RU2306495C1 - Electrically driven rotational heat generator - Google Patents

Abstract

FIELD: electrically driven heat generator with rotational working organs for heating residence rooms and separate buildings.

SUBSTANCE: heat generated at operation of electric motor is transmitted to outer heat consumption system due to forming heat exchange ducts along peripheral surface of stator of electric motor with supply duct communicated with heat consumption system. Heat exchange ducts are hydraulically insulated stator cavity filed with electrically insulating liquid and from rotor of electric motor. Arrangement of heat exchange ducts of electric motor between duct for supplying cooled heat transfer agent and inlet of energy-producing rotational working organs allows control pressure in cavity of shaft according to temperature of heat transfer agent in that cavity till level providing cavitation-free liquid flowing in said heat exchange ducts and in inner cavity of electric motor.

EFFECT: enhanced operational reliability, relatively small size and mass, improved vibration-acoustic characteristics of heat generator.

11 cl, 3 dwg

Description

The proposal relates to thermal cavitation-vortex heat generators driven by an electric motor, used for heating and hot water supply systems, for heating technological devices, and also as technological devices for activating technological processes involving liquid passing through the heat generator.

Widely known are electric vortex heat generators with drive electric motors, see Fig. 7.12, p. 229 in the book [1] - an analogue. The disadvantage of such heat generators is that the heat generated by the electric motor due to its internal losses is dissipated into the environment, which reduces the efficiency of the heat generator by the value of the efficiency of the electric motor itself, and practically and to a greater extent due to blowing of the heat generator by the air flow from the electric motor fan. In addition, heat generators of this type require the removal of coolant leaks that pass through the shaft seal with the working heat-generating organs of the heat generator.

The closest in technical essence and purpose, is the design of the electric vortex heat generator adopted for the prototype, in which there is at least one heat-generating working element 1 and at least one pumping working element mounted on the shaft of the electric motor 3, moreover, the electric motor is made by a cooled coolant, and the working bodies are hydraulically connected by their output to an external heat consumption system 6, see Fig. 3.8, p. 85 in the book [1].

The known electric drive heat generator has significant advantages over similar technical solutions due to the fact that the heat generated by the electric motor (due to its internal losses) is transferred to the coolant, which increases the thermal efficiency of the heat generator as a whole. The disadvantages of the prototype are that the electric motor is carried out with a stator and a rotor located directly in a relatively large tank with a pumped liquid, which limits the temperature of the coolant and its physico-chemical properties, reduces the reliability of the unit when there is any significant increase in the temperature of the coolant, since heat removal only a small part of the fluid flow circulating through the heat consumption system is carried out from the motor housing. The presence of a relatively large tank, in which the electric motor and working bodies are located, significantly increases the mass-dimensional characteristics of the heat generator (the tank is an integral part of the heat generator). In addition, the cooling of the motor is carried out only in the presence of an additional circulation pump 4, which is therefore also structurally necessary for the known type of heat generator.

The technical problem to which the invention is directed is, while maintaining the dignity of the prototype (determined by ensuring the transfer of energy losses in the electric motor to the coolant supplied to the external heat consumption system), a significant improvement in the mass-dimensional characteristics, a decrease in the sensitivity of the heat generator to the physicochemical properties of the coolant and its temperature , as well as a significant improvement in vibration noise and other operational characteristics of the heat generator.

In an electric drive vortex heat generator containing at least one heat generating working body and at least one pump working body mounted on the motor shaft, the electric motor being made by a cooled coolant, and the working bodies are hydraulically connected with an external heat consumption system by their output, The problem is solved in that the electric generator of the heat generator is equipped with internal additional heat-exchange tubes made along the peripheral surface of the stator housing by channels connected by their input channels located on the rear shield of the electric motor with a supply channel communicated with the output channel of the heat consumption system, additional heat exchange channels are made hydraulically isolated from the stator cavity and the rotor of the electric motor filled with electrically insulating fluid by means of a shaft seal and a compensating flexible elastic element shunting this seal hydraulically in communication with said heat exchange channels, the output of which is n in the front shield of the motor and in fluid communication with the entrances mounted on the motor shaft, at least one heat generating actuator;

- temperature and pressure sensors connected to the pressure setting device in this cavity are connected to the cavity of the front shield of the electric motor in the exit zone of the additional body exchange channels;

- the pumping working body is structurally combined with a heat generating working body in a generally mounted disk-shaped rotor with vortex-generating elements and pressure equalization channels at its ends mounted on the electric motor shaft and located with end gaps between the stationary motionless working bodies of the heat generator;

- shunting the seal, the movable elastic element is located in the cavity between its working bodies and the front shield of the electric motor and is made in the form of an axisymmetric membrane, fitting a sleeve located along the axis of the housing with the shaft seal of the electric motor;

- the electric motor is equipped with an additional pumping element installed in its insulated internal cavity and channels for circulating the electrically insulating liquid along the working bodies and the electric motor casing in areas connected in heat with the additional heat exchange channels of the stator;

- the sleeve with the shaft seal is made rigidly connected to the motor housing and hermetically connected to the central part of the axisymmetric membrane, and its peripheral part is hermetically connected to the motor housing in the exit zone of the additional heat-exchange channels;

- the sleeve with the shaft seal is made movable along the shaft, equipped with sliding bearings and hermetically connected to the Central part of the axisymmetric membrane;

- in the cavity of the location of the stator and rotor of the electric motor is a temperature sensor associated with the control system of the heat generator;

- a movable dividing elastic element separating the stator and rotor cavity with heat exchange channels of the electric motor and the heating system is made inside a separate container located outside the motor housing hydraulically connected on one side with the stator and electric motor rotor cavities and, on the other, with heat exchange channels mainly in the zone of their exit into the cavity of the location of the motor shaft;

- the rear shield of the electric motor in its central part is provided with a first channel emerging from the end cover of the heat generator, configured to communicate the internal cavity of the stator and the rotor of the electric motor in its extremely extreme end part with the environment, as well as to seal and connect it to the stator cavity filling system and the rotor of the electric motor with a vacuum electrically insulating liquid, and the second channel of the hermetic conclusion of the power cables of the electric motor and control of its temperature urs, wherein between the end cover of the heat generator and the rear shield of the electric motor is formed an annular chamber in fluid communication with both inputs into the internal heat exchanging channels and with a supply channel communicating with the outlet channel of the heat consumption system;

- in the housing element of the heat generator, a position sensor for the movable shunt shaft seal of the elastic element is installed, connected with the alarm system and / or motor shutdown.

The invention is illustrated by drawings, where in Fig. 1 an example of a heat generator with an axisymmetric movable elastic element and a stationary shaft seal sleeve is given, Fig. 2 is an example of a heat generator with a seal sleeve movable on a shaft, an additional movable elastic element with its position sensor, temperature sensor in the cavity of the rotor and stator, a circuit for filling the internal cavity of the electric motor with an electrically insulating liquid, a circuit for connecting a heat generator to a heat consumption hydraulic system.

The electric vortex heat generator in the implementation example of FIG. 1 contains at least one combined working body 1, a disk-shaped rotor, mounted on the shaft 2 of the rotor 3, which interacts with the stator 4 of the electric motor. The stator 4 and the rotor 3 are located in a housing consisting of a front shield 5 and a rear shield 6. The rotor 3 is located in the sliding bearings 7 and 8, and the output shaft 2 of the electric motor is sealed by a contact seal 9 of any known type (cup, end or combination). The internal cavity of the electric motor 10 is filled with a lubricating, electrically insulating liquid. On the peripheral surface of the stator housing 4 of the electric motor, internal heat exchange channels 11 are made, connected by their input channels 12 located on the back shield 6 with a heat supply channel 13, which is used to connect to the output (return) channel 14 of the heat consumption system 15. The heat exchange channels 11 are made hydraulically isolated from the cavity 10 of the electric motor by means of a seal 9 (on the shaft 2) and the compensation movable element 16 shunting this seal.

The output channels 17 of the heat exchange channels 11 are hydraulically connected to the input channels 18 of the pumping working body and the channels 19 of the heat generating working body, which in this embodiment are structurally combined in a disk-like rotor 1 mounted on a shaft, and the output from these working bodies is made into a common annular the housing chamber 20 with a pressure channel 21 hydraulically connected to the input channel 22 of the heat consumption system 15.

Shunting elastic movable element 16 to reduce the dimensions of the heat generator and more completely unload the seal 9 from the pressure drop in the sealing zone of the shaft 2 is made located in the cavity between the pump and heat-generating working bodies of the disk-shaped rotor 1 and the front shield 5 in the form of an axisymmetric membrane 16, fitting around located on the axis housing sleeve 23 with a seal 9 of the shaft 2 of the motor. When the membrane 16 is made without an internal power cord, its movement is limited by the limiters of its extreme positions 24 and 25. The volume of liquid displaced by the movable element 16 when moving between the extreme positions is guaranteed to be larger than the volume of temperature-related volumetric deformation of the electrically insulating liquid filling the cavity 10 . When performing the membrane 16 with a power cord, these stops may be absent.

To increase the reliability of the heat generator and the power unloading of the sliding bearings 7 and 8 from axial forces in this example of the heat generator, its heat-generating vortex-forming elements (working bodies) are made on the end surfaces of the disk-shaped rotor 1, the rotor is installed with gaps between the casing disk working bodies 26 and 27 of the heat generator, which for equalizing the pressure in the gaps are communicated by channels 28, which, in turn, are hydraulically connected with the outputs 17 of the channels 11 through an annular chamber adjacent to the single shield 5 of the electric motor. To eliminate radial forces, the peripheral surface of the disk-shaped rotor 1 directly exits into the annular chamber 20 of constant pressure (due to the calculated small difference in the velocity of the fluid along its annular channel).

To intensify the process of heating the liquid, the vortex-forming channels of the heat-generating working bodies, made at the ends of the rotor 1 and the elements 26 and 27, are equipped with channels for recirculation 29 of the fluid flowing in the indicated vortex-forming channels of the working bodies. Heat generating working bodies can also be performed on the peripheral surface of the rotor 1. However, since this leads to radial loads on bearings 7 and 8, such a working bodies are not preferred to increase the reliability of the heat generator.

The electric motor is equipped with an additional pumping unit 30 installed in its insulated inner cavity 10 and channels 31, 32, 33 for circulating the electrically insulating liquid along the stator 4, rotor 3, bearings 7, 8 and the motor housing in the heat-related areas of the front and rear electric shields and additional heat-exchange channels 11. The pumping body 30 can be mounted on the shaft and on the side of the rear shield of the electric motor to provide reverse flow of electrically insulating fluid in the direction of flow cavity 10 through the channels 31, 32, 33.

In this embodiment, the sleeve 34 with the seal 9 of the shaft 2 is rigidly connected to the motor housing and hermetically connected to the central part of the axisymmetric membrane 16, the peripheral part of which is hermetically connected to the motor housing in the area of the output channels - openings 17 of the heat exchange channels 11, which provides the most complete pressure equalization on the seal 9 and virtually eliminates leakage through it.

In the embodiment of FIG. 2, the sleeve 34 is movable along the shaft and provided with sliding bearings 35, and is also hermetically connected to the central part of the axisymmetric membrane 16, made in the form of a bellows, for example metal (to further improve the conditions for heat removal from the cavity 10), a conical element that generally provides an increase in the volume of fluid displacement with the mobility of the elastic element, as well as minimizing the impact of the surface of the shaft on the sealing lips of the seal 9 in the presence of radial runout of the shaft 2, bottom sealed for durability seals. To increase reliability, the seal 9 is made in the form of two cuffs oriented by jaws with sealing lips in different directions on the shaft surface.

To increase the reliability, a temperature sensor 36 is installed in the cavity 10, see Fig. 1, which sends a signal via cable 37 about the temperature of the stator windings 4 and / or the temperature of the liquid in the cavity 10 to the heat generator motor control system and / or the coolant circulation control system through heat exchange channels 11, for example, by controlling the flow area of the chokes 38, 39 installed at the output and input of the heat consumption system 15.

Compensating movable elastic element 16, separating the cavity 10 with the stator 4 and the rotor 3 and the heat exchange channels 11 of the electric motor and heating system 15, can be installed on the side of the rear shield 6 of the electric motor, see Fig. 3, or in a separate external housing capacity 40, the connection of which to the heat exchange channels 11 is preferably made from the front shield 5 of the motor to reduce the pressure drop across the seal 9, although it can be connected to the inlet channel 13.

The rear shield 6 of the electric motor in its central part is provided with one (first) channel 41 emerging from the end cover of the heat generator, see FIGS. 1 and 2, configured to communicate the internal cavity 10 of the electric motor in its extremely extreme end part with the environment, as well as the possibility of sealing it, for example, with a plug or valve 42 and connecting to the filling system of the cavity 10 of the electric motor with a vacuum electrically insulating liquid (not shown in the drawing), and another (second) channel 43 of the hermetic cable outlet 44 power supply of the electric motor and the cable 37 of the temperature sensor 36, and between the end cover of the heat generator and the rear shield of the electric motor there is an annular chamber 45 hydraulically communicated with both the inputs 12 to the internal heat exchange channels 11 and the supply channel 13 in communication with the output channel 14 of the heat consumption system fifteen.

To monitor the state of the heat generator and prevent emergencies, the movable elastic element 16 can be made interacting with a sensor of permissible extreme positions of this element installed in the body elements of the heat generator, for example, made in the form of position sensors (of any known types) 46 communicated with the control unit 47 of the heat generator electric motor and an alarm system about an unacceptable condition of the temperature volume compensation unit with element 16.

To ensure a cavitation-free mode of flow of the coolant through the channels 11 and in the cavities of the front shield 5 of the electric motor, including the cavity 10, temperature and pressure sensors are connected to the cavity of the shaft 2 of the motor, respectively 48 and 49 of the control system 50 of the pressure level in it, providing a cavitation-free flow of the coolant in this cavity, for example, by regulating the pressure by the throttle 38 (measured by the sensor 49) in a given function of the temperature measured by the sensor 48, or by setting the pressure in the reduction system 15 torus 51.

To ensure the possibility of an optimal heat-generating process, a throttle 39 and a pressure sensor 52 are installed at the outlet of channel 21 or in channel 22 of the heat consumption system 15, by means of which pressure is set at the output of the working bodies - rotor 1 in the annular cavity 20, which allows you to adjust how the flow rate in working body 1, and the flow rate of the heated coolant in the heat consumption system 15.

The electric drive vortex heat generator operates as follows. When the electric motor is turned on, the rotor 1 starts to rotate, pumping fluid from the axial cavity 53 of the rotor 1 through the pumping working bodies - radial channels 54 and end gaps between the heat-generating vortex-forming channels made on the end surfaces of the rotor 1 and the case disk working bodies 26 and 27, which can also have vortex-forming channels, see, for example, RF patent 2201562. Heat-generating and pumping working bodies can have other forms of vortex-generating elements, see, for example, Fig. 2.9, 2.11, 2.16, etc., indicated in [1], and can also be combined, see the embodiment of Fig. 2, where they are implemented according to the patent of the Russian Federation 2201562. In this case, the coolant enters the annular chamber 20 and through the pressure channel 21 enters the heat consumption system 15. The cooled coolant enters the inlet channel 13 through the outlet channel 14, is distributed along the annular cavity 45, taking heat through the surfaces of the rear shield 6 and enters through the channels 12 into the heat exchange channels 11, removing heat from the stator 4 and from the cavity 10, and then enters through the channels 17 in the annular cam py location of the shaft 2 and further to the input channels 18,19 working rotor bodies 1.

This interconnection of the heat-removing channels provides a gradual increase in the temperature of the coolant along its path to the input channels 18, 19 of the working bodies. The temperature and pressure in the chamber of the location of the shaft 2 is controlled by sensors 48, 49, which allows the pressure in the cavity of the front shield 5 of the electric motor, for example, the throttle control 38, 50, 51, to exceed the pressure of the saturated vapor of the coolant by an amount that guarantees the absence of cavitation in the cavity 10 , channels 11 and cavities of the front shield 5 of the electric motor, and thereby the best conditions for the removal of heat generated by the electric motor due to its internal losses in the windings, magnetic circuit, bearings and friction losses e in the fluid flowing in the cavity 10. On the other hand, the regulators 38, 50, 51 also set the pressure at the inlet to the working bodies of the rotor 1, which ensures their normal and optimal energy release operation when the temperature of the coolant changes (which takes place in transient and change of heat energy removed from the system 15).

The intensification of the heat release process by heat-generating working bodies is achieved by appropriate selection of working bodies, fluid recirculation through channels 29 and channels 28 (mutually communicating end channels of rotor 1), by controlling the pressure at their inlet and outlet by pressure depending on the temperature of the coolant, for example, according to the patent RF 2212597, as well as due to the removal into the channels 11 of all heat losses of the electric motor. The channels 28 also align the pressure fields along the ends of the rotor 1 and thereby reduce the axial load on the bearings 7 and 8 of the electric motor.

The implementation of the electric motor with sliding bearings, their unloading from axial and radial loads due to the execution of pumping and heat generating working bodies in one rotor 1 unloaded from axial and radial loads, the possibility of good dynamic balancing of the rotor 1 and the rotor of the electric motor, the work of the working parts of the electric motor in an electrically insulating fluid with good heat dissipation, the operation of bearings in a fluid with good lubricity while ensuring a cavitation-free flow of fluid into heat transfer at the relatively small channels of the electric motor and in its internal cavity with relatively small dimensions of the unit provides generally high energy efficiency and reliable operation of the unit with low vibration noise activity, which, for example, allows it to be used for heating rooms with increased requirements for noise and vibration.

Information sources

1. Fominsky L.P. DIY rotary heat generators (DIY). Cherkasy, About OKO-Plus, 2003.

Claims (11)

1. An electric vortex heat generator containing at least one heat generating working body and at least one pump working body mounted on the motor shaft, the electric motor being made by a cooled coolant, and the working bodies are hydraulically connected with an external heat consumption system by their output characterized in that the heat generator electric motor is provided with internal additional heat-exchange channels made along the peripheral surface of the stator housing with its input channels located on the back shield of the electric motor with the supply channel in communication with the output channel of the heat consumption system, the additional heat exchange channels are made hydraulically isolated from the stator cavity and the rotor of the electric motor filled with electrically insulating fluid by means of a shaft seal and a compensation movable elastic element shunting this seal hydraulically communicated with the specified heat transfer channels, the output of which is made on the front shield e of the electric motor and is hydraulically connected with the inputs to the at least one heat generating working element mounted on the shaft of the electric motor. 2. The electric vortex heat generator according to claim 1, characterized in that temperature and pressure sensors connected to the pressure setting device in this cavity are connected to the cavity of the front shield of the electric motor in the exit zone of the additional body exchange channels. 3. The electric vortex heat generator according to claim 1, characterized in that the pumping working body is structurally combined with the heat generating working body in a generally mounted disk-shaped rotor with vortex-generating elements and alignment channels between the stationary motionless disk working bodies of the heat generator and provided with end gaps between the stationary motionless working bodies of the heat generator. pressure at its ends. 4. The electric vortex heat generator according to claim 1, characterized in that the movable elastic element shunting the seal is located in the cavity between its working bodies and the front shield of the electric motor and is made in the form of an axisymmetric membrane that encloses a sleeve located along the axis of the housing with a motor shaft seal. 5. The electric vortex heat generator according to claim 1, characterized in that the electric motor is equipped with an additional pumping body and channels for circulating the electrically insulating liquid along the working bodies and the electric motor casing in the heat zones associated with additional stator heat exchange channels. 6. The electric vortex heat generator according to claim 1, characterized in that the sleeve with a shaft seal is made rigidly connected to the motor housing and hermetically connected to the central part of the axisymmetric membrane, and its peripheral part is hermetically connected to the motor housing in the exit zone of the additional heat transfer channels. 7. The electric vortex heat generator according to claim 1, characterized in that the sleeve with the shaft seal is movable along the shaft, provided with sliding bearings and is hermetically connected to the central part of the axisymmetric membrane. 8. The electric vortex heat generator according to claim 1, characterized in that in the cavity of the stator and rotor of the electric motor there is a temperature sensor associated with the control system of the heat generator. 9. The electric vortex heat generator according to claim 1, characterized in that the movable dividing elastic element separating the cavity of the stator and rotor with heat exchange channels of the electric motor and the heating system is made inside a separate container located outside the motor housing that is hydraulically connected on one side with the stator cavity and the rotor of the electric motor, and on the other, with heat-exchange channels, mainly in the zone of their exit into the cavity of the location of the electric motor shaft. 10. The electric vortex heat generator according to claim 1, characterized in that the rear shield of the electric motor in its central part is provided with a first channel emerging from the end cover of the heat generator, configured to communicate the internal cavity of the stator and the rotor of the electric motor in its extremely extreme end part with the environment, as well as with the possibility of sealing it and connecting it to the filling system of the stator cavity and rotor of the electric motor with a vacuum electrically insulating liquid, and the second channel of the sealed output of electric motor power cables and control of its temperature, moreover, an annular chamber is made between the end cover of the heat generator and the rear shield of the electric motor, hydraulically connected both with the inputs to the internal heat exchange channels and with the supply channel in communication with the output channel of the heat consumption system. 11. The electric vortex heat generator according to claim 1, characterized in that the position sensor of the movable shunt shaft seal of the elastic element is connected to the alarm and / or motor shutdown system in the body element of the heat generator.

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