CN220519320U - Double-speed chain platform - Google Patents

Abstract

The utility model provides a double-speed chain platform, which comprises a double-speed chain line body and a rotating platform, wherein the double-speed chain line body is arranged above the rotating platform; the speed-doubling chain line body comprises at least two speed-doubling chain assemblies which are arranged in parallel, the speed-doubling chain assemblies are connected with speed-doubling chain driving assemblies, the rotary platform comprises a rotary tray and a rotary driving assembly, and the rotary driving assembly is arranged below the rotary tray. The utility model can obtain a stable mechanism through the combination of the compact wire body and the rotary platform, realizes short distance, quick and transportation work at the right angle turning position, reduces unnecessary transportation and turning time, improves the running speed and reduces the cost.

Description

Double-speed chain platform

Technical Field

The utility model relates to the technical field of double-speed chains, in particular to a double-speed chain platform.

Background

The double-speed chain line body is a conveyor which adopts a double-speed chain as a conveying body, and is also called a double-speed chain line. The device is widely applied to the assembly production line of the parts of domestic household appliance production enterprises and the material conveying line.

However, when the whole wire body is laid out, a right angle bending condition exists, and for this purpose, a loop line mode is generally adopted to compensate for the time length in some stations with long automation time, so that a horizontal or vertical circulating system is required to be formed by matching with various special machines such as a jacking translation machine, a jacking transposition machine and the like to realize the wire body bending. The combination of the mechanisms increases the running length, thus increasing unnecessary working time, affecting the running time, and simultaneously, the structure is complex, resulting in increased cost.

Disclosure of Invention

In order to overcome the above-mentioned drawbacks of the prior art, an object of the present utility model is to provide a multiple speed chain platform, so as to effectively solve the above-mentioned problems.

The technical scheme adopted for solving the technical problems is as follows:

the double-speed chain platform comprises a double-speed chain line body and a rotating platform, wherein the double-speed chain line body is arranged above the rotating platform; the speed-doubling chain line body comprises at least two speed-doubling chain assemblies which are arranged in parallel, the speed-doubling chain assemblies are connected with speed-doubling chain driving assemblies, the rotary platform comprises a rotary tray and a rotary driving assembly, and the rotary driving assembly is arranged below the rotary tray.

As a further improvement of the utility model: the double-speed chain assembly comprises a double-speed chain and a chain mounting plate, wherein the double-speed chain is mounted on the chain mounting plate, and the double-speed chain is connected with a double-speed chain driving assembly.

As a further improvement of the utility model: the chain mounting plate comprises a wire body section bar, a wear-resistant strip, a section bar protecting cover and a fixing plate; the top of fixed plate sets up the line body section bar, be provided with the wear-resisting strip in the line body section bar, install doubly fast chain on the wear-resisting strip, the section bar protecting cover sets up on the line body section bar.

As a further improvement of the utility model: the double-speed chain driving assembly comprises a driving rotating shaft, a driven rotating shaft and a driving motor; the two ends of the driving rotating shaft are respectively connected with one end of the double-speed chain, the driving rotating shaft is connected with the driving motor, and the two ends of the driven rotating shaft are respectively connected with the other end of the double-speed chain.

As a further improvement of the utility model: the driving motor is provided with a motor gear, the driving rotating shaft is provided with a rotating gear, and the motor gear is connected with the rotating gear through a transmission belt.

As a further improvement of the utility model: the rotary tray is also provided with two blocking pieces, one blocking piece is arranged on one side of the driving rotating shaft, and the other blocking piece is arranged on one side of the driven rotating shaft.

As a further improvement of the utility model: the rotary driving assembly comprises a rotary motor, a bearing gear and a pinion; the rotating motor is connected with the pinion, the pinion is connected with the bearing gear in a meshed mode, and a rotating tray is arranged above the bearing gear.

As a further improvement of the utility model: the pinion and the bearing gear are surrounded by a bearing shield.

As a further improvement of the utility model: the side surface of the double-speed chain wire body is surrounded by a wire body shield.

As a further improvement of the utility model: the double-speed chain line body further comprises a fixing part, wherein the fixing part comprises a supporting frame and a guide section bar; the guide section bar is connected with the double-speed chain line body through the support frame, and the support frame is in butt joint with the shield.

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

the utility model can obtain a stable mechanism through the combination of the compact wire body and the rotary platform, realizes short distance, quick and transportation work at the right angle turning position, reduces unnecessary transportation and turning time, improves the running speed and reduces the cost.

Drawings

Fig. 1 is a schematic structural view of the present utility model.

Fig. 2 is a side view of the structure of the present utility model.

Fig. 3 is a top view of the structure of the present utility model.

Fig. 4 is a schematic view of the bottom structure of the present utility model.

Fig. 5 is a schematic view of a rotary tray according to the present utility model.

FIG. 6 is a schematic view of A-A structure of the present utility model.

Fig. 7 is a schematic view 1 of a chain mounting plate according to the present utility model.

FIG. 8 is a schematic view of a portion of a chain mounting plate according to the present utility model.

Reference numerals illustrate: 1-double-speed chain line body; 2-rotating a platform; 11-speed chain assembly; a 12-speed chain drive assembly; 21-rotating a tray; 22-a rotary drive assembly; a 111-speed chain; 112-a chain mounting plate; 1121-wire body profile; 1122-wear strips; 1123-a profile cover; 1124-fixed plate; 121-a driving rotating shaft; 122-driven spindle; 123-driving a motor; 124-motor gear; 1211-rotating gears; 125-a drive belt; 3-a wire body shield; a 4-fixing portion; 41-supporting frames; 42-guiding section bar; 5-a barrier; 221-a rotating electric machine; 222-bearing gear; 223-pinion; 224-a bearing shield; 23-platform support.

Detailed Description

The utility model will now be further described with reference to the accompanying drawings and examples:

embodiment one:

the embodiment provides a double-speed chain platform as shown in the accompanying figures 1-2, which comprises a double-speed chain line body 1 and a rotary platform 2, wherein the double-speed chain line body 1 is arranged above the rotary platform 2; the double-speed chain line body 1 comprises at least two double-speed chain assemblies 11 which are arranged in parallel, the double-speed chain assemblies 11 are connected with double-speed chain driving assemblies 12, the rotary platform 2 comprises a rotary tray 21 and a rotary driving assembly 22, and the rotary driving assembly 22 is arranged below the rotary tray 21.

In this embodiment, the double-speed chain line body 1 receives the process board on one assembly line at the turning position of the right-angle transportation line, and then the rotating platform 2 rotates to complete the turning of the process board, and then the process board is transported to the other assembly line. The at least two parallel double-speed chain assemblies 11 are used for receiving and transmitting the process plates, and the process plates are further driven to be received and transmitted through the transmission of the double-speed chains; the double-speed chain driving assembly 12 is used for driving the double-speed chain in the double-speed chain assembly 11 to rotate; the rotary tray 21 is fixedly connected with the double-speed chain line body 1 and is used for rotating the double-speed chain line body 1; the rotation driving assembly 22 is used for driving the rotation tray 21 to rotate.

Through the structure, the problem of high requirements on stability and high consistency in translational conveying is solved, the installation and the debugging are simple, the cross-shaped pipeline transportation is realized, the linear body can be directly connected in the above rotation mode, the translational conveying cost can be effectively reduced, and the direct operation speed and the stability are improved.

Embodiment two:

the embodiment provides a double-speed chain platform as shown in figures 1-8, which comprises a double-speed chain line body 1 and a rotary platform 2, wherein the double-speed chain line body 1 is arranged above the rotary platform 2; the double-speed chain line body 1 comprises at least two double-speed chain assemblies 11 which are arranged in parallel, the double-speed chain assemblies 11 are connected with double-speed chain driving assemblies 12, the rotary platform 2 comprises a rotary tray 21 and a rotary driving assembly 22, and the rotary driving assembly 22 is arranged below the rotary tray 21.

Continuing to describe the structure of the double speed chain assembly 11 in this embodiment in further detail, as shown in fig. 3, the double speed chain assembly 11 includes a double speed chain 111 and a chain mounting plate 112, the double speed chain 111 is mounted on the chain mounting plate 112, and the double speed chain 111 is connected with the double speed chain driving assembly 12. The chain mounting plate 112 is used for mounting the double-speed chain 111, and the double-speed chain 111 is used for driving the process plate to transport.

Further describing the chain mounting plate 112 of this embodiment in further detail, as shown in fig. 7-8, the chain mounting plate 112 includes a wire body profile 1121, a wear strip 1122, a profile cover 1123, and a securing plate 1124; a wire body profile 1121 is disposed above the fixing plate 1124, a wear strip 1122 is disposed in the wire body profile 1121, a double speed chain 111 is mounted on the wear strip 1122, and a profile protecting cover 1123 is disposed on the wire body profile 1121. The wire body profile 1121 is used for installing the wear strip 1122 and the double speed chain 111, the profile cover 1123 is used for protecting the internal material from damage, and the fixing plate 1124 is used for fixing the wire body profile 1121.

Further describing the double speed chain drive assembly 12 in detail in this embodiment, as shown in fig. 1 and 3, the double speed chain drive assembly 12 includes a driving shaft 121, a driven shaft 122, and a driving motor 123; the two ends of the driving rotating shaft 121 are respectively connected with one end of the double-speed chain 111, the driving rotating shaft 121 is connected with the driving motor 123, and the two ends of the driven rotating shaft 122 are respectively connected with the other end of the double-speed chain 111. When in operation, the driving motor 123 drives the driving shaft 121 to rotate, so as to drive the double-speed chain 111 at the two ends connected with the driving shaft 121 to rotate, and drive the process board to transport, while the driven shaft 122 at the other end is used for assisting the double-speed chain 111 to rotate.

In one possibility, as shown in fig. 1, a motor gear 124 is disposed on the driving motor 123, a rotation gear 1211 is disposed on the driving shaft 121, and the motor gear 124 is connected with the rotation gear 1211 through a transmission belt 125. Thus, in operation, the driving motor 123 drives the motor 123 to rotate, and the driving belt 125 drives the rotation gear 1211 to rotate, so as to drive the driving shaft 121 to rotate.

In order to further protect the structure of the double speed chain wire 1, as shown in fig. 1 and 4, a wire body shield 3 is arranged around the side surface of the double speed chain wire 1.

Further, in order to secure the wire body cover outside the double speed chain wire body 1, as shown in fig. 3, the double speed chain wire body 1 further includes a fixing portion 4, and the fixing portion 4 includes a supporting frame 41 and a guiding profile 42; the guide profile 42 is connected with the double-speed chain line body 1 through a support frame 41, and the support frame 41 is abutted with the shield. The wire body cover 3 is fixed outside the double speed chain wire body 1 by the connection structure of the supporting frame 41 and the guide profile 42.

Embodiment III:

the embodiment provides a double-speed chain platform as shown in figures 1-8, which comprises a double-speed chain line body 1 and a rotary platform 2, wherein the double-speed chain line body 1 is arranged above the rotary platform 2; the double-speed chain line body 1 comprises at least two double-speed chain assemblies 11 which are arranged in parallel, the double-speed chain assemblies 11 are connected with double-speed chain driving assemblies 12, the rotary platform 2 comprises a rotary tray 21 and a rotary driving assembly 22, and the rotary driving assembly 22 is arranged below the rotary tray 21.

In this embodiment, in order to clamp the received process plate, as shown in fig. 1 and 5, two blocking members 5 are further disposed on the rotating tray 21, one blocking member 5 is disposed on one side of the driving shaft 121, and the other blocking member 5 is disposed on one side of the driven shaft 122. When the process plate is in operation, the blocking piece 5 on one side of the process plate is lowered, the blocking piece 5 on the other side is lifted, so that the process plate can enter the double-speed chain 111, when the process plate is abutted against the blocking piece 5 on the other side which is lifted, the receiving is completed, at the moment, the blocking piece 5 on the other side which is lowered is lifted again, the clamping work of the process plate is completed, and the inertial problems of sliding displacement and the like caused by inertia in the rotating process of the process plate are avoided.

In this embodiment, the barrier 5 may preferably be a telescopic cylinder barrier.

Embodiment four:

the embodiment provides a double-speed chain platform as shown in fig. 1, which comprises a double-speed chain line body 1 and a rotary platform 2, wherein the double-speed chain line body 1 is arranged above the rotary platform 2; the double-speed chain line body 1 comprises at least two double-speed chain assemblies 11 which are arranged in parallel, the double-speed chain assemblies 11 are connected with double-speed chain driving assemblies 12, the rotary platform 2 comprises a rotary tray 21 and a rotary driving assembly 22, and the rotary driving assembly 22 is arranged below the rotary tray 21.

Continuing with the further detailed description of the rotary drive assembly 22 of the present embodiment, as shown in fig. 5-6, the rotary drive assembly 22 includes a rotary motor 221, a bearing gear 222, and a pinion gear 223; the rotary motor 221 is connected to a pinion gear 223, the pinion gear 223 is engaged with a bearing gear 222, and a rotary tray 21 is provided above the bearing gear 222. The rotation motor 221 drives the pinion 223 to rotate, and in turn drives the bearing gear 222 to rotate, so that the rotation of the upper rotation tray 21 completes the right-angle turning transmission.

Further, in order to protect the bearing assembly, as shown in fig. 6, the pinion 223 and the bearing gear 222 are surrounded by a bearing shield 224.

In this embodiment, the rotary platform 2 further comprises a platform bracket 23, the platform bracket 23 being configured to support and mount the rotary drive assembly 22.

Detailed description of the utility model:

the process plate of the transverse line body enters the double-speed chain line body 1 in a straight-through mode, the driving motor 123 drives the driving rotating shaft 121 to rotate in a chain transmission mode, then the driving rotating shaft 122 drives the double-speed chain 111 to rotate together with the driven rotating shaft 111, the double-speed chain 111 drives the process plate to move, meanwhile, the front cylinder stopper is lifted, and the rear cylinder stopper is lowered. When the front stopper blocks the groove of the process plate, the rear stopper is lifted to clamp, so that the problem of inertia generated by rotation is avoided. When the rotary motor 221 receives an information command, the motor shaft thereof rotates to drive the pinion 223 to rotate with the engaged bearing gear 222, thereby driving the rotary tray 21 fixed to the bearing gear 222 to rotate. When rotated to the commanded position, the front blocker is lowered and the process plate enters the longitudinal wire in a straight-through manner.

The main functions of the utility model are as follows: the device is applied to turning conveying work on various pipelines, and particularly aims at right-angle turning or cross-shaped turning work. In the right angle turning conveying of the process plate, the time only needs to be through time of 1 second and rotation time of 1 second, and the total time is 2 seconds. Compared with a translation conveyor, the process plate is required to stop stably for 1 second, lift for 0.5 second, transfer and receive for 2 seconds, drop for 0.5 second, and save at least 1 time from the point of view of 4 seconds. The cross-shaped line crossing time of the process plate only needs to be through time of 1 second. The principle is the same as above for the translating conveyor, and at least 5 seconds are required for the translating conveyor to complete the traverse. The time saving is shortened by 4 times.

In view of the above, after reading the present document, those skilled in the art should make various other corresponding changes without creative mental effort according to the technical scheme and the technical conception of the present utility model, which are all within the scope of the present utility model.

Claims (10)

1. The double-speed chain platform is characterized by comprising a double-speed chain line body and a rotating platform, wherein the double-speed chain line body is arranged above the rotating platform; the speed-doubling chain line body comprises at least two speed-doubling chain assemblies which are arranged in parallel, the speed-doubling chain assemblies are connected with speed-doubling chain driving assemblies, the rotary platform comprises a rotary tray and a rotary driving assembly, and the rotary driving assembly is arranged below the rotary tray.

2. The speed chain platform of claim 1, wherein the speed chain assembly comprises a speed chain and a chain mounting plate, the chain mounting plate having a speed chain mounted thereon, the speed chain being coupled to a speed chain drive assembly.

3. The speed chain platform of claim 2, wherein the chain mounting plate comprises a wire body profile, a wear strip, a profile cover, and a retaining plate; the top of fixed plate sets up the line body section bar, be provided with the wear-resisting strip in the line body section bar, install doubly fast chain on the wear-resisting strip, the section bar protecting cover sets up on the line body section bar.

4. The multiple speed chain platform of claim 2, wherein the multiple speed chain drive assembly comprises a driving shaft, a driven shaft, and a drive motor; the two ends of the driving rotating shaft are respectively connected with one end of the double-speed chain, the driving rotating shaft is connected with the driving motor, and the two ends of the driven rotating shaft are respectively connected with the other end of the double-speed chain.

5. The speed chain platform as set forth in claim 4, wherein a motor gear is provided on the driving motor, a rotating gear is provided on the driving shaft, and the motor gear is connected with the rotating gear through a transmission belt.

6. The speed chain platform as set forth in claim 4, wherein two blocking members are further provided on the rotary tray, one of the blocking members being provided on one side of the driving shaft and the other blocking member being provided on one side of the driven shaft.

7. The speed chain platform as set forth in claim 1, wherein said rotary drive assembly comprises a rotary motor, a bearing gear and a pinion gear; the rotating motor is connected with the pinion, the pinion is connected with the bearing gear in a meshed mode, and a rotating tray is arranged above the bearing gear.

8. The speed chain platform as set forth in claim 7, wherein the pinion and bearing gear are outboard of and surrounded by a bearing shield.

9. The speed chain platform of claim 1, wherein the side of the speed chain wire is surrounded by a wire shroud.

10. The speed chain platform of claim 9, wherein the speed chain body further comprises a fixed portion comprising a support frame and a guide profile; the guide section bar is connected with the double-speed chain line body through the support frame, and the support frame is in butt joint with the shield.