Multi-axis synchronous control platform for aluminum profile machining

Abstract

The utility model relates to operation platform technical field discloses a kind of multi-shaft synchronous regulation and control platform for aluminium profile processing, including platform, platform bottom both sides are fixedly installed with side plate, and side plate front side is fixedly installed with signboard, and support rod is installed in middle part in side plate;Rod groove is opened in middle part in side plate, and support rod is inserted in rod groove, and a plurality of groups of shaft grooves of even array are opened in support rod inner side.The utility model is provided with shaft, shaft groove and iron block, when height is adjusted according to processing demand as required, can be opened electromagnet, iron block on both sides is temporarily adsorbed and positioned by electromagnet, two groups of shafts are moved in at this time, and the shaft groove of support rod is dropped, then lift platform, after reaching appropriate height, close electromagnet, and the shaft of tension spring tension is driven to move out and insert into appropriate shaft groove, compared with existing mode, platform height adjusting efficiency can be improved, and it meets the height frequently adjusted use working condition requirement.

Description

Technical Field

[0001] This utility model relates to the field of operating platform technology, specifically a multi-axis synchronous control platform for aluminum profile processing. Background Technology

[0002] The basic concept of a machining workbench: A machining workbench is a type of worktable typically used to place machinery, tools, raw materials, and other items for various processing operations. A machining workbench usually consists of a tabletop, a support frame, and accessories. The tabletop is the main area for placing items, the support frame supports the tabletop and secures accessories, and accessories include various tools, clamps, electrical components, etc., to meet different processing needs. It is commonly found in aluminum profile processing environments.

[0003] In the process of realizing this utility model, the inventors discovered the following unresolved problems in the prior art: the existing multi-axis synchronous control platform for aluminum profile processing requires frequent adjustment of the platform height due to the different tool heights and user heights, and the existing platform height adjustment requires the disassembly and assembly of several sets of threaded structures before it can be used, which is time-consuming and labor-intensive and urgently needs to be improved. Therefore, we propose a multi-axis synchronous control platform for aluminum profile processing. Utility Model Content

[0004] The purpose of this invention is to provide a multi-axis synchronous control platform for aluminum profile processing, which solves the problems mentioned in the background art.

[0005] To achieve the above objectives, this utility model provides the following technical solution: a multi-axis synchronous control platform for aluminum profile processing, comprising a platform, side plates fixedly installed on both sides of the bottom of the platform, and an indicator sign fixedly installed on the front side of the side plate, and a support rod installed in the middle of the side plate;

[0006] The side plate has a rod groove in the middle, and the support rod is inserted into the rod groove. The inner side of the support rod has several sets of evenly arrayed shaft grooves. The two sets of side plates are fixedly connected by a crossbeam.

[0007] The crossbeam has a groove in the middle, and an electromagnet is fixedly installed in the middle of the groove. The crossbeam has shafts that can be moved through both sides near the electromagnet, and the shafts are inserted into the shaft grooves on the same side.

[0008] An iron block is fixedly installed at the end of the shaft, and a tension spring is sleeved on the outside of the shaft, with both ends of the tension spring fixedly connected to the iron block and the crossbeam respectively.

[0009] Pressure sensors are fixedly installed on both sides of the lower surface of the platform, and anti-slip pads a are fixedly installed on the outer side of the platform near the pressure sensors. Reinforcing ribs are fixedly installed at the connection between the side plate and the platform, and the reinforcing ribs are triangular in structure.

[0010] A housing is fixedly installed on the upper surface of the crossbeam. It can be used in conjunction with components such as shafts, shaft grooves, and iron blocks. During the use of the multi-axis synchronous control platform, if it is necessary to adjust the height according to the processing requirements, the electromagnet can be turned on. The electromagnet temporarily attracts and positions the iron blocks on both sides. At this time, the two sets of shafts move inward and disengage from the shaft grooves of the support rods. Then the platform is raised. After reaching the appropriate height, the electromagnet is turned off. The tension of the spring drives the shafts to move outward and insert into the appropriate shaft grooves. Compared with the existing method, the efficiency of platform height adjustment can be improved, which meets the needs of working conditions that require frequent height adjustment.

[0011] As an optional solution to the technical solution of this application, a processor and an alarm are fixedly installed inside the box. The data output terminals of the two sets of pressure sensors are connected to the data input terminals of the processor. The signal output terminals of the processor are connected to the signal input terminals of the electromagnet and the alarm, respectively. The pressure sensors and the alarm can be used together. When adjusting the height, the platform is held with both hands and the pressure sensors are squeezed with the fingers. When the pressure detected by the two sets of sensors is greater than the set threshold, the processor issues a command, the electromagnet is turned on, and the alarm sounds to indicate that the platform can be lifted. After the platform height is adjusted, the fingers are placed away from the anti-slip pad a, and the electromagnet is turned off. This structure can realize automatic control of the electromagnet, and the degree of automation is high. A single person can complete the adjustment.

[0012] As an optional solution to the technical solution of this application, a protective net is fixedly installed at the opening of the box, and wire holes are opened on the side wall of the box and the side of the platform near the sensor. The protective net can block external dust and provide protection against impact from external objects, and the wire holes are used for the passage of wires.

[0013] As an optional solution to the technical solution of this application, a base plate is fixedly installed at the bottom end of the support rod, and an anti-slip pad b is fixedly installed on the lower surface of the base plate. It can be supported by the base plates on both sides and the anti-slip pad b can be used to increase the friction force when in contact with the ground.

[0014] As an optional solution to the technical solution of this application, the upper surface of the platform is provided with several sets of uniformly arrayed threaded grooves, which can be used to fix various tools and meet the processing needs of tool replacement.

[0015] Compared with the prior art, the beneficial effects of this utility model are as follows:

[0016] 1. This utility model discloses a multi-axis synchronous control platform for aluminum profile processing. By configuring shafts, shaft grooves, and iron blocks, during the use of the multi-axis synchronous control platform, when it is necessary to adjust the height according to processing requirements, an electromagnet can be activated. The electromagnet temporarily attracts and positions the iron blocks on both sides, causing the two sets of shafts to move inward and disengage from the shaft grooves of the support rods. The platform is then raised, and after reaching the appropriate height, the electromagnet is deactivated. The tension spring then drives the shafts to move outward and insert into the appropriate shaft grooves. Compared to existing methods, this improves the efficiency of platform height adjustment and meets the needs of applications requiring frequent height adjustments.

[0017] 2. This utility model discloses a multi-axis synchronous control platform for aluminum profile processing. By setting pressure sensors and an alarm, when adjusting the height, both hands hold the platform and squeeze the pressure sensors with their fingers. When the pressure detected by both sets of sensors is greater than the set threshold, the processor issues a command, the electromagnet is activated, and the alarm sounds to indicate that the platform can be lifted. After the platform height is adjusted, the fingers are placed away from the anti-slip pad a, and the electromagnet is deactivated. This structure can realize automatic control of the electromagnet, with a high degree of automation, and a single person can complete the adjustment. Attached Figure Description

[0018] Other features, objects, and advantages of this invention will become more apparent from the following detailed description of non-limiting embodiments with reference to the accompanying drawings:

[0019] Figure 1 This is a schematic diagram of the overall three-dimensional structure of a multi-axis synchronous control platform for aluminum profile processing according to this utility model;

[0020] Figure 2 This is a schematic diagram of the main cross-sectional structure of a multi-axis synchronous control platform for aluminum profile processing according to this utility model;

[0021] Figure 3 This is a schematic diagram of the cross-sectional structure of the box portion of a multi-axis synchronous control platform for aluminum profile processing according to this utility model.

[0022] In the diagram: 1. Platform; 11. Threaded groove; 12. Wire hole; 13. Pressure sensor; 14. Anti-slip pad a; 2. Side plate; 21. Indicator sign; 22. Rod groove; 23. Reinforcing rib; 3. Base plate; 31. Anti-slip pad b; 32. Support rod; 33. Shaft groove; 4. Crossbeam; 41. Iron block; 42. Electromagnet; 43. Tension spring; 44. Shaft; 5. Box body; 51. Processor; 52. Alarm. Detailed Implementation

[0023] To make the technical means, creative features, objectives and effects of this utility model easier to understand, the present utility model will be further described below in conjunction with specific embodiments.

[0024] Please see Figure 1-3This utility model provides a technical solution: a multi-axis synchronous control platform for aluminum profile processing, including a platform 1. The upper surface of the platform 1 has several sets of uniformly arranged threaded grooves 11, which can be used to fix various tools, meeting the needs of tool replacement processing. Side plates 2 are fixedly installed on both sides of the bottom of the platform 1, and an indicator sign 21 is fixedly installed on the front side of the side plate 2. A support rod 32 is installed in the middle of the side plate 2. A rod groove 22 is opened in the middle of the side plate 2, and the support rod 32 is inserted into the rod groove 22. A base plate 3 is fixedly installed at the bottom end of the support rod 32. An anti-slip pad b31 is fixedly installed on the lower surface of the base plate 3, which can be supported by the base plates 3 on both sides and increases the ground friction with the anti-slip pad b31. Several sets of uniformly arranged shaft grooves 33 are opened on the inner side of the support rod 32. Two sets of side plates 2 are fixedly connected by a crossbeam 4. A groove is opened in the middle of the crossbeam 4, and the groove contains… An electromagnet 42 is fixedly installed in the middle. A shaft 44 is movably inserted through both sides of the crossbeam 4 near the electromagnet 42, and the shaft 44 is inserted into the shaft groove 33 on the same side. An iron block 41 is fixedly installed at the end of the shaft 44, and a tension spring 43 is sleeved on the outside of the shaft 44. The two ends of the tension spring 43 are fixedly connected to the iron block 41 and the crossbeam 4 respectively. Pressure sensors 13 are fixedly installed on both sides of the lower surface of the platform 1, and an anti-slip pad a14 is fixedly installed on the outside of the platform 1 near the pressure sensor 13. A reinforcing rib 23 is fixedly installed at the connection between the side plate 2 and the platform 1, and the reinforcing rib 23 has a triangular structure. A box 5 is fixedly installed on the upper surface of the crossbeam 4. A protective net is fixedly installed at the opening of the box 5, and wire holes 12 are opened on the side wall of the box 5 and the side of the platform 1 near the sensor. The protective net can block external dust and provide protection against external impact. The wire holes 12 are used for wires to pass through.

[0025] In this technical solution, components such as shaft rods 44, shaft grooves 33, and iron blocks 41 can be used together. During the use of the multi-axis synchronous control platform, if it is necessary to adjust the height according to the processing requirements, the electromagnet 42 can be turned on. The electromagnet 42 temporarily attracts and positions the iron blocks 41 on both sides. At this time, the two sets of shaft rods 44 move inward and disengage from the shaft grooves 33 of the support rods 32. Then, the platform 1 is raised. After reaching the appropriate height, the electromagnet 42 is turned off. The tension spring 43 pulls the shaft rods 44 outward and inserts them into the appropriate shaft grooves 33. Compared with the existing method, the efficiency of platform height adjustment can be improved, which meets the needs of working conditions that require frequent height adjustment.

[0026] In some technical solutions, a processor 51 and an alarm 52 are fixedly installed inside the housing 5. The data output terminals of the two sets of pressure sensors 13 are connected to the data input terminals of the processor 51, and the signal output terminals of the processor 51 are connected to the signal input terminals of the electromagnet 42 and the alarm 52, respectively.

[0027] In this technical solution, components such as pressure sensor 13 and alarm 52 can be used together. When adjusting the height, both hands hold the platform 1 and squeeze the pressure sensor 13 with their fingers. When the pressure detected by both sensors is greater than the set threshold, the processor 51 issues a command, the electromagnet 42 is turned on, and the alarm 52 sounds to indicate that the person can lift the platform 1. After the platform 1 is adjusted to the height, the fingers are placed away from the anti-slip pad a14, and the electromagnet 42 is turned off. This structure can realize automatic control of the electromagnet 42, and the degree of automation is high, so that a single person can complete the adjustment.

[0028] Working principle: It should be noted that this utility model is a multi-axis synchronous control platform for aluminum profile processing. All components are general standard parts or parts known to those skilled in the art. Their structure and principle can be learned by those skilled in the art through technical manuals or conventional test methods.

[0029] When using a multi-axis synchronous control platform for aluminum profile processing, the multi-axis synchronous control platform is placed at the aluminum profile processing station. Then, according to the process, various aluminum profile processing tools (such as clamps, grinding tools, etc.) can be fixed on the platform 1 through the threaded groove 11, and personnel can perform aluminum profile processing on the platform 1.

[0030] By incorporating shafts 44, shaft grooves 33, and iron blocks 41, the multi-axis synchronous control platform can adjust its height according to processing requirements during operation. This is achieved by activating the electromagnet 42, which temporarily attracts and positions the iron blocks 41 on both sides. At this time, the two sets of shafts 44 move inward and disengage from the shaft grooves 33 of the support rod 32. The platform 1 is then raised to the appropriate height. Afterward, the electromagnet 42 is deactivated, and the tension spring 43 pulls the shafts 44 outward and inserts them into the appropriate shaft grooves 33. Compared to existing methods, this improves the efficiency of platform height adjustment and is suitable for applications requiring frequent adjustments. To meet the demands of high-performance working conditions, a pressure sensor 13 and an alarm 52 are installed. When adjusting the height, both hands hold the platform 1 and press the pressure sensor 13 with the fingers. When the pressure detected by both sensors exceeds the set threshold, the processor 51 issues a command, the electromagnet 42 is activated, and the alarm 52 sounds to indicate that the platform 1 can be lifted. After the platform 1 is adjusted to the desired height, the fingers are placed away from the anti-slip pad a14, and the electromagnet 42 is deactivated. This structure can automatically control the electromagnet 42, and the degree of automation is high, allowing a single person to complete the adjustment.

Claims

1. A multi-axis synchronous control platform for aluminum profile processing, characterized in that: The platform (1) includes a platform (1), on both sides of the bottom of the platform (1) are fixedly installed with side plates (2), and an indicator sign (21) is fixedly installed on the front side of the side plate (2). A support rod (32) is installed in the middle of the side plate (2). The side plate (2) has a rod groove (22) in the middle, and the support rod (32) is inserted into the rod groove (22). The support rod (32) has several sets of uniformly arrayed shaft grooves (33) on its inner side. The two sets of side plates (2) are fixedly connected by a crossbeam (4). The crossbeam (4) has a groove in the middle, and an electromagnet (42) is fixedly installed in the middle of the groove. The crossbeam (4) has a shaft (44) that can be moved through both sides near the electromagnet (42), and the shaft (44) is inserted into the shaft groove (33) on the same side. An iron block (41) is fixedly installed at the end of the shaft (44), and a tension spring (43) is sleeved on the outside of the shaft (44), and the two ends of the tension spring (43) are fixedly connected to the iron block (41) and the crossbeam (4) respectively. Pressure sensors (13) are fixedly installed on both sides of the lower surface of the platform (1), and anti-slip pads a (14) are fixedly installed on the outer side of the platform (1) near the pressure sensors (13). A reinforcing rib (23) is fixedly installed at the connection between the side plate (2) and the platform (1), and the reinforcing rib (23) is a triangular structure. A box (5) is fixedly installed on the upper surface of the crossbeam (4).

2. The multi-axis synchronous control platform for aluminum profile processing according to claim 1, characterized in that: The housing (5) is fixedly installed with a processor (51) and an alarm (52). The data output terminals of the two sets of pressure sensors (13) are connected to the data input terminals of the processor (51). The signal output terminals of the processor (51) are connected to the signal input terminals of the electromagnet (42) and the alarm (52) respectively.

3. The multi-axis synchronous control platform for aluminum profile processing according to claim 1, characterized in that: A protective net is fixedly installed at the opening of the box (5), and wire holes (12) are opened on the side wall of the box (5) and the side of the platform (1) near the sensor.

4. The multi-axis synchronous control platform for aluminum profile processing according to claim 1, characterized in that: The bottom end of the support rod (32) is fixedly installed with a base plate (3), and the lower surface of the base plate (3) is fixedly installed with an anti-slip pad b (31).

5. The multi-axis synchronous control platform for aluminum profile processing according to claim 1, characterized in that: The upper surface of the platform (1) is provided with several sets of uniformly arranged threaded grooves (11).

Images