RU2541299C2 - Hydraulic heat generator and liquid heating device - Google Patents

Abstract

FIELD: power industry.

SUBSTANCE: invention refers to heat engineering. A hydraulic heat generator including an inlet swirling device connected to a housing of a vortex chamber, a heated liquid outlet branch pipe, which differs by the fact that it is provided on a throttle arrangement side with a paraxial central hole with a branch pipe installed in it and intended to supply additional liquid masses to the paraxial area of the vortex chamber, and the end faces of which are provided with lead screws with a gland seal providing adjustment of operating modes. A liquid heating device containing a hydraulic heat generator, a main-line pump with an electric drive, which is connected to the heat generator housing, supply and return pipelines with shutoff valves, which provide interaction of the heat generator with heat exchangers, which differs by the fact that the supply line is divided into two, one of which is directed to the vortex chamber swirling the flow, and the second one through an ejector to its paraxial area; besides, there are two discharge lines - one leaves a central hole of a diaphragm and is supplied to the pump inlet, the second one passes by a system of external heating apparatus and is sucked with the ejector to the paraxial area of the vortex chamber, thus forming a closed hydraulic circuit.

EFFECT: use of the invention allows accelerating the heating rate of non-compressed medium due to intensification of heat and mass exchange.

5 cl, 1 dwg

Description

The invention relates to the field of power engineering and heat generation in an environmentally friendly way and can be used both in heating systems of buildings, structures, vehicles, heating incompressible liquids, including water, and in heating devices for various purposes.

Various heat generators are known that use the conversion of the energy of moving working media into heat, in particular, hydraulic heat generators are known in which heat is generated when braking a swirling fluid flow (RU 2045715 C1, IPC F25B 29/00, 10.10.1995; RU 2059162 C1, IPC F24 D3 / 02, F24D 3/08, 04/27/1996; RU 2134381 C1, IPC F24D 3/02, F24J 3/00, 08/10/1999; RU 2140042 C1, IPC F24D 3/02, 10/20/1999; RU 2204090 C2, IPC F25B 9/02; F25B 29/00, 05/10/2003).

The well-known "Consumer heat supply system" (RU 2059162, IPC 6 F24D 3/02, F24D 3/08, 01/27/1996), which contains a heat generator in the form of a vortex chamber with a tangential fluid supply, heated in a cylindrical body of the vortex chamber, equipped with a brake device and heated fluid outlet pipe, electric water mains pump, supply, return and connecting piping, shut-off and control valves, expansion tank, connected to the consumer; to regulate the temperature and pressure of the coolant, a bypass line with the ability to bypass the coolant from the feed to the return pipe, as well as a device for automatically controlling the temperature of the coolant with the control unit, is used.

In the described and similar devices, the movement of the fluid entering the vortex chamber under pressure through a swirling flow inlet device (which can be made in the form of a cochlea, one or more tangential channels, etc.) acquires a vortex character. The fluid velocity increases at the moment it enters the vortex chamber. Once in it, the liquid due to the action of centrifugal forces is discarded to the inner surface of the cavity of the housing of the vortex chamber and, washing it, makes a helical movement, during which it is partially inhibited. In this case, the braking energy is converted into heat and heats the moving fluid. The fluid layers located at different distances from the axis of rotation of the vortex, in accordance with the law of conservation of momentum, have different speeds, which causes friction between the fluid layers rotating relative to each other and its further heating.

Known hydraulic heat generators and devices for heating the liquid have a low entry rate of the coolant (liquid) to the stationary mode to acceptable temperatures (above 70 ° C) and are not compact enough.

The closest in technical essence and the achieved effect is, adopted as a prototype, "Scheme of heating a water heating system with a heat generator" (RU 2202740 C2, IPC F24D 3/02, F25B 29/00, 04/20/2003), containing a heat generator in the form of a vortex chamber with a fluid flow swirling nozzle device, heated in a cylindrical vortex chamber body, equipped with a brake device and a heated fluid drain pipe (according to RU 2204090 C2, IPC F25B 9/02, F25B 29/00, 05/10/2003), electric water pump with electric drive, heat connected to the housing generator using an injection pipe, the supply and return pipelines with individual valves, respectively, the latter are connected in parallel so that the inlet pipe of the valve communicating with its output pipe to the supply pipe line is connected in parallel with the inlet pipe of the valve communicating with its output pipe with the return line pipeline, and the initial end of the return line is connected to the outlet pipe of the heat exchanger of the most distant consumer.

The economic efficiency from the application of the proposed scheme lies in the fact that the technological ability to regulate the circulation of water increases, however, the closest to the claimed invention device for heating a liquid with a hydraulic heat generator, although to a lesser extent, has the same disadvantages that were noted above: large dimensions, lack of effectiveness.

Therefore, the invention is based on the technical task of creating a hydraulic heat generator, which would be characterized by minimum dimensions, mass and higher efficiency and speed of reaching the temperature regime due to the intensification of the processes of energy conversion occurring in it.

The technical result is expressed in the intensification of the process of heating the liquid in a hydraulic heat generator and an increase in the rate of exit to a given temperature regime.

The technical result is achieved by the fact that a hydraulic heat generator including an input swirling device connected to the housing of the vortex chamber, the outlet pipe of the heated liquid, according to the present invention, is provided on the side of the throttle with a central axial hole with a pipe for supplying additional masses of liquid to the axial region of the vortex chamber , the ends are equipped with a lead screw with stuffing box seal, which provides adjustment of the operating modes of the end face of the vortex chamber remote from the nozzle inlet is equipped with a slot diffuser, the end face adjacent to the aperture opening is made in the form of a slot diffuser, slot diffusers are combined with snail heads.

In a fluid heating device comprising a hydraulic heat generator, an electric motor pump connected to the heat generator body, supply and return pipelines with shut-off valves, providing the heat generator to communicate with heat exchangers according to the invention, the supply line is divided into two — one of which is directed to the swirling device vortex chamber, and the second through the ejector to its axial region, in addition, there are two discharge lines - one, leaving the central aperture of the diaphragm, is fed at the pump inlet, the second, having passed the system of external heating devices, is sucked by the ejector into the near-axis region of the vortex chamber, thereby forming a closed hydraulic circuit.

The placement in the central part of the slot diffuser coaxial with the diaphragm opening of the additional flow supply pipe from the side opposite to the twisting device in combination with the involvement of a heated stream sucked by the ejector into the closed circuit ensures intense liquid circulation in the housing cavity, and the friction between rotating and shifting axially direction of the liquid layers is enhanced due to the influence of disturbances created by the introduction of an additional flow. As a result of the interaction of a complex of factors in a rotating fluid flow, the gradients of velocity change increase both in the transverse and in the longitudinal directions with respect to the vortex chamber body with the occurrence of reverse fluid currents in the axial zone with the subsequent exit of the heated fluid through the slot diffuser to the outlet of the heated fluid.

The invention is illustrated in figure 1, which presents a structural diagram of a device for heating an incompressible medium.

The hydraulic heat generator contains a vortex chamber 1, with a swirling flow nozzle device 2, a diaphragm with a central hole 3, a throttle 4 made in the form of a slot diffuser, in the central part of which, coaxial to the opening of the diaphragm 3, an additional flow supply pipe 5 is installed. The vortex chamber 1 is connected to pressure port 6 of pump 7, which is driven by electric motor 8. At the inlet to pump 7, valves 9 and 10 are installed to coordinate and regulate the operation of the entire device. The ends of the vortex chamber are equipped with lead screws with gland packing 11 and 12, which provide adjustment of its operation mode.

The operation of the device is as follows. First, the entire hydraulic circuit is filled with liquid through an expansion tank 13 so that an air cavity remains in the volume of the expansion tank to allow it to be further filled with liquid when it is heated. After filling the hydraulic circuit with liquid, voltage is applied to the electric motor 8, the pump 7 starts pumping the working fluid, for example water, through the spatial distribution system of the heat generator.

The fluid under pressure, flowing through the twisting device of the nozzle input, is fed into the vortex chamber of the pipe, and from the throttle side, an additional flow is introduced into its axial zone through the ejector 14. The working agent - liquid - rotates inside the vortex chamber of the pipe and heats up somewhat more due to friction in the peripheral layers, forming, mainly from additional masses in the axial zone, a reverse flow, and flows along a converging spiral through a central opening to the pump inlet. The working body of the pump sucks in the liquid and again pumps it through the swirling flow of the nozzle inlet and ejector into the vortex chamber of the pipe. A jet of liquid from the exit of the vortex chamber is sucked in with the aid of an ejector 14, and the heated liquid is drawn into the circulation. After heating the liquid to a predetermined temperature, an external valve opens behind the nozzle 15 and is discharged into the external heat exchange line 16. The heat gain to the system is composed of the thermal energy introduced by the electric motor power source and the energy injected by the vortex of the working agent through the penetrating fields. The total heating coefficient of the system is close to 1, i.e. the vortex heating system creates an increase in energy heat due to the injection of energy external to the system of fields by the vortex flow of the working agent. This injection is nonlinear, i.e. is determined by the second degree of linear and angular flow velocity.

Thus, the proposed device fulfills its purpose. Thanks to the use of a vortex chamber with an additional flow, which has high values of energy efficiency coefficients and the organization of the system in a closed cycle, it is possible to make the whole device much more compact, eliminating the evaporation of the working fluid and providing the possibility of using highly efficient liquid media that increase the heating rate and heating coefficient.

Claims (5)

1. A hydraulic heat generator, including an input swirling device connected to the housing of the vortex chamber, a pipe for discharging heated liquid, characterized in that it is provided on the side of the throttle with a paraxial central opening with a pipe for supplying additional masses of liquid to the axial region of the vortex chamber, the ends of which equipped with spindles with stuffing box seal, providing adjustment of operating modes. 2. The heat generator according to claim 1, characterized in that the end face of the vortex chamber, remote from the nozzle input, is equipped with a slot diffuser. 3. The heat generator according to claim 1 or 2, characterized in that the end face adjacent to the opening of the diaphragm is made in the form of a slot diffuser. 4. The heat generator according to claim 3, characterized in that the slot diffusers are combined with snail heads. 5. A fluid heating device comprising a hydraulic heat source, an electric motor pump connected to the body of the heat source, supply and return pipelines with shut-off valves, ensuring the relationship of the heat generator with heat exchangers, characterized in that the supply line is divided into two, one of which is directed to the screw the flow to the vortex chamber device, and the second through the ejector to its axial region, in addition, there are two exhaust lines - one, leaving the central aperture of the diaphragm, is fed at the pump inlet, the second, having passed the system of external heating devices, is sucked by the ejector into the near-axis region of the vortex chamber, thereby forming a closed hydraulic circuit.