RU89675U1 - PUMP-HEAT-EXCHANGE EQUIPMENT SYSTEM (OPTIONS) - Google Patents

Abstract

1. A compact system of pumping and heat-exchanging equipment, comprising at least one circuit of the heat supply system and consisting of at least one circulation pump, all of which equipment is installed on a portable support-bearing frame from the condition of providing it with full access around the perimeter of the frame, and the circulation pump is located within the above specified frame, characterized in that the collector distributing the coolant is laid on top of the supporting frame. ! 2. The system according to claim 1, characterized in that it further includes auxiliary equipment in the form of at least one of the following elements: heat metering equipment, shut-off and control valves, power supply and control equipment for main and auxiliary equipment. ! 3. The system according to claim 1, characterized in that at least one of the following circuits is used as a heat supply system circuit: a heating system circuit, a ventilation and air conditioning system circuit, a cold supply system circuit, a hot water supply system circuit, a process heat supply system circuit, internal boiler circuit. ! 4. A compact system of pumping and heat-exchange equipment, comprising at least one circuit of the heat supply system and consisting of at least one circulation pump and at least one heat exchanger, while all of its equipment is installed on a portable support-bearing frame from the condition of providing full access along the perimeter of the frame, and the circulation pump is located within the above specified frame, characterized in that the collector,

Description

The claimed variants of the utility model relate to installations intended for use as part of the circuits of heat supply systems, for example: a heating system circuit, a ventilation and air conditioning system circuit, a cold supply system circuit, a hot water system circuit, a process heating system circuit, an internal boiler circuit, etc.

It is well known that boilers or thermal stations have auxiliary equipment in the form of water-water heaters (heat exchangers) and centrifugal (circulation) pumps (see, for example, the meaning of the word “heat point” in the Great Soviet Encyclopedia).

The placement of heat exchangers and circulation pumps in the premises of boiler plants or heating units is associated with the allocation of separate, sometimes significant, areas for each of the types of equipment listed, as well as the need to attach the equipment to the walls of the premises, which does not guarantee full access to it during repair and maintenance . At the same time, there are a number of difficulties that the construction and installation organization has to overcome when installing heat exchange and pumping equipment. So, often the difficulty lies in the correct selection of the required equipment, taking into account the hydraulic characteristics of other systems of the boiler house or heat point, coordination of the type of equipment, organization of its delivery and installation, and this type of work requires significant time and material costs.

The disadvantages listed above are amplified many times if it becomes necessary to organize construction in remote and inaccessible areas, as a rule, which do not have developed infrastructure and / or are not able to provide the proper level of organization of construction and installation works.

Given these shortcomings, block heating units were developed and introduced, the use of which is possible when organizing heating and hot water supply systems for household and household objects from central heating networks. Among these items are block thermal units of the CetePunkt series (see the website http://www.online-teplo.ru/tepl.htm), proposed as the closest analogue.

The well-known block heat points are fully prefabricated units for connecting buildings to the heat network, and their layout includes one or two plate heat exchangers installed on a single frame (depending on the scheme used), a centralized automatic regulation and control system, various types of pumps, shut-off and control valves and filters, instrumentation.

The disadvantages of both the described block heating units and other analogs include the possibility of their use only for connecting buildings to the heating network, the lack of the possibility of their use as part of boiler plants, insufficiently compact placement of the main equipment, which significantly increases the area required for installation of equipment.

Based on the foregoing, the author of the claimed variants of the utility model has set the task of creating options for a system of pumping and heat-exchange equipment devoid of the indicated drawbacks inherent in known block heat points, while the technical result achieved by implementing such options is to increase the compactness of heat supply units, their universality and mobility.

The set result is achieved by means of the first variant of the claimed system of pumping and heat-exchange equipment, which is a compact structure mounted on a supporting-bearing frame and containing at least one of the circuits of the heat supply system (heating system circuit, ventilation and air conditioning system circuit, cold supply system circuit, circuit of a hot water supply system, a circuit of a process heat supply system, an internal boiler circuit, etc.), consisting of at least one circus translational pump. The option also provides for the placement of all equipment on a portable support-bearing frame with an upper collector that distributes the heat carrier of heat supply systems along radially displaced vertical pipelines, from the condition that the circulation pump is placed by the engine inside the frame structure, while providing access to the working bodies of the equipment along the frame perimeter on any serviceable side.

The second of the declared options, unlike the first, is a compact system of pumping and heat-exchange equipment installed on a support-bearing frame and containing, with the possibility of interaction, at least one of the circuits of the heat supply system (heating system circuit, ventilation and air conditioning system circuit, circuit of the cold supply system, circuit of the hot water supply system, circuit of the process heat supply system, internal boiler circuit, etc.), consisting of at least one circulation th pump and one heat exchanger. This option provides for the placement of all equipment on a portable support-bearing frame with an upper collector that distributes the heat carrier of the heat supply systems along radially displaced vertical pipelines, from the condition that the circulation pump is placed by the engine inside the frame structure and directly above the heat exchange equipment located horizontally, while ensuring access to the working bodies of the equipment from any convenient for service side.

Additionally, the described implementation options may contain auxiliary equipment in the form of at least one of the following elements: heat metering equipment, shut-off and control valves, power supply equipment and control of the main and auxiliary equipment.

The functionally claimed variants of the utility model are intended for organizing the required heat exchange between the heat carrier coming from the heat source and the heated liquid of any of the heat supply systems, and are also called upon to ensure the circulation of heating and heated liquids, guaranteeing the heat transfer flow characteristics required during the organization of heat transfer.

The utility model is illustrated by a general view image.

In general terms, the claimed variants of the utility model consist of a set of main and auxiliary equipment.

The structural composition of the elements of the main equipment in general is well known, since it is determined by the general requirements for the composition of any heat supply circuit. These elements include a circulation pump (item 1), a heat exchanger (item 2), and, providing the ability to connect a heat supply source to heating networks, piping. The number of elements and their technical characteristics can be different and are determined both by the initial operating conditions of the installation and the required amount of released heat energy.

As an auxiliary equipment, the claimed utility model can be equipped, if necessary, with means of accounting for the consumption of thermal energy (item 3), shut-off and control valves (item 4), as well as equipment for control systems and power supply, etc.

A distinctive feature of the claimed variants of the utility model from existing installations is their compactness, determined by the location of the main equipment on a single support-bearing frame directly above each other with the placement of pumping equipment within the frame structure. For greater compactness, the distances between the equipment do not exceed the minimum possible necessary to ensure general safety requirements, and the space between the equipment is used only for the location of the piping. It should also be noted that any of the elements of the claimed variants of the utility model has convenient access during their operation (for the purpose of repair, prevention, maintenance, etc.).

In essence, the claimed variants of the utility model are completely ready for connection to a heat supply source on the one hand and external heat supply networks on the other hand, a pumping and heat-exchange equipment system that can be used both as part of a heat station and as part of a boiler plant.

The preparation of the pump-heat-exchange equipment system for operation, in essence, includes only its placement in the boiler room with its subsequent connection to the pipeline systems, as well as control and power supply systems.

The foregoing, with all the obviousness, allows us to conclude that the claimed variants of the utility model are significant advantages, since mobile design combined with the compact placement of technological equipment can significantly reduce the requirements for the size of the areas allocated for boiler rooms or heating units.

Among the advantages of the compact design of the pump-heat-exchange equipment system is the fact that during its operation the presence of service personnel in the spaces between the equipment is impossible, which, in turn, ensures an increase in the level of labor safety. Access to the equipment during operation is carried out from any convenient for service side, which allows for the possibility of repair work and scheduled maintenance work.

In conclusion, it should be noted that the claimed utility model options, if necessary to use them as part of boiler plants and as part of heating units, guarantee a reduction in the cost of organizing and performing construction and installation works, which undoubtedly is their additional advantage.

The claimed system of pump-heat exchange equipment can be used as part of any boiler plant, while ensuring the supply of a coolant with the required parameters to any of the heat supply circuits.

Claims (6)

1. A compact system of pumping and heat-exchanging equipment, comprising at least one circuit of the heat supply system and consisting of at least one circulation pump, all of which equipment is installed on a portable support-bearing frame from the condition of providing it with full access around the perimeter of the frame, and the circulation pump is located within the above specified frame, characterized in that the collector distributing the coolant is laid on top of the supporting frame. 2. The system according to claim 1, characterized in that it further includes auxiliary equipment in the form of at least one of the following elements: heat metering equipment, shut-off and control valves, power supply and control equipment for main and auxiliary equipment. 3. The system according to claim 1, characterized in that at least one of the following circuits is used as a heat supply system circuit: a heating system circuit, a ventilation and air conditioning system circuit, a cold supply system circuit, a hot water supply system circuit, a process heat supply system circuit, internal boiler circuit. 4. A compact system of pumping and heat-exchange equipment, comprising at least one circuit of the heat supply system and consisting of at least one circulation pump and at least one heat exchanger, while all of its equipment is installed on a portable support-bearing frame from the condition of providing full access along the perimeter of the frame, and the circulation pump is located within the above specified frame, characterized in that the collector distributing the coolant is laid on top of the supporting frame, and the compass ion pump is located above the heat exchange equipment disposed horizontally. 5. The system according to claim 4, characterized in that it further includes auxiliary equipment in the form of at least one of the following elements: heat metering equipment, shut-off and control valves, power supply equipment and control of the main and auxiliary equipment. 6. The system according to claim 4, characterized in that at least one of the following circuits is used as a heat supply system circuit: a heating system circuit, a ventilation and air conditioning system circuit, a cold supply system circuit, a hot water system circuit, a process heat supply system circuit, internal boiler circuit.