RU39393U1 - STAPEL FOR MANUFACTURING HEAT EXCHANGE SECTION OF GAS AIR COOLING UNIT - Google Patents

Abstract

The utility model relates to the field of engineering, and more specifically to assembly equipment for fixing large-sized products and can be used for the manufacture of a heat-exchange section of an air cooling apparatus (ABO) of gas. The building berth contains a support frame with intermediate and end support elements for fixing the side walls, entry and exit chambers of the heat-exchange section ABO. On the horizontal platform of each technological support, racks are mounted with coordinate-lighthouse surface sections exposed to the dimension of the outer surface of the wall of the section being manufactured. The end support from each end of the slipway is equipped with an upper coordinate-fixing element, the contact surfaces of which at opposite ends of the slipway are installed with a vertical difference. The technical result provided by the utility model consists in creating a construction of a slipway for manufacturing a heat exchange section of an air-cooled gas cooling apparatus of low material consumption and laboriousness of manufacture, which enables high-precision assembly of the heat transfer section with the exception of violations of the geometric parameters of the relative positioning of all its elements due to the design solutions of the slipway developed in the invention .

Description

The utility model relates to the field of engineering, and more specifically to assembly equipment for fixing large-sized products and can be used for the manufacture of a heat-exchange section of an air cooling apparatus (ABO) of gas.

Known slipway, which is a device included in the assembly tool and designed to install and fix in a given position parts and assemblies for large-sized structures (see Polytechnical Dictionary, - 3rd ed., - M .: Soviet Encyclopedia, 1989, p. .501).

A slipway for assembling volumetric aggregates is known, comprising lower adjustable lodgements, a slipway plate with fixing pins and sliding technological rods with support racks and screw jacks, while before installing into the slipway, sliding rods are installed on the elements of the upper section of the volumetric assembly to be assembled, provided with oriented downwards stop racks on which screw jacks are installed, then docking plates are attached to the mating elements of the lower section of the assembled unit, I install the upper section in the slipway, ensuring the coincidence of the elements of the upper and lower sections and the contact of all the struts, stops with floor beams, fix the upper section on the slip plate, and the combination of the mounting base holes in the mating elements of the upper and lower sections is adjusted by the length of the sliding rods and moving by means of a jack support racks (RU, No. 2123965, B 64 F 5/00, 1998).

The closest analogue is the slipway for assembling and assembling equipment for assembling assemblies (RU, No. 2079421, 64 F 5/00, 1997), including a frame with reference platforms and racks, a rigid tool beam with rows of basic coordinate holes, rigid carriers of aggregate sizes - mounting standards, while rigid media sizes are interconnected, and

snap-in elements are mounted by means of a tool beam with basic coordinate holes, which are defined from the construction axes of the assembled units.

The disadvantage of these analogues, including the closest analogue, is the high material consumption of the structures, the high complexity of manufacturing and installation, associated with the complexity of the design of the known slipways.

The objective of this utility model is to create a slipway for manufacturing a heat-exchange section of an air-cooled gas cooling apparatus, characterized by low material consumption and laboriousness of manufacturing and installation while ensuring high quality assembly on it and reducing the complexity of its manufacturing.

The problem in this utility model is solved due to the fact that the slipway for manufacturing the heat exchange section of the gas air cooling apparatus contains a support frame with intermediate and end technological supports located on it in two rows for fixing the side walls and the inlet and outlet chambers mounted at the ends of the section gas, and each technological support has horizontal supporting platforms and racks mounted on them with at least one coordinate-lighthouse surface area, high not less than one end support from each end of the slipway is provided with an upper coordinate-fixing element, and the contact surfaces of these elements at opposite ends of the slipway are installed with a vertical difference.

In this case, the support frame can be provided with transverse coupling elements, and intermediate technological supports in opposite rows can be placed pairwise coaxially in the junction points of the ends of the coupling elements to the longitudinal elements of the slipway frame.

At least a part of the transverse coupling elements can be configured to adjust the relative position of the coordinate-lighthouse sections of the surface of the uprights of the corresponding pair of intermediate supports, while the intermediate supports of one row can be made stationary, and the corresponding intermediate supports of another row can

be made adjustable movable.

The vertical difference can be from 0.002 to 0.009 the working length of the slipway without taking into account the total length of the specified coordinate-fixing elements.

In addition, each upper coordinate-fixing element can be cantilevered, with a working length of the contact surface corresponding to the width of the gas inlet or outlet chamber of the heat-exchange section being manufactured, and is equipped at the free end with a stopper that fixes the camera in the design position along the length of the heat-exchange section to be manufactured.

In this case, the supports of technological supports can be made with predominantly external stiffeners.

The technical result provided by the utility model consists in creating a construction of a slipway for manufacturing a heat exchange section of an air-cooled gas cooling apparatus of low material consumption and laboriousness of manufacture, which enables high-precision assembly of the heat transfer section with the exception of violations of the geometric parameters of the relative positioning of all its elements due to the design solutions of the slipway developed in the invention .

The essence of the utility model is illustrated by drawings, where

figure 1 - shows a side view of the slipway for the manufacture of heat-exchanging section ABO gas;

figure 2 is a top view of the slipway for the manufacture of a heat-exchange section ABO gas.

The slipway for manufacturing the heat-exchange section of the gas air-cooling apparatus contains a support frame 1 with intermediate 2 and end 3 technological supports located on it in two rows to fix the side walls 4 and the gas inlet 5 and gas outlet 6 chambers mounted at the ends of the section, respectively. Each technological support 2 and 3 has horizontal support pads 7 and racks 8 mounted on them with at least one coordinate-lighthouse surface section 9 exposed to the external surface dimension of the corresponding wall 4 of the section being manufactured. No less than

one end support 3 from each end 10 of the slipway is provided with an upper coordinate-fixing element 11, and the contact surfaces 12 of these elements at opposite ends 10 of the slipway are mounted with a vertical difference.

The support frame 1 is provided with transverse coupling elements 13, and the intermediate technological supports 2 in opposite rows are arranged in pairs coaxially at the junctions of the ends 14 of the coupling elements 13 to the longitudinal elements 15 of the frame 1 of the slipway.

Part of the transverse coupling elements 13 can be made with the possibility of regulating the relative position of the coordinate-lighthouse sections 9 of the surface of the uprights of the corresponding pair of intermediate supports 2, while the intermediate supports 16 of one row are made stationary, and the corresponding intermediate supports 17 of the other row are made adjustable-movable.

The height difference of the contact surfaces 12 of the upper coordinate-fixing elements 11 of the end supports 3 located on the opposite ends 10 of the slipway can be from 0.002 to 0.009 working lengths of the slipway without taking into account the total length of the specified coordinate-fixing elements 11.

Each upper coordinate-fixing element 11 is made cantilevered, with the working length of the contact surface 12 corresponding to the width of the gas inlet or outlet chamber of the heat-exchange section being manufactured, and is equipped at the free end with a stop 18 fixing the chambers 5 or 6 in the design position along the length of the heat-exchange section to be manufactured.

Racks 8 technological supports are made with predominantly external stiffeners 19.

In the process of manufacturing the heat-exchange section of the gas air heater using racks 8 with coordinate-lighthouse sections 9 mounted on the supporting platforms 7 of the technological supports 2 and 3, the input chamber 5 and the exit chamber 6 are fixed and the section dimensions are set. After that, using the upper coordinate-fixing elements 11, a bias is set in the axial direction between the entry and exit cameras in the range from 0.002 to 0.009. Moreover, the specified slope is set using the contact surface 12 of the element 11 and the limiter 18, installed with a vertical difference of

opposite ends 10 of the slipway and chambers 5 and 6 in contact with the upper walls. Then, the chambers are fixed in a predetermined position. After this, the heat exchange tubes of the section are installed in the holes of the tube plate of each of the chambers 5 and 6. This ensures that the pipes are placed in the heat exchange section of the gas air heater with a slope of 0.002 to 0.009 in the axial direction.

Thus, the inventive construction of the slipway provides accurate fixation of the overall dimensions of the heat-exchanging section ABO, as well as the fixation of its individual nodes to facilitate installation and assembly.

Claims (6)

1. A slipway for the manufacture of a heat-exchange section of an air-cooled gas cooling apparatus, characterized in that it comprises a support frame with intermediate and end technological supports arranged in two rows for fixing side walls and gas inlet and outlet chambers mounted at the ends of the section, each technological support has horizontal support platforms and at least part of the technological supports has racks mounted on them with at least one coordinate-lighthouse surface section the tee, which is set to fit the outer surface of the corresponding wall of the section being manufactured, and not less than one end support from each end of the slipway is equipped with an upper coordinate-fixing element, and the contact surfaces of these elements at opposite ends of the slipway are installed with a vertical difference. 2. The slipway according to claim 1, characterized in that the support frame is provided with transverse coupling elements, and the intermediate technological supports in opposite rows are arranged in pairs coaxially at the junctions of the ends of the coupling elements to the longitudinal elements of the slipway frame. 3. The slipway according to claim 2, characterized in that at least a portion of the transverse coupling elements is configured to adjust the relative position of the coordinate-lighthouse sections of the surface of the uprights of the corresponding pair of intermediate supports, while the intermediate supports of one row are made stationary, and the corresponding intermediate supports another row are made adjustable-movable. 4. The slipway according to claim 1, characterized in that the vertical difference is from 0.002 to 0.009 working lengths of the slipway without taking into account the total length of the specified coordinate-fixing elements. 5. The slipway according to claim 1, characterized in that each upper coordinate-fixing element is cantilevered with a working length of the contact surface corresponding to the width of the gas inlet or outlet chamber of the heat-exchange section being manufactured, and is equipped at the free end with a stopper fixing the chamber in the design position according to the length of the heat exchange section being manufactured. 6. The slipway according to claim 1, characterized in that the struts of the technological supports are made with predominantly external stiffeners.