RU55104U1 - HEAT PUMP (OPTIONS) - Google Patents

Abstract

A useful model relates to the field of power engineering - to designs of heat-generating pumps that convert mechanical motion energy into heat energy, which can be used to heat the coolant mainly in autonomous closed-loop heat supply systems of residential, public and industrial buildings, and to heat structures and installations.

The device is a heat pump, which can be set together with the drive (electric motor) on the frame with the ability to move the unit, made (options) both single and multi-stage, having a hollow body with an inlet suction pipe for the heated coolant and an outlet discharge pipe for the removal of the heated coolant equipped with a load valve - pressure regulator, containing inside the housing pairwise alternating stators and coaxially placed with the possibility of rotation on the shaft of driving a working rotor wheel for supplying coolant and rotors forming a means of influencing the coolant to heat it, on the peripheral part of the disks of which the blades are radially mounted, both single-sided and bilateral.

Description

A useful model relates to the designs of heat-generating pumps that convert mechanical energy into heat, which are used to heat the coolant, mainly in stand-alone closed heat supply systems of residential, public and industrial buildings, heating structures, plants and devices.

Currently, heat pumps are increasingly being used as heat generators. Known devices of heat pumps using changes in the physicomechanical parameters of heat carriers, in particular pressure, volume and speed, to produce thermal energy.

Known: a heater of liquid (water) coolant containing a chamber with a liquid, equipped with nozzles for supplying and discharging a heated fluid and a rotor installed in the chamber in the form of perforated disks fixed to the shaft, and pairs of stationary perforated disks additionally fixed in the chamber, between which a corresponding rotor disk is mounted with the formation of a gap for the passage of fluid [RF Patent No. 2094711 from 08/17/1995 IPC F 24 J 3/00, publ. 10/27/1997]; a heat pump, comprising a hollow body, a rotor cantileverly mounted inside it on the rotational drive shaft, a suction pipe located coaxially with the rotor and opposite to it, and a discharge pipe, a stator in the form

at least two perforated rings concentrically arranged to form annular gaps, the rotor being made in the form of a disk provided with at least one perforated ring, while the perforated ring or perforated rotor rings are also located in the annular gaps between the perforated stator rings with a gap, a, the discharge pipe is made radially to the housing [Cert. RF №25929 dated 05/14/2002, IPC F 24 J 3/00, publ. 10.27.2002].

The disadvantage of such heating pumps is unstable heating capacity and excessive hydraulic and other losses due to periodic sharp interruption of the fluid flow when it passes through the holes of perforated disks (rings).

A heat pump is known, comprising a housing with inlet and outlet nozzles, inside which a rotor wheel is mounted rotatably from the drive, made in the form of a disk having a cavity with blades and a peripheral part with channels, and axial cylindrical resonators are made in the peripheral part of the rotor wheel, the channels of the peripheral part of the rotor wheel are made in the form of input to the resonators, output from the resonator sections, the input sections of the channels are located tangentially to the resonators, and the output is glad cial [Testimonies. RF №23098 dated 11/09/2001, IPC F 24 J 3/00, F 25 V 30/00, publ. 05/20/2002].

At the same time, although the design of the rotor wheel in the form of a disk with blades improves the hydraulic power of such a heat pump, however, the inclusion of an intricate configuration of a set of resonators in the system of mechanical action on the liquid (water) complicates the manufacture and requires a certain preliminary adjustment of the system (selection of dimensions and configuration elements).

The claimed utility model is aimed at solving the technical problem: obtaining thermal energy from the coolant when implementing high-speed dynamic reorientation of the molecular structures of the coolant and achieving the conditions for the transfer of the kinetic energy of these structures into thermal energy, as well as the use of the energy of the accompanying factor - cavitation.

The technical problem is solved by means of the proposed utility model of a heat pump, the casing of which is exposed on the frame together with the drive (electric motor), with the possibility of moving the unit, is equipped externally with an inlet suction pipe and an outlet discharge pipe equipped with a load valve-pressure regulator, inside the heat pump casing on the shaft a rotary impeller is arranged for rotation of the drive for supplying the coolant, and a means of influencing the coolant paired with it heating - a stator (a variant of a single-stage heat pump), which is an impeller made in the form of an annular disk, on the peripheral part of which there are radially mounted blades having an angle of inclination of the blades to the plane of the disk from 90 ° to 80 °, while the annular gap between the stator and the working the rotor wheel has a width of not more than 0.5 mm,

In the embodiment of a multi-stage heat pump (two or more stages), in addition to the drive shaft with the possibility of rotation, two or more rotors are paired coaxially with stators made in the form of disks, moreover, the stators are made in the form of ring disks with a central hole for the coolant passage , on the peripheral part of the stators and rotors, blades are installed radially and perpendicular to the plane of the disks, with the formation of annular gaps between adjacent stators and rotors and the working rotor wheel of a width not more than 0.5 mm. Impeller for pressure

coolant flow, adjacent rotors and stators with vanes acting on the coolant provide heat reproducibility. In this case, the rotors and stators, forming a means of influencing the coolant to heat it, can have both unilateral and bilateral installation of the blades, the angle of inclination of the blades to the plane of the disks from 90 ° to 80 °.

The execution of stators and rotors in the form of alternating coaxial disks with numerous blades mounted on them, acts as a shaper of the coolant vortex structures in the space between the rotors, where the formation of a vortex flow occurs. Due to the fact that the blades mounted on the surfaces of the disks of the rotors and stators are facing each other, with the formation of an annular gap with a width of not more than 0.5 mm, between the rotors and the stators, in the opposite recesses formed by the blades and the surfaces of the disks, clumping chambers are created that form the formation of microvortices, during the collapse of which thermal energy is released, which causes heating of the coolant.

The design of heat pumps, in particular the presence of an annular gap up to 0.5 mm wide, between the rotors and stators, the installation of blades at an angle to the plane of the disks from 90 ° to 80 °, is aimed at the formation of a cavitation phenomenon, that is, at provoking discontinuity inside transported fluid - coolant, ensuring comprehensive stretching of the fluid. At the same time, gas bubbles, steam or mixtures present in the liquid acquire the ability to turn into large "cavitation bubbles", as a result of local pressure reduction in a rapidly moving liquid. Moving with the flow, the bubbles fall into the region with a pressure above the critical pressure, where they contract and disappear. The process of contraction of the cavitation bubble at the zone boundary occurs

with a very high speed and is accompanied by a kind of hydraulic shock and the release of thermal energy.

Placing the blades on the disks with the angle of inclination of the blades to the plane of the disks of rotors and stators from 90 ° to 80 ° improves the conditions for the formation of cavitation zones - collapse chambers. Typically, the blades in the pumps are perpendicular, that is, at an angle of 90 °, to ensure maximum fluid flow. Placing the blades on disks with a 10 ° deviation from the perpendicular of the blades, contributing to an increase in heat dissipation, provides the necessary fluid supply, which decreases with increasing angles of inclination of the blades, that is, beyond the specified interval. The width of the annular gap of not more than 0.5 mm is selected from that calculation to ensure the free rotation of the rotor (rotor wheel), preventing its contact with the stator, while simultaneously exerting local influence on the liquid for its full extension.

The creation and use of the energy of the accompanying factor-cavitation is facilitated by macro-roughness on the surface of the disks of stators and rotors and blades mounted on them.

The technical solution is illustrated by examples of its implementation. The drawings show: figure 1 - General diagram of a heat pump; figure 2 is a diagram of a multi-stage heat pump; figure 3 is a diagram of the pairing of the working rotor wheel and the stator; figure 4 a) is a General view of the working rotor wheel or rotor (section); figure 4 b) is a General view of the stator (section).

The heat pump is installed on the frame 1, has a drive (electric motor) 2, contains a housing 3, an inlet suction pipe 4 and an outlet discharge pipe 5, a rotor wheel 7, rotors 8 and stators 9, on which the blades 10 are mounted, are located on the drive shaft 6 load valve - regulator 11.

The device operates as follows. The coolant through the inlet suction pipe 4 enters the cylindrical cavity of the housing 3. The impeller rotor 7 and the rotors 8 rotate together with the shaft 6 of the electric drive 2 at a speed (speed) of up to 3000 rpm. In this case, the coolant comes into rotation in the cavity of the casing 3. Microvortices arise in the collapse chambers, during the collapse of which the hydraulic energy of the microvortices passes into thermal energy. When the working rotor wheel 7 and rotors 8 rotate, the coolant in the cavity of the casing 3 is pressed from the shaft 6 to the periphery of the cavity under the influence of centrifugal forces, forming a zone of high pressure. Thus in the area of the shaft 6 creates a zone of reduced pressure. The coolant is sucked into this zone from the high-pressure zone, where microvortexes coagulate and, accordingly, step by step, mix the sucked-in heated coolant with the coolant entering the heat pump. The hot coolant is supplied to the consumer through the outlet discharge pipe. Preheating (starting warming up) is preferably carried out in a closed mode of its circulation without removal of thermal energy to the consumer, with subsequent regulation of the flow, through the load control valve 11.

Real tests of full-scale samples of heat pumps manufactured under production conditions, both single and multi-stage (3 and 5 stage), with annular gaps of 0.3 and 0.5 mm, with the angle of inclination of the blades to the plane of the disk 90 ° and 80 ° , confirmed the effectiveness of such a design of heat pumps. With a decrease in the angle of inclination of the blades to the plane of the disk less than 80 °, and with an increase in the annular gap of more than 0.5 mm, the flow rate and pressure of the liquid significantly decreased, and as a result, the heat generation efficiency, in particular, the temperature, decreased, ceteris paribus exit from the heat pump.

Example. Under equal conditions, the efficiency of the same heat pump was compared using interchangeable disks with different angles of inclination of the blades and changing the annular gap, while maintaining approximately the same energy consumption and the number of revolutions of the electric motor, the volumetric flow of the coolant and its temperature (coolant) at the inlet to the heat pump (table):

The angle of the blade a, degrees. 70 80 90 Ring gap d, mm 0.3-0.5 one Heat carrier temperature Т _out , ° С 75 95-100 one hundred 85 The pressure at the outlet P _o , kgf / cm ² 1.2-1.2 1.1-1.0 1,0 1,0

In this case, the perpendicular arrangement of the blades on the disk (the angle of inclination is 90 °) and the annular gap of 0.5 mm provide the highest temperature at the outlet of the heat pump. An increase in the annular gap (up to 1 mm) reduces the temperature of the coolant. Also, there is a decrease in heat dissipation efficiency when the angle of inclination of the blades on the disk changes to 70 °, - the temperature of the coolant at the outlet of the heat pump decreased from 100 to 75 ° C. Within the angle of inclination of the blades from 90-80 °, the heat release efficiency remains at the same level (the temperature of the coolant at the outlet of the heat pump was 100-95 ° C).

The heat pump is simple in hydraulic circuit and simple to manufacture, using, for example, individual standard components directly on the basis of single and multistage centrifugal pumps. By changing the dimensions of the casing (standard size), the corresponding diameter of the impeller, rotor and stator, the number of steps - alternating rotors and stators placed in pairs on the shaft, the annular gap between them, as well as changing the number and dimensions of the blades, the angle of the blades to the plane of the disk, from 90 ° to 80 °, the heat pump can be performed as single-stage or multi-stage, with different heat and discharge capacities, and the presence of a pressure regulating valve on the outlet nozzle allows you to adjust the discharge pressure Niya. In this case, it is preferable to use discs and blades mounted on them with an unprocessed surface, having macro roughness. The use of blades of a simple configuration allows us to use not only traditional water, but also oils, oil and bitumen, including with mechanical inclusions, as a coolant, for the purpose of creating installations for their heating, for example, in tanks

Claims (8)

1. A heat pump, consisting of a hollow body, equipped with an inlet suction pipe for the heated coolant and an outlet discharge pipe for the removal of the heated coolant, set together with the electric drive on the frame, containing inside the housing, rotary impeller and coaxially placed inside the housing, rotatable on the drive shaft stator, forming annular gaps between themselves, characterized in that the stator is an impeller made in the form of an annular disk, on the peripheral part of which The blades are mounted flaxly, having an angle of inclination of the blades to the plane of the disk from 90 to 80 °, while the annular gap between the stator and the rotor wheel has a width of not more than 0.5 mm. 2. The heat pump according to claim 1, characterized in that the rotors and stators can have on the disk both one-sided and two-sided installation of the blades. 3. The heat pump according to claim 1, characterized in that the outlet discharge pipe is equipped with a pressure control valve-pressure regulator. 4. The heat pump according to claim 1, characterized in that the frame is set together with an electric motor with the ability to move as a unit. 5. A heat pump, consisting of a hollow body, equipped with an inlet suction pipe for the heated coolant and an outlet discharge pipe for the removal of the heated coolant, set together with the electric drive on the frame, containing inside the housing, rotary impeller and coaxially placed inside the housing, rotatable on the drive shaft a stator forming an annular gap, characterized in that n e is additionally equipped with two or more pairs of alternating installed coaxially, stators and rotors, e taken nna x on the rotary shaft of the drive, which are impellers made in the form of annular disks, on the peripheral part of which are blades radially mounted having an angle of inclination of the blades to the plane of the disc from 90 to 80 °, with an annular gap between the rotor impeller, rotors and stators has a width of not more than 0.5 mm. 6. The heat pump according to claim 5, characterized in that the rotors and stators can have both one-sided and two-sided blade installation on the disk. 7. The heat pump according to claim 5, characterized in that the outlet discharge pipe is equipped with a pressure control valve-pressure regulator. 8. The heat pump according to claim 5, characterized in that the frame is set together with an electric motor with the ability to move as a unit.