt; and a glue outlet module; the glue outlet module is arranged at the bottom end of the connector and rotates along with the rotation of the second rotating wheel; and the outer wall of the glue outlet module is provided with a glue outlet pipe which is radially outwards along the glue outlet module.

Further, the glue outlet module further comprises a high-pressure connector, and the high-pressure connector is connected to the bottom end of the connector.

Further, the transport module includes a metering module including a fixed unit including a slide plate locked on the valve body mounting plate by a locking handle.

Further, the metering module further comprises a metering unit, wherein the metering unit comprises a containing piece, and the containing piece is connected with a plurality of feeding pipes.

Further, the transport module further comprises a static mixing pipe, wherein the upper end of the static mixing pipe is connected with the accommodating part, and the lower end of the static mixing pipe is connected with the connector.

Further, the number of the feeding pipes is two, and the feeding pipes are distributed on the top surface of the accommodating part in an array mode.

Further, a tensioning wheel is arranged on the top surface of the synchronous wheel motor mounting plate.

The beneficial technical effects of the utility model are as follows:

When the valve body mounting plate is positioned at a proper position, the motor is started, and the motor drives the high-voltage connector to rotate through the second rotating wheel and the first rotating wheel; simultaneously, the colloid mixed liquid through the static mixing tube flows out from the rubber outlet tube, the rubber outlet tube sprays colloid on the inner surface of the die under the drive of the high-pressure joint, and the high-pressure joint enables the colloid to be uniformly smeared on the die in the rotating process.

Drawings

FIG. 1 is a perspective view of a rotary dispensing assembly of the present utility model;

FIG. 2 is a second perspective view of the rotary dispensing assembly of the present utility model;

Fig. 3 is a partial enlarged view at a in fig. 2.

100, A valve body mounting plate; 200. a synchronous wheel motor mounting plate; 300. a transport module; 310. a connector; 320. a metering module; 330. a static mixing tube; 321. a fixing unit; 322. a metering unit; 323. a slide plate; 324. a locking handle; 325. a receiving member; 326. a feeding tube; 400. rotating the module; 410. a second rotating wheel; 420. a motor; 430. a first rotating wheel; 440. a synchronous belt; 500. a glue outlet module; 510. a rubber outlet pipe; 520. a high pressure junction; 600. and a tension wheel.

Detailed Description

In order that the manner in which the above recited features of the present utility model are attained and can be understood in detail, a more particular description of the utility model, briefly summarized below, may be had by reference to the appended drawings and examples, which are illustrated in their embodiments, but are not intended to limit the scope of the utility model.

The rotary dispensing assembly according to this embodiment, as shown in fig. 1, includes a valve body mounting plate 100 disposed vertically, where the valve body mounting plate 100 may be mounted on a sliding rail or a mechanical arm, or other mechanical structure capable of moving the valve body mounting plate 100. The bottom surface of the valve body mounting plate 100 is provided with a synchronous wheel motor mounting plate 200, and an L-shaped space is formed between the synchronous wheel motor mounting plate and the valve body mounting plate 100.

As shown in fig. 2, the present utility model is provided with a rotation module 400; the rotation module 400 includes a motor 420, the motor 420 is mounted on the top surface of the synchronous wheel motor mounting board 200, and the driving end of the motor 420 passes through the synchronous wheel motor mounting board 200, and a first rotation wheel 430 is mounted on the driving end of the motor 420, and the first rotation wheel 430 is a synchronous wheel.

As shown in fig. 1 and 2, the valve body mounting plate 100 is mounted with a liquid-filled transport module 300 at a side thereof, and colloid or other auxiliary additive is filled into the transport module 300 to be transported, and is continuously stirred to be uniform in the transport module 300, and is finally filled into a mold in which new energy batteries are placed. The liquid outlet end of the transport module 300 is penetrated out of the synchronous wheel motor mounting plate 200, and the connector 310 is rotatably connected with the liquid outlet end. The second rotating wheel 410 is disposed on the outer peripheral wall of the connector 310, and the second rotating wheel 410 is also a synchronizing wheel. The second rotating wheel 410 is connected with the first rotating wheel 430 through the synchronous belt 440, that is, after the motor 420 is turned on, the motor 420 drives the second gear to rotate, and the rotation of the second gear drives the first gear to rotate through the synchronous belt 440. The top surface of the synchronous wheel motor mounting plate 200 is provided with a tension wheel 600, and the tension wheel 600 is used for tensioning the synchronous belt 440, so that the synchronous belt 440 is more stable in the running process.

As shown in fig. 2, the transport module 300 includes a metering module 320, the metering module 320 includes a fixing unit 321, and the fixing unit 321 includes a sliding plate 323, and the sliding plate 323 can slide up and down on a sidewall of the valve body mounting plate 100 during the mounting process. The slide plate 323 is locked to the valve body mounting plate 100 by a locking handle 324. After the slide plate 323 is moved to the proper position, the slide plate 323 is secured to the valve body mounting plate 100 by screwing the locking handle 324. The metering module 320 further includes a metering unit 322, the metering unit 322 including a receiving member 325, the receiving member 325 being connected to a plurality of feeding tubes 326. The transport module 300 further includes a static mixing tube 330, an upper end of the static mixing tube 330 being connected to the receiving part 325 and a lower end thereof being connected to the connection head 310, and the gel within the receiving part 325 flowing into the static mixing tube 330. One end of the connection head 310 is embedded in the static mixing tube 330 and it communicates with the static mixing tube 330 so that the gel can pass through the connection head 310. The connector 310 is divided into a hollow circular tube and a hexagonal part on the circumferential wall of the circular tube, the circular tube part is fixed with the static mixing tube 330, and the hexagonal part can rotate relative to the circular tube. The number of the feeding pipes 326 is two and the array is distributed on the top surface of the receiving member 325, wherein the main liquid is added in one feeding pipe 326 and the curing agent or other additives are added in the other feeding pipe 326. Within static mixing tube 330 may be present a main liquid and a curing agent, which may be replaced with other additives. The liquid in the static mixing tube 330 is continuously stirred by the screw rod, and the stirred colloid continuously flows downwards until the colloid is positioned in the groove in the die. In actual production, static mixing tube 330 may be replaced with other work pieces that perform the same function.

As shown in fig. 2 and 3, the glue module 500 is disposed at the bottom end of the connecting head 310 and rotates with the rotation of the second rotating wheel 410; the outer wall of the glue outlet module 500 is provided with a glue outlet pipe 510, the glue outlet pipe 510 is radially outwards along the glue outlet module 500, and the glue outlet pipe 510 is made of alloy materials. The battery mould can be placed on the platform, and the platform is located the rotation point and glues the subassembly below. The glue flowing out of the glue outlet pipe 510 is adhered to the inner wall of the mold for placing the new energy battery, and then the glue outlet pipe 510 is continuously rotated in the glue outlet process until the glue coating work is completed. The glue coating mode can enable the glue to be uniformly coated on the inner wall of the battery mould. In order to save the gluing time and improve the working efficiency, after one of the grooves in the mold is coated with the glue, the motor 420 drives the first rotating wheel 430 and the second rotating wheel 410 to rotate, so that the rotating glue dispensing assembly can translate into the next groove to carry out the gluing work, and the waste of the working time caused by the up-and-down movement of the glue outlet pipe 510 is avoided. The glue outlet module 500 further comprises a high-pressure connector 520, wherein the high-pressure connector 520 is integrally cylindrical and can be replaced with different sizes according to actual production requirements. The high pressure connector 520 is connected to the bottom end of the connector 310. The high-pressure connector 520 is communicated with the connector 310, so that the colloid in the connector 310 is sprayed out by a pressurizing mode.

The above description is only of the preferred embodiments of the present utility model and is not intended to limit the present utility model, and it should be noted that it is possible for those skilled in the art to make several improvements and modifications without departing from the technical principle of the present utility model, and these improvements and modifications should also be regarded as the protection scope of the present utility model.

Claims (7)

1. A rotary dispensing assembly is characterized by comprising,

A valve body mounting plate (100) placed vertically; a synchronous wheel motor mounting plate (200) is arranged on the bottom surface of the valve body mounting plate (100);

a rotation module (400); the rotating module (400) comprises a motor (420), the motor (420) is arranged on the top surface of the synchronous wheel motor mounting plate (200) and the driving end of the motor (420) penetrates through the synchronous wheel motor mounting plate (200), and a first rotating wheel (430) is arranged at the driving end of the motor (420);

And a connector (310); a transportation module (300) filled with liquid is arranged on the side surface of the valve body mounting plate (100), a liquid outlet end of the transportation module (300) penetrates through the synchronous wheel motor mounting plate (200) and a connector (310) is rotationally connected with the liquid outlet end; a second rotating wheel (410) is arranged on the peripheral wall of the connector (310); the second rotating wheel (410) is connected with the first rotating wheel (430) through a synchronous belt (440);

And a glue outlet module (500); the glue outlet module (500) is arranged at the bottom end of the connector (310) and rotates along with the rotation of the second rotating wheel (410); an outlet rubber tube (510) is arranged on the outer wall of the outlet rubber module (500), and the outlet rubber tube (510) is radially outwards arranged along the outlet rubber module (500).

2. The rotary dispensing assembly of claim 1, wherein the dispensing module (500) further comprises a high pressure connector (520), the high pressure connector (520) being connected to the bottom end of the connector (310).

3. The rotary dispensing assembly of claim 1, wherein the transport module (300) includes a metering module (320), the metering module (320) includes a stationary unit (321), the stationary unit (321) includes a slide plate (323), and the slide plate (323) is locked to the valve body mounting plate (100) by a locking handle (324).

4. A rotary dispensing assembly according to claim 3, wherein the metering module (320) further comprises a metering unit (322), the metering unit (322) comprising a receiving member (325), the receiving member (325) being connected with a plurality of feeding tubes (326).

5. The rotary dispensing assembly of claim 4, wherein the transport module (300) further comprises a static mixing tube (330), the static mixing tube (330) having an upper end connected to the receiving member (325) and a lower end connected to the connector (310).

6. The rotary dispensing assembly of claim 4, wherein the number of the feeding tubes (326) is two and the array is distributed on the top surface of the receiving member (325).

7. The rotary dispensing assembly of claim 1, wherein a tensioner (600) is provided on a top surface of the synchronous wheel motor mounting plate (200).