RU2364798C2 - Heat supply and/or hot water supply system of complex consumer and heat supply and/or hot water supply system of building, facility - Google Patents

Abstract

FIELD: heating systems.

SUBSTANCE: group of inventions refers to heat supply engineering, and namely to heat supply and/or hot water supply systems of the building, facility, as well as complex heat energy consumer in the form of buildings, facilities combined into architectural and construction groups, microdistricts, quarters, villages and towns. Heat supply and/or hot water supply system of complex heat energy consumer, including local consumers in the form of separate buildings or facilities combined e.g. into architectural and construction groups, microdistricts, quarters, villages and towns, consists of distribution network of pipelines connected via heat carrier to heat supply source e.g. boiler house, thermal power station, combined heat-and-power plant, boiler room or the main heat line and to local heat energy consumers, shutoff and/or shutoff and control valves with a locking element, pump equipment that includes at least one pump namely with electric drive, as well as at least one hydromechanical smooth load device of hydraulic system, which is connected to the pipeline namely on the delivery side in the section between the pump or pump group creating the head in the pipeline and the nearest shutoff and/or shutoff and control valves. That device is connected to the pipeline as to the working medium, and mainly as to heat carrier and installed with the possibility of automatic prolonged activation and deactivation of shutoff and/or shutoff and control valves. At that, hydromechanical device includes an inlet branch pipe and mechanical-hydraulic drive which are connected to each other in-series. Inlet branch pipe includes a housing, speed control of opening shutoff and/or shutoff and control valves and load transfer to hydraulic system, which is equipped with non-return valve and spraying nozzle. Mechanical-hydraulic drive includes power chamber with the housing containing at least one section with the changing working volume controlled with liquid working medium filled back thereto at pressure increase in the pipeline, and transfer mechanism. At that, mechanical-hydraulic drive is double connected to the pipeline: at the inlet it is connected with inlet branch pipe to the pipeline as to working medium, and at the outlet it is kinematically connected with mechanical-hydraulic drive to the locking element of the above valve; at that, transfer mechanism is movable and connected to the power chamber as "piston-stock" or "membrane-stock"; at that, the stock in its turn is connected in a movable manner thus forming the drive with the locking element of the above valves with the possibility of automatic movements of the locking element in the range from fully closed to fully opened position per the pipeline passage and vice versa. Heat supply and/or hot water supply system of the building, facility is described as well.

EFFECT: providing smooth increase of load on the hydraulic water supply system, providing smooth start-up of hydraulic system excluding the possibility of high hydrodynamic loads on the system, as well as decreasing material consumption of the start-up device elements, increasing the system safety and reliability as a whole, and reducing repair and operating costs.

25 cl, 13 dwg

Description

The group of inventions relates to heat supply, and in particular to heat supply systems and / or hot water supply of a building, structure, as well as a complex consumer of thermal energy in the form of buildings, structures, combined into architectural and construction groups, residential districts, neighborhoods, towns, cities.

The prior art system is known for water heating and hot water supply, which solves the problem of protecting the pipelines of heating networks and the devices and equipment installed in them from destruction and the formation of steam plugs and pillows by installing a sealed container connected by means of a reducer to a source of compressed air in order to preventing the pressure drop in the system when the pump stops (see, for example, SU 321659 A, publ. 11/19/1971).

The claimed group of inventions aims to solve the same problem, that is, to prevent unwanted water hammer in the hydraulic heat supply system, causing premature wear of the pipeline, and therefore, the cost of maintenance of the hydraulic system, by providing a smooth increase in the load on the hydraulic system and the working pump with a smooth increase fluid pressure in the system from zero to the complete absence of pressure and fluid flow in the system to the working one, i.e. the task the present invention is directed to is to ensure a smooth start-up of the hydraulic system with the exception of the possibility of large hydrodynamic loads on the hydraulic system (water hammer), as well as reducing the material consumption of the elements of the starting device, increasing the safety and reliability of the system as a whole, reducing the cost of repairing it and operation.

The task in terms of the heat supply system and / or hot water supply of a complex consumer of thermal energy, including local consumers in the form of separate buildings or structures, united, for example, in architectural and construction groups, microdistrict, neighborhoods, towns, cities, is solved due to the fact that it according to the invention is a hydraulic system comprising a distribution network of pipelines in fluid communication with a heat source, such as a boiler room, a thermal electric a plant, a heating electric center, a boiler or main heating main and with local consumers of thermal energy, shut-off and / or shut-off and control valves with a locking element, pumping equipment, including at least one pump, mainly with an electric drive, as well as at least at least one hydromechanical device for smooth loading of the hydraulic system connected to the pipeline, mainly from the pressure side in the area between the pump or pump group that creates the pressure in the pipeline and the closest shut-off and / or shut-off and control valves connected with the pipeline through the working fluid, mainly through the coolant and mounted with the possibility of automatically prolonged on and off shut-off and / or shut-off and control valves, while the hydromechanical device includes an inlet pipe connected in series having a casing regulator for the speed of opening the shut-off and / or shut-off and control valves and transferring the load to the hydraulic system equipped with a return m valve and nozzle, and a hydromechanical actuator, including a power chamber with a housing containing at least one compartment with a variable displacement, adjustable refillable liquid working fluid with increasing pressure in the pipeline, and a transmission mechanism, while connecting to the hydromechanical pipeline the device is made double: at the inlet - with the inlet pipe it is communicated with the pipeline through the working fluid, and at the exit - with a kinematically hydromechanical drive with a locking element of the mentioned valves moreover, the transmission mechanism is made movable, connected to the power chamber of the type "piston-rod" or "membrane-rod", the rod, in turn, is movably connected with the formation of the actuator with a locking element of the said valve with the possibility of automatic movement of the locking element in the range from full overlap to a fully open pipeline and vice versa.

One of the local consumers of thermal energy in the complex consumer may include an industrial enterprise, for example, a metallurgical plant, an engineering plant, shipyards, an oil refinery, a gas enterprise, a food factory, a bakery, a winery, a meat factory, a dairy, and a creamery.

The system may include one public or commercial complex, or an educational institution, or at least one automobile manufacturing plant and / or transport, trucking enterprise.

The aforementioned non-return valve and nozzle can be placed in the body of the opening speed controller of the above-mentioned valves, and the nozzle and non-return valve can be structurally combined.

The check valve of the opening speed controller of said valve may comprise a rod having a passage with outlet openings with a damper made at one end and a nozzle at the other end, including a regulating, preferably screw, element inserted into the check valve stem passage with the possibility of at least of a partial overlap of the passage section of the passage channel - the passage hole for its calibration using the nozzle of the nozzle, which can be equipped with a screw element, by changing it Assumption relatively passageway.

The speed controller for the opening of said reinforcement can be equipped with a return device mounted on the screw element of the nozzle and made, for example, in the form of a spring.

The body of the speed controller for opening the shut-off and / or shut-off and control valves may contain at least three compartments, a check valve with an inlet of the passage channel made in it can be located in the first compartment, and at least at least one can be located in the second compartment partially, the check valve stem and at least one outlet passage of the passage channel, made in the rod, in the third compartment can be located a screw element of the nozzle and the return device of the speed controller is open Ia, the second compartment may be connected by working fluid to the power chamber and the opening in the housing of the speed controller in the third compartment can be an aperture closed by a screw plug for adjusting the flow cross section of the passageway through the screw member.

To change the position of the nozzle needle relative to the passage opening, the nozzle can be equipped with a calibration device that can be manually adjusted from the outside of the body of the speed controller for opening the shut-off or shut-off and control valves.

The hydromechanical device may be provided with a hydromechanical actuator return device connected to the transmission mechanism and / or the actuator membrane and made, for example, in the form of a spring, and the opening valve of the mentioned valves can be equipped with a return device connected to the non-return valve and / or nozzle and made , for example, in the form of a spring.

The power chamber may be provided with a sealed elastic membrane dividing the power chamber body into said compartment with a variable working volume filled with a working fluid and a compartment which is not filled by it, and the membrane may be made with the possibility of alternating deformation directed depending on pressure towards the filled compartment, so and towards the non-fillable compartment of the power chamber, and in the non-fillable compartment of the power chamber can be made a hole with a guide sleeve fixed in it, providing vayuschey forward movement gear.

Shut-off and / or shut-off and control valves can be made with a locking body having a spindle, and the transmission mechanism can consist of at least two elements, while the first element - the transmission mechanism rod through the safety pad can be connected to the membrane of the power chamber, and the second element can be connected to the locking body of the shut-off and control valves, preferably through a spindle with the possibility of rotary movement of the latter.

The first and second elements of the transmission mechanism can be made rectilinear and interconnected movably, for example, articulated, moreover, in the second element at the junction of it with the first, a hole can be made, inside which there is a pin connecting both of these elements, the second element of the transmission mechanism be made with the possibility of rotation from 0 to 90 degrees from the initial position, while 0 degrees corresponds, for example, to a completely closed armature, and a value of 90 degrees corresponds to a completely open ytoy.

The power chamber may be provided with a piston dividing the power chamber housing into said compartment with a variable working volume filled with a working fluid and a compartment that is not filled with it and configured to move depending on pressure both towards the filled compartment and towards the unfilled compartment of the power chamber, in the non-fillable compartment of the power chamber, an opening can be made with a guide sleeve fixed in it, which provides translational movement of the transmission mechanism.

Shut-off and / or shut-off and control valves may be a valve, for example, a ball valve.

The transmission mechanism interacting with the shut-off and / or shut-off and control valves can be made in the form of a lever or a crank mechanism, or a gear rack.

The maximum throughput of the non-return valve of the speed controller for opening the aforementioned valves may be at least two times higher than the maximum throughput of the nozzle.

The problem in part of the heat supply system and / or hot water supply of a building, structure, is solved due to the fact that it is a hydraulic system, including connected to the distribution network or to the boiler, at least one inlet pipe with a liquid coolant, preferably hot water , a pipeline in fluid communication with a system of pipes for internal wiring, equipped with at least one heating device, mainly a radiator or radiator-convection battery type, shut-off and control valves with a locking element, as well as at least one hydromechanical device for smooth loading of the hydraulic system, connected to the pipeline, mainly from the pressure side in the area in front of the shut-off and / or shut-off and control valves, in communication with the pipeline on the working fluid, mainly on water, and mounted with the possibility of automatically prolonged on and off shut-off and / or shut-off and control valves, while the hydromechanical the triad includes an inlet consecutively connected to each other, having a body that controls the speed of opening the shut-off and / or shut-off and control valves and transferring the load to the hydraulic system, equipped with a check valve and nozzle, and a hydromechanical drive, including a power chamber with a housing containing at least , one compartment with a variable displacement, adjustable refillable liquid working fluid with increasing pressure in the pipeline, and a transmission mechanism, while connecting to the water supply of the hydromechanical device is double: at the inlet - the inlet pipe is communicated with the pipeline through the working fluid, and at the exit - with a kinematically hydromechanical drive with a locking element of the mentioned fittings, and the transmission mechanism is movable, connected to the power chamber as a membrane-rod type, wherein the rod, in turn, is movably connected with the formation of a drive with a locking element of the said valve with the possibility of automatic movements of the locking element in the range from full erekrytiya to fully open at the pipe duct and vice versa.

The aforementioned non-return valve and nozzle made structurally combined and a non-return device may be placed in the body of the speed controller for opening the valve mentioned above, and the non-return valve may include a rod with a passage with outlet openings with a shutter made on one end and a nozzle on the other including a regulating, preferably screw, element inserted into the passage channel of the check valve stem with the possibility of at least partially blocking the passage section through launch channel - a through hole for its calibration with the nozzle of the nozzle, which can be equipped with a screw element by changing its position relative to the through channel, and the return device can be mounted on the screw element of the nozzle and made, for example, in the form of a spring.

The body of the speed controller for opening the shut-off and / or shut-off and control valves may contain at least three compartments, a check valve with an inlet of the passage channel made in it can be located in the first compartment, and at least at least one can be located in the second compartment partially, the check valve stem and at least one outlet passage of the passage channel, made in the rod, in the third compartment can be located a screw element of the nozzle and the return device of the speed controller is open Ia, the second compartment may be connected by working fluid to the power chamber and the opening in the housing of the speed controller in the third compartment can be an aperture closed by a screw plug for adjusting the flow cross section of the passageway through the screw member.

To change the position of the nozzle needle relative to the passage opening, the nozzle can be equipped with a calibration device that can be manually adjusted from the outside of the body of the speed controller for opening the shut-off or shut-off and control valves.

The power chamber of the hydromechanical actuator can be equipped with a sealed elastic membrane that separates the power chamber housing into said compartment with a variable working volume and a compartment that is not filled with it, and the membrane can be made with the possibility of alternating deformation, directed depending on the pressure towards the filled compartment , and towards the non-fillable compartment of the power chamber, and in the non-fillable compartment of the power chamber a hole can be made with fixed on it control sleeve, providing translational movement of the gear mechanism.

Shut-off and / or shut-off and control valves can be made with a locking body having a spindle, and the transmission mechanism can consist of at least two elements, while the first element - the transmission mechanism rod can be connected through a safety pad to the membrane of the power chamber, and the second element can be connected to the locking body of the shut-off and control valves, preferably through a spindle with the possibility of rotary movement of the latter, while the hydromechanical device could s hydromechanical device is provided with a return actuator associated with the gear mechanism and / or membrane actuator and is made, for example, a spring.

The first and second elements of the transmission mechanism can be made rectilinear and interconnected movably, for example, articulated, moreover, in the second element at the junction of it with the first, a hole can be made, inside which there is a pin connecting both of these elements, the second element of the transmission mechanism be made with the ability to rotate from 0 to 90 degrees from the starting position, while 0 degrees will correspond, for example, to fully closed fittings, and a value of 90 degrees will be fully Tew open.

Shut-off and / or shut-off and control valves can be a crane, for example a ball valve, and the transmission mechanism interacting with it can be made in the form of a lever or a crank mechanism, or a gear rack.

The maximum throughput of the non-return valve of the speed controller for opening the aforementioned valves may be at least two times higher than the maximum throughput of the nozzle.

The technical result achieved by using the claimed group of inventions is to ensure safety and reduce energy consumption during operation of heat supply systems and / or hot water supply, as well as increase durability and reliability, reduce repair and maintenance costs due to reduced load on hydraulic system elements - shutoff valves , pipelines and to the pump electric motor, which is achieved by the combination of essential features developed in the invention that create aggregate a positive effect that exceeds the sum of the input effects from individual elements of the invention, namely, the location of the proposed device communicated with the pipeline through the working fluid or the working medium of the proposed device between the pump and the shut-off and control valves allows the pump to be turned on and a set of revolutions close to working with closed valves, which reduces energy consumption when starting the pump motor, and the sequence of location and the proposed design solutions of the controller sk grow opening and the hydromechanical actuator valves provide on the one hand, the attainable smoothness automatically opening the valve and including a hydraulic system and, on the other hand, provide a quick release of pressure in the apparatus and system shutdown when the engine is turned off. The latter is achieved due to the adjustable ratio of the intake nozzle and hydromechanical device check valve for smooth loading of the hydraulic system proposed in the invention, as well as due to the implementation of an elastic-flexible separating membrane installed in a rigid membrane chamber, which ensures smooth movement of the hydromechanical drive transmission mechanism in valve opening mode and faster, but also smoother closing, reinforced by the operation in reverse mode of course at the expense of additional power amplifier spring travel. This together creates the necessary smoothness and adjustable speed of the device, as well as cost-effectiveness, the possibility of both autonomous and joint work with other devices in the hydraulic heating system and / or hot water supply.

Technical solutions are illustrated by drawings, which show a particular case of the implementation of heat supply systems and / or hot water supply of a building, structure, as well as a complex consumer, not covering and, moreover, not limiting the entire scope of the claims of this decision.

Figure 1 shows the hydromechanical device included in the heat supply and / or hot water supply systems of a building, structure, as well as a complex consumer with a power chamber equipped with a membrane connected to the pipeline (working fluid or working medium is not shown);

figure 2 shows the hydromechanical device included in the heat supply and / or hot water supply systems of a building, structure, as well as a complex consumer with a power chamber equipped with a piston connected to the pipeline (working fluid or working medium is not shown);

figure 3 presents the speed controller of the hydromechanical device for opening shut-off and control valves with a screwed-off plug;

figure 4 shows the power chamber of the hydromechanical device;

figure 5 is given a hydromechanical device at the beginning of the process of opening valves - the pump motor in the phase of exit from idle to operating revolutions;

figure 6 shows a hydromechanical device with a fully open shut-off and control valves - the engine in the phase of operation at full power;

Fig.7 shows a hydromechanical device after the end of the pressure - when the engine is off;

on Fig - the same hydromechanical device in an embodiment with an intermediate (additional) working fluid;

figure 9 is the same hydromechanical device in an embodiment with several intermediate (additional) working bodies;

figure 10 is an embodiment of a hydromechanical device with a transmission mechanism in the form of gear racks and wheels;

11 shows a closed hydraulic system for heat supply and / or hot water supply of a building with a hydromechanical device and a swirl heat generator;

on Fig given a schematic diagram of a hydraulic hot water system with a hydromechanical device;

on Fig presents graphs of the dependences of the current strength and pressure of the working engine on the flow rate of the working medium or working fluid.

The heat supply and / or hot water supply system of a complex consumer of thermal energy is a hydraulic system 1, which includes a distribution network (not shown conventionally in the drawings) of pipelines communicated via a heat carrier with a heat supply source and with local consumers of thermal energy. A heat supply source can be, for example, a boiler room, thermal power station, thermal power station, boiler or main heating main. Local consumers are individual buildings or structures, united, for example, in architectural and construction groups, microdistrict, neighborhoods, village, city.

The heat supply and / or hot water supply system of a building, structure, is a hydraulic system 1, which includes connected to the distribution network or to the boiler, at least one inlet of the pipeline with a liquid coolant, preferably hot water, a pipe in communication with the pipe system through the coolant internal wiring equipped with at least one heating device. A radiator or a radiator-convection type battery can serve as a heating device.

The hydraulic system 1 is equipped with pumping equipment connected to a source of heat supply and / or hot water supply, including at least one pump 2, mainly with an electric drive, shut-off and / or shut-off and control valves 3 with a locking element, as well as at least , one hydromechanical device 4 of a smooth load of the hydraulic system 1 connected to the pipeline 5. The hydromechanical device is connected on the pressure side in the area between the pressure pump 2 in the pipe 5 and the shut-off th and / or shut-off and control valves 3. It is communicated with the pipeline 5 through the working fluid 6, mainly along the coolant. The hydromechanical device 4 includes an inlet pipe 7 connected in series with each other, a regulator 8 for opening the shut-off and / or shut-off and control valves 3 and transferring the load to the hydraulic system 1 with a check valve 9 and a nozzle 10, as well as a hydromechanical actuator 11. Connection to the pipeline 5 hydromechanical device 4 is made double: at the inlet by the inlet pipe 7 it is communicated with the pipeline 5 through the working fluid 6, and at the exit - kinematically by a hydromechanical drive 11 with a locking element (to hell hedgehogs not shown) of shut-off and / or shut-off and control valves 3. The hydromechanical actuator 11 includes a power chamber 12 and a gear mechanism 13. The gear mechanism 13 is made movable and connected to the power chamber 12 of the piston-rod or membrane-rod type depending on the design of the power chamber 12. The transmission mechanism 13 is movably connected with the formation of a drive with a locking element of the said armature 3 with the possibility of automatic movements of the locking element in the range from full overlap to fully open on flow conduit and vice versa.

The regulator 8 of the speed of opening of the shut-off and control valves 3 can be in communication with the power chamber 12 both through the working fluid 6, that is, through the coolant, and through the intermediate (additional) working fluid 14 or several bodies, liquid and / or gaseous. As an intermediate (additional) working fluid 14, a gel may be used. When using several working fluids in the area between the speed controller and the power chamber, a device or devices of known designs can be used that interfere with the mixing of the working fluids between themselves.

The opening speed controller 8 of said reinforcement 3 includes a housing 15 in which a check valve 9 and a nozzle 10 are placed, the nozzle 10 and the check valve 9 being structurally combined. The non-return valve 9 contains a stem 16 having a passage channel 17 with outlet holes 18. A shutter 19 is made at one end of the rod 16 and a nozzle 10 at the other end. The nozzle 10 is a control screw element 20 inserted into the passage channel 17 of the check valve stem 16 9. The screw element 20 is configured to overlap the passage section of the passage channel 17 — the passage hole for its calibration using the needle 21 of the nozzle 10, which is provided with the screw element 20. This calibration is achieved by changing the position of the needle 21 of the nozzle 10 relative to the passage channel 17. On the screw element 20 of the nozzle 10, a return device is installed in the form of a spring 22. The housing 15 of the controller 8 for opening the shut-off and / or shut-off and control valves 3 contains three compartments. In the first compartment 23, there is a check valve 19 with an inlet 24 of the passage channel 17 formed in it. In the second compartment 25, there is a rod 16 of the check valve 9 and the outlet openings 18 of the passage channel 17. In the third compartment 26 there is a screw element 20 of the nozzle 10 and the return device of the controller 8 of the opening speed (spring 22). The second compartment 25 is connected via a working fluid 6 to the power chamber 12. The nozzle 10 is equipped with a calibration device. To this end, a hole 27 is made in the third compartment 26, closed by a screw plug 28, which allows you to manually adjust the passage speed of the passage channel 17 through the hole through the screw element 20 from the outside of the housing 15 of the regulator 8 to open the shut-off or shut-off and control valves 3.

The power chamber 12 is a housing 29 provided with a sealed elastic membrane 30, dividing it into two compartments. The compartment 31 filled with the working fluid 6 changes its working volume, since it is regulated to be refilled with the liquid working fluid 6 with increasing pressure in the pipeline. Another compartment is a compartment 32 which is not filled with a working fluid 6. The membrane 30 is made with the possibility of alternating deformation, depending on the pressure, both towards the filled compartment 31 and towards the unfilled compartment 32. An opening 33 is made in the unfilled compartment 32 with a guide fixed therein a sleeve 34, providing translational movement of the gear mechanism 13.

In another embodiment (FIG. 2), the power chamber 12 is a cylinder body 28 provided with a piston 35 that separates it into the compartment 31 with a variable working volume filled by the working fluid 6 and the non-fillable compartment 32. The piston 35 is movable depending on the pressure, both towards the filled compartment 31 and towards the non-filled compartment 32 of the power chamber 12. In the non-filled compartment 32 of the power chamber 12, an opening 33 is made with a guide sleeve 34 fixed therein, providing gearbox movement 13.

The transmission mechanism 13 consists of two elements. The first element 36 - the rod of the transmission mechanism 13 is connected through a safety pad 37 to the membrane 30 in the embodiment of the power chamber 12 with the membrane or to the piston 35 - in another embodiment of the power chamber 12. The second element 38 is connected to the locking body of the shut-off and control valves 3, preferably through a spindle with the possibility of rotary movement of the latter. The first 36 and second 38 elements of the transmission mechanism 13 are made rectilinear and interconnected movably, for example articulated. In the second element 38, in the place of its connection with the first elements 36, a hole 39 is made, inside of which there is a pin 40, connecting both of these elements. The second element 38 of the transmission mechanism 13 is made with the possibility of rotation from 0 to 90 degrees from the initial position, while 0 degrees corresponds, for example, to a completely closed valve, and a value of 90 degrees is fully open.

The hydromechanical actuator 11 in a preferred embodiment is provided with a return device in the form of a spring 41 mounted on the second element 38 — the rod of the transmission mechanism 13 and connected either to the transmission mechanism 13 or to the membrane 30 or to the piston 35 of the power chamber 12.

Shut-off and / or shut-off and control valves 3 is a ball valve (not shown in the drawing). The transmission mechanism 13, interacting with it, can be made in the form of a lever or crank mechanism. Or, the first element 34 of the transmission mechanism can be made in the form of a gear rack 42, and the second element 36 can be in the form of a gear wheel 43 associated with shut-off and control valves 3 (Fig. 10).

The maximum throughput of the non-return valve 9 of the speed controller 8 of the opening of said reinforcement 3 is at least two times higher than the maximum throughput of the nozzle 10.

The operation of the hydraulic system 1 of heat supply and / or hot water supply, equipped with a hydromechanical device 1 for smooth loading of the hydraulic system, in General, can be described as follows.

Turn on the pump 2, communicated on the one hand with a source of liquid, and on the other with an automatic hydromechanical device 4. Starting the electric motor 44 of the pump 2 is carried out in two stages. At the first stage, when the shut-off and control valves 3 are closed, the engine runs, preferably at idle or close to them, without pumping the coolant volume of the hydraulic system 1, but pumping it into the speed control valve 8 of the shut-off and control valves 3, which is connected to the pipeline 5 in the area between the pump 2 and the shut-off and control valves 3. The working fluid 6, the coolant, passing through the nozzle 10 of the regulator 8 of the opening speed of the shut-off and control valves 3, enters the power chamber 12. In the process of In this case, the working fluid 6 begins to act on the membrane 30, gradually deforming it, or on the piston 35, gradually moving it. The membrane 30 (piston 35), deforming (moving), drives the first element 36 of the transmission mechanism 13, which moves progressively in proportion to the deformation of the membrane 30 (movement of the piston 35). The first element 36, moving, overcomes the force of the return device in the form of a spring 41 of the hydromechanical actuator 11. With the help of the second element 38 of the transmission mechanism 13 connected with the first element 36, the translational movement is converted into the movement of the locking body of the valve 3, aimed at the gradual opening of the valve during a certain period of time. Before operating the pipeline 5, the nozzle 10 of the speed controller 8 is adjusted in such a way as to provide the necessary time interval from the start of starting the pump motor with the valve 3 closed to the complete opening of the valve 3. This interval is in the range from 1 to 30 s. After stopping the electric motor 44 and reducing the pressure in the pipeline 5, the working fluid 6 is forced out of the power chamber 12 through the check valve 9 of the valve 8 for opening the valve 3 opened by the pressure of the spring 41. The opening of the check valve 9 is provided by the force generated by the return device (spring 41) hydromechanical actuator 11, which exceeds the force generated by the return device (spring 22) of the check valve 9. The maximum throughput of the check valve 9, at least twice the maximum nozzle throughput 10.

The operation of a closed hydraulic building heat supply system, for example, equipped with a vortex heat generator, is performed as follows (Fig. 11).

This hydraulic system 1 contains a pump 2, an electric motor 44 of a pump 2, for example, А200М2Ж2 grade as part of a KM 100-65-250 electric pump unit, a hydromechanical device 4, an expansion tank 45, a swirl heat generator 46, for example, similar to the design of a vortex heat generator VTG-37- IV, the device of which is known from patent RU 2129689 C2, 04/27/1999, heat exchanger 47, temperature sensor 48, cabinet 49 for automatic control of starting the electric motor 44.

Engine Features:

- Power 37 kW;

- Voltage 380 V;

- Rated current 70 A.

At the moment when the electric motor 44 is turned off or in "sleep mode", the shut-off and control valves 3 are in the closed position, and the working fluid 6 (coolant) of the hydraulic system 1 does not circulate through it.

When the temperature drops below a certain point, the temperature sensor 48 is activated, which continuously sends a signal to the automatic control cabinet 49, which supplies power to the electric motor 44 connected to the pump 2 in a monoblock. After starting, the electric motor 44 first moves the working fluid 6 in its small volume, as a result of which it runs at idle for some time, and the fluid flow rate Q — the volume pumped by pump 2 is practically zero. At the outlet of the pump 2 and in the area in front of the shut-off and control valves 5, the pressure increases. Through the opening speed controller 8 with a non-return valve 9, pressure is transmitted to the power chamber 12. Since the calibrated orifice regulated by the needle 21, based on the required loading speed of the electric motor 44, allows a small amount of liquid to pass into the power chamber 12, the power chamber 12 is filled slowly (during for a certain period of time), after which, under the action of liquid pressure - the working fluid 6, the membrane bends and informs the first element 36 of the transmission mechanism 13 translational motion. The first element 36, in turn, acting on the second element 38 of the transmission mechanism 13, gives it a rotational movement and smoothly rotates the second element through an angle of about 90 °, opening the shut-off and control valves 3 and gradually increasing the flow rate Q from 0 to 100 m ³ / h

With an increase in the flow cross section of the pipeline 5 and, consequently, the flow rate Q, the load on the electric motor 44 increases, and the current strength from its initial value of 10-12 A, corresponding to idling, increases to its nominal value, for example 70 A, at Q = 100 m ³ / h

Moreover, preferably, the calibrated hole of the valve 8 of the opening speed of the valve 3 is controlled so that the magnitude of the current depending on the flow rate varies linearly.

When the required temperature is reached by the signal of the sensor 48 to the automatic control cabinet 49, the power supply to the electric motor 44 is stopped and it is turned off. The pressure at the outlet of the pump 2 and the portion from it to the stop valves 3 falls, and the membrane 30 (piston 35) under the action of the elastic force of the expanding compressed spring 41 returns to its original position. The transmission mechanism 13, associated with the shut-off and control valves 3, overlaps the working section of the pipeline 5. After that, the hydromechanical device 4 and the hydraulic system 1 return to their original state and are ready for the next start when the temperature drops and the sensor 48 responds.

The proposed device has a large degree of versatility and can work in the following ranges of its characteristics:

- the range of fluid flow when regulating the load is in the range from 0.1 to 250 m ³ / h inclusive;

- the pressure at the inlet of the speed controller can be in the range from 0.5 to 10 atm inclusive;

- working section of the pipeline and / or shut-off and control valves from 20 to 120 mm or more;

- the time of the full opening of the closed shut-off and control valves from 1 to 30 seconds or more.

The device with the same configuration can work in hydraulic systems with electric pump units with power from 0.5 to 75 kW.

Claims (25)

1. The heat supply and / or hot water supply system of a complex consumer of thermal energy, including local consumers in the form of separate buildings or structures, combined, for example, in architectural and construction groups, microdistricts, quarters, towns, cities, characterized in that it is a hydraulic a system including a distribution network of pipelines connected via a heat carrier with a heat supply source, for example, a boiler house, thermal power station, thermal power station, boiler and and a main heating main and with local consumers of thermal energy, shut-off and / or shut-off and control valves with a locking element, pumping equipment comprising at least one pump, mainly with an electric drive, and at least one hydromechanical device hydraulic system loads connected to the pipeline, mainly from the pressure side in the area between the pump or pump group that creates the pressure in the pipeline and the closest shut-off and / or shut-off and control valves connected with the pipeline through the working fluid, mainly through the coolant and mounted with the possibility of automatic prolonged on and off of shut-off and / or shut-off and control valves, while the hydromechanical device includes an inlet pipe connected in series with each other, having a shutter opening speed controller and / or shut-off and control valves and load transfer to a hydraulic system equipped with a check valve and a jet, and hydromechanical water, including a power chamber with a housing containing at least one compartment with a variable working volume, adjustable refillable with a liquid working fluid with increasing pressure in the pipeline, and a transmission mechanism, while the connection to the pipeline of the hydromechanical device is double: at the inlet - it is inlet connected to the pipeline through the working fluid, and at the exit, by a kinematically hydromechanical actuator with a locking element of the aforementioned valves, the transmission mechanism being made a piston rod connected to a power chamber of the piston-rod or membrane-rod type, the rod, in turn, being movably connected with the formation of a drive with a locking element of the aforementioned valve with the possibility of automatic movement of the locking element in the range from full overlap to completely open to the duct and vice versa. 2. The system according to claim 1, characterized in that at least one of the local consumers of thermal energy includes an industrial enterprise, for example, a metallurgical plant, a machine-building plant, shipyards, a food factory, a bakery, a winery, and a complex consumer. , meat factory, dairy, creamery. 3. The system according to claim 1, characterized in that it includes at least one public or commercial complex, or an educational institution, or at least one automobile manufacturing plant and / or transport, trucking enterprise. 4. The system according to claim 1, characterized in that the aforementioned non-return valve and nozzle are placed in the body of the opening speed controller of said valve, the nozzle and non-return valve being structurally combined. 5. The system according to claim 1, characterized in that the check valve of the valve for opening speed of said valve comprises a rod with a through-hole with outlet openings with a damper made at one end and a nozzle at the other end, including a control element, preferably a screw element, introduced into the passage channel of the check valve stem with the possibility of at least partially overlapping the passage section of the passage channel - the passage hole for its calibration using the nozzle needle, which is equipped with a screw element, by changing its position relative to the throughput channel. 6. The system according to claim 5, characterized in that the speed controller for opening the said valve is equipped with a return device mounted on the screw element of the nozzle and made, for example, in the form of a spring. 7. The system according to claim 6, characterized in that the casing of the speed controller for opening the shut-off and / or shut-off and control valves contains at least three compartments, in the first compartment there is a check valve with an inlet of the passage channel the second compartment contains at least partially a check valve stem and at least one outlet passage of the passage channel made in the rod; in the third compartment there is a screw element of the nozzle and a return device of the open speed controller While the second compartment is connected on the working fluid to the power chamber and the opening in the housing of the speed controller in the third compartment an opening closed by a screw plug for adjusting the flow cross section of the passageway through the screw member. 8. The system according to claim 5, characterized in that for changing the position of the nozzle needle relative to the through hole, the nozzle is equipped with a calibration device that can be manually adjusted from the outside of the body of the speed controller for opening the shut-off or shut-off and control valves. 9. The system according to claim 1, characterized in that the hydromechanical device is equipped with a return device for a hydromechanical drive associated with the transmission mechanism and / or the membrane of the power chamber and made, for example, in the form of a spring, and the speed controller for opening the said valve is equipped with a return device connected with a check valve and / or nozzle and made, for example, in the form of a spring. 10. The system according to claim 1, characterized in that the power chamber is equipped with a sealed elastic membrane dividing the power chamber housing into said compartment with a variable working volume filled with a working fluid and a non-filled compartment, the membrane being made with the possibility of alternating deformation, depending on pressure, both in the direction of the filled compartment, and in the direction of the non-filled compartment of the power chamber, and in the non-filled compartment of the power chamber a hole is made with a guide sleeve fixed therein, about providing translational movement of the gear mechanism. 11. The system of claim 10, characterized in that the shut-off and / or shut-off and control valves are made with a locking body having a spindle, and the gear mechanism consists of at least two elements, the first element being the gear rod through the safety the pad is connected to the membrane of the power chamber, and the second element is connected to the locking body of the shut-off and control valves, preferably through a spindle with the possibility of rotary movement of the latter. 12. The system according to claim 11, characterized in that the first and second elements of the transmission mechanism are made rectilinear and are interconnected movably, for example, by hinge, and in the second element at the junction of it with the first there is a hole inside which there is a pin connecting both of these element, and the second element of the transmission mechanism is made with the possibility of rotation from 0 to 90 ° from the initial position, while 0 ° corresponds, for example, to completely closed fittings, and a value of 90 ° to fully open. 13. The system according to claim 1, characterized in that the power chamber is equipped with a piston dividing the power chamber body into said compartment with a variable working volume filled with a working fluid and a compartment that is not filled with it and made with the possibility of movement depending on pressure both towards the filled compartment, and towards the non-fillable compartment of the power chamber, and in the non-fillable compartment of the power chamber a hole is made with a guide sleeve fixed therein, providing translational movement of the transmission mechanism. 14. The system according to claim 1, characterized in that the shut-off and / or shut-off and control valves is a valve, for example a ball valve. 15. The system according to claim 1, characterized in that the gear mechanism interacting with the shut-off and / or shut-off and control valves is made in the form of a lever, or a crank mechanism, or a gear rack. 16. The system according to claim 1, characterized in that the maximum throughput of the non-return valve of the valve of the speed of opening of said armature is at least two times the maximum throughput of the nozzle. 17. The heat supply and / or hot water supply system of a building, structure, characterized in that it is a hydraulic system, including connected to the distribution network or to the boiler, at least one inlet pipe with a liquid coolant, preferably hot water, pipeline, communicated via a heat transfer medium with a system of internal wiring pipes equipped with at least one heating device, mainly a radiator or radiator-convection type battery, tap fittings with a locking element, as well as at least one hydromechanical device for smooth loading of the hydraulic system, connected to the pipeline, mainly from the pressure side in the area in front of the shut-off and / or shut-off and control valves, in communication with the pipeline through the working fluid, mainly , water mounted and with the possibility of automatically prolonged on and off shut-off and / or shut-off and control valves, while the hydromechanical device includes after an inlet pipe interconnected to one another, having a body having a speed regulator for opening the shut-off and / or shut-off and control valves and transferring the load to the hydraulic system, equipped with a check valve and a nozzle, and a hydromechanical actuator including a power chamber with a housing containing at least one compartment with a variable displacement, adjustable refillable liquid working fluid with increasing pressure in the pipeline, and a transmission mechanism, while the connection to the pipeline is hydromechanical The device is designed in two ways: at the inlet - with the inlet pipe it is connected with the pipeline through the working fluid, and at the outlet - with a kinematically hydromechanical drive with a locking element of the mentioned fittings, the transmission mechanism is made movable, connected to the power chamber by the “membrane-rod” type, this, the rod, in turn, is movably connected with the formation of the actuator with a locking element of the aforementioned valves with the possibility of automatic movements of the locking element in the range from full overlap to completely Access the duct on the duct and vice versa. 18. The system according to 17, characterized in that the aforementioned non-return valve and nozzle, made structurally combined, and a non-return device, the non-return valve comprising a through channel with outlet openings with a rod made on one its end is a shutter, and on the other - a nozzle, including a regulating, preferably screw element, inserted into the passage channel of the check valve stem with the possibility of at least partial overlap the by-pass section of the passage channel — the passage hole for its calibration using the nozzle needle, which is provided with the screw element, by changing its position relative to the passage channel, and the return device is mounted on the screw element of the nozzle and is made, for example, in the form of a spring. 19. The system according to p. 18, characterized in that the body of the speed controller for opening the shut-off and / or shut-off and control valves contains at least three compartments, in the first compartment there is a check valve with an inlet of the passage channel the second compartment is located, at least partially, the check valve stem and at least one outlet passage of the passage channel made in the rod, in the third compartment there is a screw element of the nozzle and the return device of the speed controller is open I, wherein the second compartment is connected on the working fluid to the power chamber and the opening in the housing of the speed controller in the third compartment an opening closed by a screw plug for adjusting the flow cross section of the passageway through the screw member. 20. The system according to p. 18, characterized in that for changing the position of the nozzle needle relative to the through hole, the nozzle is equipped with a calibration device made with the possibility of manual adjustment from the outside of the body of the speed controller opening the shut-off or shut-off and control valves. 21. The system according to 17, characterized in that the power chamber of the hydromechanical actuator is equipped with a sealed elastic membrane that separates the housing of the power chamber into said compartment with a variable working volume and a compartment that is not filled with it, and the membrane is made with the possibility of alternating deformation directed towards depending on the pressure, both towards the filled compartment and towards the non-filled compartment of the power chamber, and in the non-filled compartment of the power chamber a hole is made with him guiding sleeve, providing translational movement of the gear mechanism. 22. The system according to 17, characterized in that the shut-off and / or shut-off and control valves are made with a locking body having a spindle, and the transmission mechanism consists of at least two elements, the first element being the rod of the transmission mechanism through the safety the pad is connected to the membrane of the power chamber, and the second element is connected to the locking body of the shut-off and control valves, preferably through a spindle with the possibility of rotary movement of the latter, while the hydromechanical device is equipped with ozvratnym hydromechanical device actuator associated with the gear mechanism and / or force chamber and membrane made, for example, a spring. 23. The system according to p. 22, characterized in that the first and second elements of the transmission mechanism are made rectilinear and interconnected movably, for example, by hinge, and in the second element at the junction of it with the first there is a hole inside which there is a pin connecting both of these element, and the second element of the transmission mechanism is made with the possibility of rotation from 0 to 90 ° from the initial position, while 0 ° corresponds, for example, to completely closed fittings, and a value of 90 ° to fully open. 24. The system according to 17, characterized in that the shut-off and / or shut-off and control valves is a valve, for example a ball valve, and the transmission mechanism interacting with it is made in the form of a lever, or a crank mechanism, or a gear rack. 25. The system according to 17, characterized in that the maximum throughput of the non-return valve of the valve of the speed of opening of said reinforcement is at least two times the maximum throughput of the nozzle.

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