CN220244596U - Servo lifting transmission mechanism - Google Patents

Abstract

The utility model discloses a servo lifting transmission mechanism, which comprises a supporting frame, wherein guide mechanisms are arranged on two inner sides of the supporting frame, the guide mechanisms are connected with hanging fixing plates, a transmission frame is arranged between the hanging fixing plates on two sides, driving rollers are rotatably arranged on two sides of the transmission frame, a transmission belt is arranged between the driving rollers on two sides, one side of the transmission frame is connected with a mounting plate in a locking manner, the mounting plate is provided with a first motor, the power output end of the first motor is connected with a first gear, the first gear is connected with a second gear in a meshed manner, the second gear is connected with one driving roller, the lower side of the hanging fixing plate is provided with a locking plate, one side of the locking plate is provided with a second motor, the second motor is connected with a rotary rod, the two sides of the rotary rod are provided with driving gears, the driving gears are connected with a rack seat in a meshed manner, and the rack seat is fixedly arranged on the supporting frame.

Description

Servo lifting transmission mechanism

Technical Field

The utility model belongs to the technical field of lifting transmission mechanisms, and particularly relates to a servo lifting transmission mechanism.

Background

In the conveying equipment field, ordinary conveying line equipment generally only can pass through horizontal transmission when using, but in other application scenarios, need to use conveying equipment to carry out the condition of lift transmission, thereby need go up and down to transmission device, make the material of carrying on it reach different heights, and then carry the destination of different heights with the material, and adopt one or more cylinder direct jacking transmission device more in prior art, when using a plurality of cylinders to carry out the jacking, be difficult to guarantee the synchronism that the cylinder goes up and down, especially when long distance transmission, be difficult to guarantee transmission device's level, can produce the slope even, take place the accident of conveying target position skew, influence transmission accuracy, therefore need a servo lift transmission mechanism to be used for solving above-mentioned problem.

Disclosure of Invention

In view of the above-mentioned problems with the background art, the present utility model has as its object: aims at providing a servo lifting transmission mechanism.

In order to achieve the technical purpose, the utility model adopts the following technical scheme:

the utility model provides a servo lift transmission mechanism, includes braced frame, braced frame's inside both sides are installed guiding mechanism, guiding mechanism is connected with hangs the fixed plate, both sides install the conveying frame between the hanging the fixed plate, the driving roller is installed to the both sides rotation of conveying frame, both sides install the transmission band between the driving roller, one side locking of conveying frame is connected with the mounting panel, first motor is installed to the mounting panel, the power take off end of first motor is connected with first gear, first gear engagement is connected with the second gear, the second gear with one of them one side the driving roller is connected, the lock plate is installed to the downside of hanging the fixed plate, one of them one side the second motor is installed to the lock plate, the second motor is connected with the rotary rod, drive gear is installed to the both sides of rotary rod, drive gear engagement is connected with the rack seat, rack seat fixed mounting is on braced frame.

Further defined, the guide mechanism includes a guide rail fixedly mounted within the support frame, the guide rail slidably mounted with a guide shoe fixedly mounted on the hanger plate. The structural design ensures that the hanging fixing plate can vertically move up and down.

Further limited, one side of the conveying frame is provided with a U-shaped mounting groove, the driving roller connected with the second gear is mounted in the U-shaped mounting groove, and when bearing seats are connected to two sides of the driving roller, the bearing seats are mounted on the conveying frame in a locking manner. The structural design is convenient for the installation and transmission work of the transmission roller.

Further defined, the second motor is formed by a combination of a servo motor and a speed reducer. Such a structural design improves the transmission effect.

Further defined, a bearing is connected to one side of the rotating rod, and the bearing is fixedly mounted on the lock plate. Such structural design makes rotary rod motion more steady.

The beneficial effects of the utility model are as follows: according to the utility model, the first motor is used for providing transmission power, so that the continuous or intermittent material transmission of the transmission belt can be realized, the second motor is used for driving the transmission gears on two sides to rotate, and the transmission gears are used for driving the hanging fixing plate to drive the transmission frame by virtue of the transmission of the meshed rack seat, so that the transmission frame drives the transmission roller, and the transmission roller drives the transmission belt to ascend or descend along the guide mechanism, thereby ensuring the horizontal and vertical movement of the transmission belt, avoiding the occurrence of accidents of inclination and position deviation, and not affecting the transmission precision, and further improving the use effect.

Drawings

The utility model can be further illustrated by means of non-limiting examples given in the accompanying drawings;

FIG. 1 is a schematic diagram of a servo lifting transmission mechanism according to an embodiment of the present utility model;

FIG. 2 is a schematic cross-sectional view of a supporting frame of a servo lift transmission mechanism according to an embodiment of the present utility model;

the main reference numerals are as follows:

the device comprises a supporting frame 1, a guiding mechanism 2, a hanging fixing plate 3, a conveying frame 4, a driving roller 5, a conveying belt 6, a mounting plate 7, a first motor 8, a first gear 9, a second gear 10, a locking plate 11, a second motor 12, a rotating rod 13, a driving gear 14, a rack seat 15, a guiding rail 16, a guiding seat 17, a U-shaped mounting groove 18, a bearing seat 19 and a bearing 20.

Detailed Description

In order that those skilled in the art will better understand the present utility model, the following technical scheme of the present utility model will be further described with reference to the accompanying drawings and examples.

As shown in fig. 1-2, a guiding mechanism 2 is installed on two sides of the inside of a supporting frame 1, the guiding mechanism 2 is connected with a hanging fixing plate 3, a transmission frame 4 is installed between the hanging fixing plates 3 on two sides, driving rollers 5 are rotatably installed on two sides of the transmission frame 4, a transmission belt 6 is installed between the driving rollers 5 on two sides, a mounting plate 7 is fixedly connected to one side of the transmission frame 4, a first motor 8 is installed on the mounting plate 7, a first gear 9 is connected to the power output end of the first motor 8, a second gear 10 is connected to the first gear 9 in a meshed manner, the second gear 10 is connected with one side of the driving rollers 5, a locking plate 11 is installed on the lower side of the hanging fixing plate 3, a second motor 12 is installed on one side of the locking plate 11, a rotary rod 13 is connected to the second motor 12, a driving gear 14 is installed on two sides of the rotary rod 13, a rack seat 15 is connected in a meshed manner, and the rack seat 15 is fixedly installed on the supporting frame 1.

In this embodiment, when practical, the first motor 8 is started to make the first motor 8 drive the first gear 9 to rotate, the first gear 9 drives the engaged second gear 10, the second gear 10 drives the driving roller 5, the driving roller 5 drives the conveying belt 6 to move, the first motor 8 provides transmission power, so that the conveying belt 6 can continuously or intermittently convey materials, and when the position of the conveying belt 6 needs to be adjusted, the second motor 12 is started to make the second motor 12 drive the rotary rod 13 to rotate, the rotary rod 13 drives the driving gears 14 on two sides, the driving gears 14 move along the engaged rack seat 15, so that the lock plate 11 drives the hanging fixing plate 3, the hanging fixing plate 3 drives the conveying frame 4, the conveying frame 4 drives the driving roller 5, and the driving roller 5 drives the conveying belt 6 to ascend or descend along the guiding mechanism 2.

Preferably, the guiding mechanism 2 comprises a guiding rail 16 fixedly arranged in the supporting frame 1, the guiding rail 16 is slidably provided with a guiding seat 17, and the guiding seat 17 is fixedly arranged on the hanging fixing plate 3. Such a structural design ensures that the suspension fixing plate 3 can perform vertical up-and-down movement. In practice, other structural shapes of the guide mechanism 2 may be considered for use as the case may be.

Preferably, a U-shaped mounting groove 18 is formed in one side of the conveying frame 4, the driving roller 5 connected with the second gear 10 is mounted in the U-shaped mounting groove 18, and when bearing seats 19 are connected to two sides of the driving roller 5, the bearing seats 19 are mounted on the conveying frame 4 in a locking mode. Such a structural design facilitates the mounting and driving work of the driving roller 5. In practice, other mounting configurations of the driving roller 5 may be considered as appropriate.

Preferably, the second motor 12 is formed by a combination of a servo motor and a speed reducer. Such a structural design improves the transmission effect. Indeed, other configurations of the second motor 12 are contemplated as appropriate.

Preferably, a bearing 20 is connected to one side of the rotating lever 13, and the bearing 20 is fixedly installed on the locking plate 11. Such a structural design makes the movement of the rotating lever 13 smoother. In practice, other mounting configurations of the rotary lever 13 are also contemplated as appropriate.

The above embodiments are merely illustrative of the principles of the present utility model and its effectiveness, and are not intended to limit the utility model. Modifications and variations may be made to the above-described embodiments by those skilled in the art without departing from the spirit and scope of the utility model. Accordingly, it is intended that all equivalent modifications and variations of the utility model be covered by the claims of this utility model, which are within the skill of those skilled in the art, can be made without departing from the spirit and scope of the utility model disclosed herein.

Claims (5)

1. A servo lifting transmission mechanism is characterized in that: including braced frame (1), guiding mechanism (2) are installed to the inside both sides of braced frame (1), guiding mechanism (2) are connected with and hang fixed plate (3), both sides hang and install transfer frame (4) between fixed plate (3), transfer frame (4) both sides rotary mounting has driving roller (5), both sides install conveyer belt (6) between driving roller (5), one side locking of transfer frame (4) is connected with mounting panel (7), first motor (8) are installed to mounting panel (7), the power take off end of first motor (8) is connected with first gear (9), first gear (9) meshing is connected with second gear (10), second gear (10) and one of them side driving roller (5) are connected, lock plate (11) are installed to the downside of hanging fixed plate (3), and wherein one side locking plate (11) has second motor (12), second motor (12) are connected with mounting panel (13), the power take off end of first motor (8) is connected with first gear (9), rack (14) are installed in the meshing on rack (15) of rotary rod (13), rack (14) are installed on the fixed carrier (15).

2. A servo lift transmission mechanism as recited in claim 1 wherein: the guide mechanism (2) comprises a guide rail (16) fixedly installed in the supporting frame (1), a guide seat (17) is slidably installed on the guide rail (16), and the guide seat (17) is fixedly installed on the hanging fixing plate (3).

3. A servo lift transmission mechanism as claimed in claim 2 wherein: one side of the conveying frame (4) is provided with a U-shaped mounting groove (18), the driving roller (5) connected with the second gear (10) is mounted in the U-shaped mounting groove (18), and when bearing seats (19) are connected to two sides of the driving roller (5), the bearing seats (19) are mounted on the conveying frame (4) in a locking mode.

4. A servo lift transmission mechanism as claimed in claim 3 wherein: the second motor (12) is formed by a combination of a servo motor and a speed reducer.

5. The servo lift transmission mechanism of claim 4 wherein: one side of the rotary rod (13) is connected with a bearing (20), and the bearing (20) is fixedly arranged on the lock plate (11).