RU10245U1 - GAS ROOF BOILER ROOM - Google Patents

Abstract

A gas roof boiler house containing a boiler block and a heating unit, each of which is mounted in a container module consisting of a frame, base, side and end walls and a roof, a system of water supply and distribution pipelines with connecting fittings, including a boiler supply and return pipe water supply and return pipelines of consumers of heating, ventilation, air conditioning, supply and return piping of hot water supply and cold water pipeline, characterized in that it is abzhena vibration damping inserts located on the lower base of the module containers, and at least one side wall of each module container is removable, with the possibility of installation in place of removal of the vibration damping insert, while the findings of the connecting fittings of the supply and return piping of boiler water between the boiler unit and the heat point is directed to the side removable wall, and the conclusions of the falling and return pipelines of consumers of heating, ventilation, air conditioning, hot water and a pipe cold water wires are mounted in a common installation opening made at the base of the heating unit.

Description

GAS ROOF BOILER ROOM

The utility model relates to the field of autonomous heat supply sources, and more specifically to gas boiler houses with hot water boilers. It can be used in the construction and reconstruction of boiler houses for heat supply of industrial and agricultural enterprises, residential and public buildings.

There are known roof boiler rooms designed for heat supply using a closed heat supply and hot water supply scheme, consisting of one container in which all the necessary equipment is located: a boiler, an automation unit, water supply and distribution pipelines (see, for example, the magazine “Ventilation, heating, air conditioning No. 2 , the publication “ABOK PRESS for 1998, p. 49) I.

The disadvantage of this boiler room is its limited ability to increase thermal capacity.

Roof gas boiler rooms are also known, containing a boiler unit and a heating unit located in modules of containers consisting of a frame, a lower base, side and

end walls, water supply and distribution pipelines with connecting fittings and butt assemblies, including the supply and return piping of boiler water, the supply and return pipelines of consumers of heating, ventilation, air conditioning (HVAC), hot water supply (DHW) and cold water pipelines (HV) (see, for example, the magazine “Ventilation, heating, air conditioning No. 4 for 1997,“ ABOK PRESS, p. 19) 2.

The design of the above boiler room 2 allows you to increase its thermal capacity by combining several modular containers. However, the disadvantage of this design 2 is the difficulty of assembling them on the roof of the building where the gas boiler room is located. In addition, the installation is complicated due to the need to carry out preliminary anti-vibration measures to prevent the spread of vibration from operating units to the building structure.

The task to which the proposed utility model is aimed is to increase the ease of installation and increase the safety of the gas boiler house located on the roof of the building by reducing the time needed to assemble the boiler house and eliminating the transmission of vibrations arising from the operation of units on the building structure. This is a technical result from the use of the proposed technical solution.

The specified technical result is achieved by supplying a gas rooftop boiler house containing a boiler unit and a heating unit located in the container modules,

consisting of a frame, lower base and end walls, water supply and distribution pipelines with connecting fittings of the docking stations, including supply and return pipelines of boiler water, supply and return pipelines of consumers of heating, ventilation and air conditioning (HVAC) hot water supply (DHW) and pipeline cold water (HV), vibration damping inserts located on the lower base of the module containers, and at least one side wall is removable, with the possibility of installation in the place of the vibration-damping plug connector, while the connecting fittings of the docking nodes between the boiler blocks and the heating point of the supply and return boiler water pipelines are located coaxially and directed to the side removable walls, and the conclusions of the supply and return pipelines of the HVAC, DHW and HV pipelines are made in general mounting opening of the lower base of the heating unit.

It is known in the art to use vibration damping inserts to prevent transmission of vibration from operating units to the foundations of a building. In the proposed utility model, vibration damping inserts are installed on the lower base and in places of the removable wall of the modular container, thereby preventing transmission of vibration to the building through the floor and walls. This, together with other distinguishing features, namely the implementation of one side or side and end walls with removable and special arrangement and orientation of the connecting fittings of the docking nodes, allows to achieve the above technical result.

The utility model is illustrated by drawings, where:

In FIG. I shows a plan view of a gas boiler house;

in FIG. 2 shows an end view of a gas boiler;

in FIG. 3 same side view

in FIG. 4 shows the placement of shock absorbing inserts on

bottom base of a modular container; in FIG. 5 - option for installing a shock absorbing insert in

connector location; in FIG. 6 shows an installation option for shock absorbing

inserts on the lower base of the container; in FIG. 7 shows a mounting option for a removable wall

container module;

in FIG. Figure 8 shows a fragment of a heating unit with an installation opening for connecting the supply and return pipelines of the HVAC, DHW and HV.

The gas roof boiler includes a heating point I and a boiler block 2 located in the container modules 3 and 4. Each container module includes a metal frame 5, a lower base 6, side walls 7, end walls 8 and a roof 9. Supply system and distribution water and gas pipelines in heating point I and boiler block 2 contains a supply 10 and a return II boiler water pipelines, a supply 12 and a return 13 pipelines of consumers of heating, ventilation, air conditioning (HVAC), a supply 14 and a return 15 pipelines of hot water abzheniya (GVS), the pipeline 16 cold water (HV) and the inlet gas pipeline 17.

Vibration damping inserts 18 are installed on the lower base 6. Container modules 3 and 4 have at least one

removable wall 19. It can be either side 7 or end 8, and when docking more than two containers, both can be combined.

The removable wall 19 is attached to the frame 5 with screws 20. In places of the connector on the frame 5, holes 21 are provided for installing and securing the vibration damping inserts 22 with a bolt and nut 24.

The connecting pipes 25 of the docking nodes between the boiler unit 2 and the heat point I, supply 10 and return II piping boiler water made coaxially and directed to the side removable walls 19.

In the lower base 6 of the container module 3 of thermal point I, an installation opening 26 was made, to which the conclusions of the supply and return 13 pipelines of the HVAC consumers, pipelines 14 and 15 of the hot water supply, and 16 HV pipeline were drawn. The outer walls of the module containers 3 and 4 are equipped with decorative screens 27.

The gas roof boiler room, assembled in the form of separate module containers 3 and 4 with the heat point I and the boiler unit 2 located in them, is delivered to the installation site. On the roof, the module containers 3 and 4 are placed in such a way that the removable walls 19 are located against each other. Then, the self-tapping screws 20 are unscrewed and the removable walls 19 are removed, freeing access to the connecting pipes 25 and the connecting nodes of the container modules 3 and 4. In places where the holes 21 are made, vibration damping inserts 22 are installed and, using bolts 23 and nuts 24, a coupler is made container modules 3 and 4. After that, the pipelines 10 and II are connected using the connecting pipes 25. Through the mounting opening 26

connects to communications the conclusions of the 12 supply and 13 return pipelines of the HVAC consumers, the 14 supply and 15 return pipelines of the hot water supply and the 16 HV pipeline.

After connecting to the supply gas pipeline 17, checking and debugging all the systems, the boiler room is ready for operation. During operation, vibration damping inserts 18 and 22 prevent the transmission of vibrations from operating units to the roof of the building where the gas boiler room is located.

Using the proposed utility model improves the ease of installation and safety during operation of gas roof boiler rooms.

Claims (1)

A gas roof boiler house containing a boiler block and a heating unit, each of which is mounted in a container module consisting of a frame, base, side and end walls and a roof, a water supply and distribution system with connecting fittings, including a boiler supply and return pipe water supply and return pipelines of consumers of heating, ventilation, air conditioning, supply and return piping of hot water supply and cold water pipeline, characterized in that it is abzhena vibration damping inserts located on the lower base of the module containers, and at least one side wall of each module container is removable, with the possibility of installation in place of removal of the vibration damping insert, while the findings of the connecting fittings of the supply and return piping of boiler water between the boiler unit and the heat point is directed to the side removable wall, and the conclusions of the falling and return pipelines of consumers of heating, ventilation, air conditioning, hot water and a pipe cold water wires are mounted in a common installation opening made at the base of the heating unit.