RU209359U1 - Mobile unit for air cooling of the heat carrier in the pipelines of heating networks - Google Patents

Abstract

The utility model relates to thermal power engineering, namely to installations for cooling the coolant in pipelines of heating networks during technological operations and maintenance work on pipelines. The mobile unit for air cooling of the coolant in pipelines of heating networks contains pumping equipment rigidly arranged on a single supporting metal structure, consisting of a circulation pump and a vortex self-priming pump, a dry cooler, pipeline fittings, instrumentation, an expansion tank and a control cabinet. The pumping equipment is connected by pipelines through a system of filters, valves and dampers with a drycooler and an expansion tank. The control cabinet is connected to instrumentation and electric fittings. EFFECT: creation of a mobile unit for air cooling of the coolant in pipelines of heat networks to a predetermined level, which combines all the necessary equipment on a single supporting metal structure, which is made with the possibility of transportation by a cargo vehicle, does not require the connection of additional equipment and installation on site at the work site. 3 ill.

Description

The utility model relates to heat power engineering, namely to the area of centralized heat supply of buildings and structures and the adjacent territory, and in particular to installations for cooling the coolant in pipelines of heat networks during technological operations and maintenance work on pipelines.

From the source RU2683199 C1, F24D 3/08, 03/26/2019, a centralized heat supply system for a building and the adjacent territory is known, including direct and return pipelines of a heat network, which, together with the contours of local heat supply systems, create buildings using a high-temperature coolant and including a hot water supply system circuit with a preheating unit for hot water supplied to the water intake, a system for circulating a network coolant.

When carrying out technological operations and maintenance work on the pipelines of the TS, it often becomes necessary to reduce the temperature of the coolant to a predetermined level, due to a number of factors. In particular, when carrying out work on in-line diagnostics of the technical condition of TS pipelines, it is necessary to reduce the temperature of the coolant to 40 ° C, which is associated with the technical requirements for the operation of in-line diagnostic complexes. Also, a decrease in the temperature of the coolant is required when conducting annual hydraulic tests of pipelines of the TS for strength and density, as well as other routine tests.

So, for example, from RU110167 U1, F22B 37/00, 11/10/2011, a heating network pipeline conservation system is known, in which a part of the pipeline to be preserved is isolated using shutoff valves, through drainage devices and network water is removed. Then compressed dried air at pressure is used to purge a part of the pipeline until water stops flowing through the second drainage unit. This system allows the conservation of the pipeline with the possibility of monitoring corrosion processes in the conserved areas. However, this system does not provide for the cooling of the removed coolant from the pipeline.

Currently, the cooling of pipelines of heating networks is carried out by replacing the coolant in the supply pipeline with the coolant from the return pipeline, with further cooling of the coolant, by circulating through distribution heating networks. This method of cooling down is quite effective and allows you to cool down quite long sections of heating networks in a relatively short period of time.

However, in some cases, cooling of the coolant by the standard method is not possible. At the same time, there is no possibility of installing an air cooler cooling unit at the work site. In this case, they resort to cooling down during natural cooling. The process of natural cooling can take up to 3 days, which will inevitably lead to economic losses and possible dissatisfaction of subscribers.

The technical result achieved by the claimed utility model is to create a mobile unit for air cooling of the coolant in pipelines of heating networks to a predetermined level, which combines all the necessary equipment on a single supporting metal structure, which is made capable of being transported by a truck, does not require the connection of additional equipment and installation on site at the work site.

The claimed technical result is achieved through the use of a mobile unit for air cooling of the coolant in pipelines of heating networks, containing pumping equipment rigidly arranged on a single supporting metal structure, consisting of a circulation pump and a vortex self-priming pump, a dry cooler, pipeline fittings, instrumentation, an expansion tank and a cabinet control, while the pumping equipment is connected by pipelines through a system of filters, valves and dampers with a drycooler and an expansion tank, and the control cabinet is connected to instrumentation and electric fittings and is located in the rear part of the supporting metal structure in a closed niche isolated from the rest of the equipment, with In this case, the connection of the unit to the pipelines of heating networks is carried out using flexible suction and delivery hoses.

The layout of all the necessary equipment of a mobile coolant air-cooling unit on a single supporting metal structure makes it possible to increase the unit’s mobility, due to the ability to transport the unit by trucks and use the heating network right at the work site, without the need to use additional equipment, prepare a site for installation and connect it to power supply networks, and, therefore, reduces the cooling time of the pipeline coolant.

To move the installation using crane equipment, it is equipped with lugs made on the supporting structure.

The supporting metal structure is made in the form of a welded frame made of rolled steel profile. The overall dimensions of the frame are determined from the maximum overall dimensions of the drycooler, as well as based on the maximum overall dimensions of the chassis loading platform.

The equipment used in the unit is arranged on a supporting metal structure in such a way that the plant operator can have free access to pumping equipment, pipeline fittings, instrumentation and control cabinet, both during operation and during routine repair work and service.

The mobility of the installation implies its regular movement from site to site and use in an open area, respectively, the equipment of the installation will be exposed to external mechanical influences, precipitation and vibration loads. The use of a control cabinet protects electrical equipment from external mechanical influences, as well as protects against precipitation, and to reduce the impact of vibration, the supporting structure is equipped with vibration mounts.

The essence of the utility model is illustrated by drawings.

In FIG. 1 shows a mobile air-cooled coolant unit.

In FIG. 2 shows the pumping equipment used in the plant.

In FIG. 3, a general view of the pipeline section of the main heating network of the place and the loading platform of the vehicle with the installation is presented.

The mobile unit (Fig. 1) contains all the necessary equipment for air cooling of the coolant in pipelines of heat networks at the work site, rigidly arranged on a single supporting metal structure (1), namely, pumping equipment (2), consisting of a circulation pump (3) and a vortex self-priming pump (4), drycooler (5), pipeline fittings (6), instrumentation, expansion tank (7) and control cabinet (8). All used mobile installation equipment is in functional and constructive unity.

The pumping equipment (2) is connected by pipelines through a system of filters, valves and dampers with a drycooler (5) and an expansion tank (7).

The pipeline fittings (Fig. 2) contain dampers (9), check valves (10), valves, strainers, a bypass valve (11) and an air release valve (12).

The control cabinet (8) is connected to control and measuring devices and electric fittings and is located in the rear part of the supporting metal structure in a closed niche isolated from the rest of the equipment (see Fig. 1, 3).

Instrumentation (FIG. 2) includes pressure sensors (13), flow sensors (14), flow meter, level sensors (15) and temperature sensors (16). Control and measuring devices provide the ability to control and configure the operation parameters both in manual and automatic modes.

At the same time, the presented figures show only a particular version of the possible location of pipeline valves and instrumentation on the used equipment of the mobile installation, while it is obvious to the specialist that in order to ensure the functioning of the mobile installation, they can be located in various necessary places of the used equipment of the installation.

The operation of the installation is carried out as follows.

To transport a mobile installation, it is loaded onto the cargo platform of a car with a crane and transported to the place of work. A truck drives up to the place of technological operations and maintenance work on the pipelines of the heating network. The main heating networks are divided into sections of optimal length in the range of 0.5-3 km with the help of valves. Gate valves are usually installed at the points of connection of distribution networks to the main ones. In FIG. 3 shows a de-energized section of the pipeline of the main heating network and the installation connected to it. Since all the necessary equipment for air cooling of the coolant is arranged on a single supporting metal structure located on the cargo platform of the vehicle, it does not need to be connected to additional equipment and installed on site at the work site to start the operation of the mobile unit. With the help of flexible pressure-suction hoses (17, 18), the mobile unit is connected to the heating network pipeline - the circulation pump (3) with the supply pipe (19), and the vortex self-priming pump (4) with the return pipe (20). Connecting the unit to pipelines with flexible hoses makes it versatile compared to stationary cooling units. To connect flexible hoses (17, 18) to the pipeline, the pipeline must have connection points, air release valves, drain pipes equipped with shut-off valves (faucets, dampers, valves (22)). In this case, the supply and return pipelines are interconnected by a technological jumper (21).

The circulation pump (3) takes the coolant from the supply pipe (19) of the de-energized section of the heating network and delivers it to the drycooler (5). After leaving the drycooler (5), the cooled coolant enters the return pipe (20) and squeezes the coolant through the technological jumper (21) into the vacant space of the supply pipe (19).

During the replacement process, the coolant is mixed. The circulation of the coolant through the drycooler is repeated until its temperature reaches the required value. The control and settings of the installation operation parameters are carried out by the operator both in manual and automatic modes.

In the process of cooling the coolant, its volume begins to decrease. As the volume decreases, the pressure in the system decreases. The pressure drop in a closed system, if it reaches a negative value, can lead to deformation of the pipeline in its weak points, for example, at the points of connection of flexible hoses, or the collapse of the drycooler tubes. To prevent such emergencies, the installation system provides for topping up the amount of coolant necessary to maintain normal operating pressure from the pipeline section outside the overlap zone or from the pipeline of heat distribution networks (23). The unit is also connected to the feeding pipeline (23) using a flexible hose (24). Topping up occurs automatically as the volume of coolant in the system decreases. If the pressure in the supply pipeline is sufficient to supply it to the system, then, at the signal of the low level sensor (15) installed in the expansion tank (7), the motorized damper opens and the coolant enters the system. If there is no pressure in the feed line (23), or it is not sufficient to replenish the system, after opening the damper (9) with an electric drive, a vortex self-priming pump (4) is connected by a signal from the pressure sensor (13) and the system is replenished. The system replenishment is stopped by a signal from the sensor (13) when the working pressure reaches the normal level.

The power supply of the plant is carried out with the help of diesel generator sets.

Thus, the use of a mobile coolant air-cooling unit makes it possible to combine all the necessary equipment on a single supporting metal structure, which is designed to be transported by a cargo vehicle, does not require the connection of additional equipment and installation on site at the work site, and, therefore, reduces the time pipeline coolant cooling.

Claims (7)

1. A mobile unit for air cooling of a coolant in pipelines of heating networks, containing pumping equipment rigidly arranged on a single supporting metal structure, consisting of a circulation pump and a vortex self-priming pump, a dry cooler, pipeline fittings, instrumentation, an expansion tank and a control cabinet, while pumping the equipment is connected by pipelines through a system of filters, valves and dampers with a dry cooler and an expansion tank, and the control cabinet is connected to control and measuring devices and electric fittings and is located in the rear part of the support metal structure in a niche isolated from the rest of the equipment, while connecting the unit to pipelines heating networks is carried out using flexible suction-pressure hoses. 2. Mobile installation according to claim 1, characterized in that the pipeline fittings contain dampers, check valves, valves, strainers, a bypass valve and an air release valve. 3. Mobile installation according to claim. 1, characterized in that instrumentation includes pressure sensors, flow sensors, flow meter, level sensors and temperature sensors. 4. Mobile installation according to claim 1, characterized in that the supporting metal structure is made in the form of a welded frame made of steel profiled metal. 5. Mobile installation according to claim 1, characterized in that the supporting metal structure is equipped with lugs for the possibility of moving the installation using crane equipment. 6. Mobile installation according to claim 1, characterized in that the supporting metal structure is equipped with vibration mounts. 7. Mobile installation according to claim 1, characterized in that it is made with the possibility of connection with the help of flexible pressure-suction hoses to the feeding pipeline.

Images