RU5128U1 - THERMAL CUTTING PLANT - Google Patents

Abstract

Installation for thermal cutting, comprising racks with mechanisms for orienting the workpiece relative to the vertical and horizontal axes, installed between the racks of the beam with guides, copiers and carriages with cutters, an air and water supply system for the cutters, characterized in that the copiers are made in the form of working and rectilinear sections connecting the first among themselves and having a profile similar to the profile of the working sections, and sensors for the relative position of the cutters and the workpiece, racks with orientation mechanisms and beams are rigidly connected by a single metal structure, and the installation is additionally equipped with two box-shaped ducts interconnected, located below the base prisms of the orientation mechanisms and along the beams with guides, symmetrically to the longitudinal axis of the installation, and having rectangular openings in the upper part forms with suction nozzles, and at the junction of the ducts are equipped with a rotary vane device, while the air supply system Water and the torches are equipped with glandless valves with one-way electromagnetic control.

Description

THERMAL CUTTING PLANT

The utility model relates to the field of assembly and welding productions of machine-building enterprises and can be used for mechanized thermal cutting of holes in large box-shaped products.

A known installation for plasma-arc cutting open holes in box-shaped products, made according to project 9964227, AO UralNITI, Yekaterinburg / holding racks mounted on the foundation, with orientation mechanisms of the workpiece relative to the vertical and horizontal axes, beams located between them with guides, copiers and carriages with plasmatrons, as well as a system for supplying water and air to the plasma torches.

Known installation has the following disadvantages:

1.When cutting holes in the product (sequentially on both sides of the product), moving along the guides of the carriages with plasmatrons using the copier method, engaging and uncoupling the copy rollers with the copier profile is done manually, which does not allow automating the process of cutting successively all holes located on one of the sides of the product , as well as during uncoupling and engagement of the copy rollers with copiers, the copiers wear on the initial and final sections, since the material from which the copiers are made has a significant lower hardness than the material from which the rollers Die sinking. The wear of the copiers leads to a deterioration in the quality of the cut holes and there is a need to restore the worn areas, which is very time-consuming.

MPK6 at 23 to 10/00

2. Aerosols emitted during plasma-arc cutting in the form of fine dust and toxic gases, due to the lack of a local exhaust ventilation system in the installation design, enter the production room. At the same time, the concentration of aerosols at the workplace of the installation operator and nearby workplaces can significantly exceed the maximum permissible standards, which poses a danger to the health of workers.

3. The placement of racks with basic prisms of the orienting mechanisms of the workpiece and beams with guides, copiers and carriages with plasmatrons on the jellied foundation leads to additional costs during installation of the installation and reduces the accuracy of cutting holes during operation due to the absence of rigid connections between the racks and beams with carriage guides and copiers.

4. The absence of a stepwise supply of plasma-forming air to the plasma torches, which leads to a deterioration in the ignition conditions of the auxiliary arc, the instability of its occurrence and transition to the cutting one, since for the stability of ignition of the auxiliary arc using an oscillator, it is necessary that the air flow is lower than the flow rate required for the cutting arc . The instability of the appearance of the auxiliary arc also makes it difficult to automate the process of sequential cutting of holes.

5. Significant expenditures of time for controlling the air and water supply system to the plasma torches, since they are supplied using manual valves located at a considerable distance from the plasma torches.

The purpose of creating a utility model is to increase productivity, as well as quality, accuracy of cut holes and improve sanitary and hygienic working conditions by automating the cutting process and equipping the installation with a local exhaust ventilation system.

In the proposed utility model, this goal is achieved by the fact that the copiers mounted on the beams on both sides of the installation are solid in the form of working and rectilinear sections connecting the first to each other and having a profile similar to the profile of working sections, and on carriages and beams are additionally installed sensors of relative position of torches and workpiece.

The specified version of the copiers ensures the movement of the carriages with cutters between the cut open holes of the open form without manual engagement (uncoupling) of the copy rollers with the copiers and eliminates the associated wear at the beginning and end of the working sections, and, therefore, the quality of the cut holes increases and there is no need to restore worn separate plots of copiers. The presence of continuous copiers and sensors of the relative position of the cutters and the workpiece allows you to automate the process of sequential cutting holes located on each side of the workpiece.

Racks with orientation mechanisms and beams located between them are placed on a single metal structure (for example, a plate), which provides a rigid connection between them, and therefore, the location and size of the cut holes are constant.

The installation is additionally equipped with a local exhaust ventilation system made in the form of two box-shaped ducts located below the base prisms of the orientation mechanisms and along the beams with guides, symmetrically to the longitudinal axis of the installation and having rectangular openings with suction nozzles in the upper part. The end surfaces of the nozzles are located under the holes available in the lower part of the workpiece in close proximity to it. Through the holes and nozzles, aerosols generated during the cutting process are removed, which ensures high sanitary and hygienic working conditions at the operator’s workplace and nearby workplaces. In place

air ducts are equipped with a rotary gate device, which can significantly increase the efficiency exhaust ventilation systems by controlling the flow of contaminated air removed from the cutting zone.

The system of water and air supply to the torches is equipped with valveless valves with electromagnetic control, which allows you to control the supply of water and air to the torches remotely or in automatic mode, providing a step-by-step air supply to the torches with the flow rates necessary for stable burning of the auxiliary arc and, after transition her to the cutting, required for a cutting arc. This provides the possibility of automating the cutting process and eliminates unproductive time spent on controlling the feed system using manual valves.

Figure 1 shows the proposed installation, side view. Thin lines show the workpiece with holes cut out in it;

figure 2 is a top view of the installation, the product is conditionally not shown; in Fig. 3 - section aa in Fig. 1, one of the carriages with a cutter is conventionally not shown. Arrows indicate the direction of flow of contaminated air removed from the cutting zone;

figure 4 shows the engagement of the copy rollers with copiers; figure 5 shows a schematic pneumohydraulic diagram of the system for supplying water and air to the torches.

The installation contains a single base 1 - Fig. 1 (for example, a cast plate) on which racks 2 are mounted with orientation mechanisms of the workpiece, consisting of base prisms 3 and centering devices 4. In prisms 3, the workpiece is installed through mandrels 5 and 5 6. Between the posts 2, on both sides of the installation, on the base 1, longitudinal beams 7 are mounted on which the guides 8 and copiers 9 are mounted, made solid in the form of working and straight sections.

connecting the first among themselves, and having a profile similar to the profile of the work sites. The shape of the working sections of the copiers corresponds to the shape of the cut holes. On the guides 8, on both sides of the installation, there are self-propelled carriages 10 with a DC motor 11 (Fig. 3), which rotates the drive copy rollers 12 through a differential worm gear (not highlighted in the drawing), and cutters 13. On the carriages 10 and guides 8 are located sensors 14 (for example, proximity, made in the form of capacitive limit switches and flags) the relative position of the torches 13 with the workpiece before and during cutting. Below the base prisms 3, along the beams 7 symmetrically to the longitudinal axis of the installation, air ducts 15 are located having in the upper part of the opening with suction nozzles 16. A rotary vane device 17 is installed at the junction of the air ducts 15 (Fig. 2) to control the flow of contaminated air removed from the cutting zone. Through valve 18 (FIG. 5) and glandless valves with electromagnetic control 19, cooling water is supplied to the cutters 13. Plasma-forming air is supplied to the cutters 13 through the valve 20, glandless valves with electromagnetic control 21, 22, valves 23, 24 and rotameters 25, used to control air flow. Valves 24 are designed to control the air flow required for the auxiliary arc, and valves 23 for the cutting. Manometers 26 and 27 control the pressure supplied to the torches 13 of water and air, and pressure switches 28 - the presence of water discharge from the torches 13.

The operation of the installation is carried out in a spedial manner.

The movement of the carriages 10 with cutters 13 along the guides 8 is carried out due to mechanical interaction between the spring-loaded copy rollers 12 and the copiers 9 by rolling around the latter after turning on the DC motor 11, which rotates the drive copy rollers 12 through a differential-worm gearbox. Carriages 10s

cutters 13 are diverted to extreme positions in which their metal construction will not impede the installation of the workpiece.

Mandrels 5 and 6 are inserted into the openings on both sides of the front and rear parts of the product. By means of a lifting mechanism (for example, a bridge crane), through the mandrels 5 and 6, the product is installed in the base prisms 3 located on the racks 2 of the installation. Thus, the product is oriented relative to the vertical axis. Then, using the centering devices 4 (for example, devices in the form of folding screw jacks) placed on the posts 2, the product is moved along its transverse axis to the desired position. At the same time, the amount of movement is controlled by vernier pointers placed on the centering devices 4. Thus, the product is guided by the installation relative to the horizontal axis.

Holes are cut sequentially from one and the other side of the product. The fan motor of the local exhaust ventilation system is turned on. Turning on the DC motor 11, the carriage 10, together with the cutter 13, begins to move along the guide 8 along the straight section of the copier 9 to the first (relative to the cutting sequence - rightmost) hole. When the location of the first hole is reached, the carriage 10 stops automatically upon a command from the sensor 14 corresponding to the first hole. Cutter 13 is brought to the workpiece at the required distance. Also, on a command from the sensor 14 corresponding to the first hole, cooling water is supplied to the cutter by turning on the glandless valve 19 and air, by turning on the glandless valve 21 through valve 25 and with 24. The auxiliary arc is ignited and, after its contact with the surface of the cut product, a cutting arc appears . After the occurrence of the cutting arc, the non-apical valve 22 is automatically turned on and the air flow increases to the level required for burning the cutting arc.

With a certain time delay (necessary for cutting the metal through the entire thickness and for the plasma arc power source to reach the operating mode), the motor 11 of the carriage 10 is also automatically turned on and the first hole is cut. After cutting the first hole, the cutting arc goes out, the glandless valves 21, 22 are turned off, the air supply to the cutter 13 is stopped and the carriage 10 with the cutter 13 moves along the straight section of the copier 9 to the location of the next hole, where it stops at the command of the sensor 14 corresponding to the second hole . In the same sequence, the remaining holes located on this side of the product are cut.

After completing the sequential cutting of all holes located on this side of the product, the glandless valve 19 stops the water supply to the cutter 13 mounted on the carriage 10 on this side of the product. The operator moves to the other side of the installation and the entire cycle of cutting holes located on the other side of the product is repeated.

The rotary gate device 17 is installed in the position in which the contaminated air is sucked out from the cutting zone through the duct 15 located on the side of the installation where the holes are cut.

After completion of cutting all the openings of the carriage 10 with cutters 13 are retracted to their original, initial positions. The product is fixed on the installation due to the removal of the centering devices 4 from it to the inoperative position.

The product is removed from the installation by a bridge fan and transported for further processing.

The proposed installation provides an increase

labor productivity, improving the quality and accuracy of cut holes by automating the cutting process and reducing unproductive time spent on restoring worn out

individual sections of copiers and to supply water and air to the cutters, as well as improving sanitary and hygienic working conditions by effectively removing aerosols from the cutting zone from the cutting zone.

Claims (1)

Installation for thermal cutting, comprising racks with mechanisms for orienting the workpiece relative to the vertical and horizontal axes, installed between the racks of the beam with guides, copiers and carriages with cutters, an air and water supply system for the cutters, characterized in that the copiers are made in the form of working and rectilinear sections connecting the first among themselves and having a profile similar to the profile of the working sections, and sensors for the relative position of the cutters and the workpiece, racks with orientation mechanisms and beams are rigidly connected by a single metal structure, and the installation is additionally equipped with two box-shaped ducts interconnected, located below the base prisms of the orientation mechanisms and along the beams with guides, symmetrically to the longitudinal axis of the installation, and having rectangular openings in the upper part forms with suction nozzles, and at the junction of the ducts are equipped with a rotary vane device, while the air supply system Water and the torches are equipped with glandless valves with one-way electromagnetic control.