RU148067U1 - SOURCE OF HEAT ENERGY - Google Patents

Abstract

1. A source of thermal energy, characterized in that it includes an electric circulating pump with a wet rotor, comprising a stator, a separation cup, a rotor on the shaft, with an impeller at one end, and a casing, characterized in that the casing is provided with an inlet channel joined inside housing, through a small movable gap with an impeller, with at least one rigidly fixed to it, with numerous through passages and / or holes, a rotating partition that divides the internal cavity of the housing into the pressure part from ystviya impeller and an adjacent portion with a mechanical coolant temperature increase, for further transmission to the output kanal.2. The device according to claim 1, characterized in that a cavity with a coolant is made outside the stator, fitting and in contact with it, for preliminary heat removal and supply to the input channel. A device according to any one of claims 1 and 2, characterized in that in the divided cavities of the casing, stationary dampers of rotational motion of the coolant are made. 4. A device according to any one of claims 1 to 3, characterized in that the rotating partition is made in the form of a disk and / or surface of revolution.

Description

The claimed utility model relates to mechanical engineering in the field of thermal energy, as an effective source of thermal energy or an effective source of heat supply when converting electric energy into heat, and can be used for heating residential, office and other premises, as well as in greenhouses, drying warehouses and various technological processes.

The prior art devices are not known.

However, such sources of thermal energy are known as disk heat generators for converting electrical energy into thermal energy of a liquid heat carrier (utility model RU 73457) driven by a separate electric motor, consisting of disks with holes in a separate hollow body and a separate circulation pump that moves this fluid through the specified housing. At the same time, there is a close analogue as a drive, containing an electric circulating pump with a wet rotor (“Pump alphabet” WILO, DORTMUND 2006, p. 25, sectional drawing), containing a stator, a separation cup, a rotor on a shaft with an impeller at one end and a housing .

Known sources of thermal energy have significant drawbacks: large dimensions, complex and multi-node structures that require constant maintenance, their noisy work, as well as low efficiency, which do not allow to expand their scope with simultaneous saving of materials and energy resources.

The main reasons that impede the obtaining of the technical result of the claimed utility model are separate and multi-nodal execution of the analog design, irrationality of the layout, high material consumption, which leads to losses of electric and thermal energy and its noisy operation, and also leads to large dimensions.

The tasks to which the proposed utility model is aimed are: a multiple reduction in size, simplification of the design, a multiple reduction in noise during their operation, as well as a significant increase in efficiency, while expanding the scope of application, saving materials and energy resources.

The technical result is achieved due to the fact that: 1. The proposed source of thermal energy includes an electric circulation pump with a wet rotor containing a stator, a separation cup, a rotor on the shaft, with an impeller at one end, and a housing with an input channel made in it, which is docked inside the housing, through a small movable gap with an impeller, with at least one rigidly fixed to it, with numerous through passages and / or holes, a rotating partition separating the internal cavity of the housing and the pressure part from the action of the impeller and the adjacent part, with a mechanical increase in the temperature of the coolant, for further passage into the outlet channel.

In this embodiment of the thermal energy source, most of the heat from the heating of the stator windings is dissipated into the heated local environment, and a smaller part passes into the heat carrier.

2. Here, an improved technical result is achieved by the fact that the proposed source of thermal energy includes an electric circulating pump with a wet rotor containing a stator, a separation cup, a rotor on the shaft, with an impeller at one end, and a housing with a made cavity for the coolant, which is tight and in contact with outside the stator for preliminary heat removal and supply to the input channel, which is docked inside the housing, through a small movable gap with the impeller, with at least one rigidly fixed to it, with many numbered through passages and / or holes, a rotating partition separating the internal cavity of the housing into the pressure part from the action of the impeller and the adjacent part, with a mechanical increase in the temperature of the coolant, for further passage into the outlet channel.

In this embodiment, the source of thermal energy, most of the heat from heating the windings passes into the coolant through the cavity, fitting and in contact with the outside of the stator.

3. Achievable technical result is obtained due to the fact that the proposed source of thermal energy includes an electric circulation pump with a wet rotor containing a stator, a separation cup, a rotor on the shaft, with an impeller at one end, and a housing with a cavity made with a coolant that hugs and contacts from the outside of the stator for preliminary heat removal and supply to the input channel, which is docked inside the housing, through a small movable gap with the impeller, with at least one rigidly fixed to it, with m by counting through passages and / or openings, a rotating partition separating the internal cavity of the housing into the pressure part from the action of the impeller and the adjacent part, with a mechanical increase in the temperature of the coolant, for further passage into the outlet channel, while the stationary radial rotary dampers are made in the divided cavities of the housing coolant. In this embodiment, the thermal energy source additionally transfers the mechanical energy of the rotating fluid into the coolant, which is converted into heat after braking it in stationary dampers.

4. The proposed source of thermal energy includes an electric circulating pump with a wet rotor containing a stator, a separation cup, a rotor on the shaft, with an impeller at one end, and a housing with a cavity made with a coolant, fitting and contacting the outside of the stator for preliminary heat removal and supply to the inlet channel, which is docked inside the housing, through a small movable gap with the impeller, with at least one rigidly fixed to it, with numerous through passages and / or holes, rotating Xia partition in the form of a disk and / or rotation of the surface separating the inner cavity of the housing on the pressure portion of the impeller and the adjacent part of the action with a mechanical coolant temperature increase, for the further passage of the exit channel, wherein in divided cavities formed fixed radial dampers

In this case, the execution of the source of thermal energy, when performing at least one rotating partition in the form of a disk, as the simplest option, and / or surface of rotation, for example, a truncated surface of the cone - with a larger surface with many through passages and / or holes allows you to optimally receive heat from friction with the coolant. It is possible to perform the surface of rotation in a curved form along the section line with a plane passing through the axis of rotation, which will increase the friction area in comparison with the conical surface. All static, including the size, quantity, location and configuration of the passages and / or holes of the rotating partitions, and the dynamic parameters of the device are know-how, and the principle of operation in the mathematical description, together with the presentation parameters, are protected by separate copyright.

The technical result that provides the above set of features is: reduction in size, simplification of design, reduction of noise during their operation, as well as increased efficiency, to expand the scope with simultaneous saving of materials and energy resources.

In the proposed utility model, all results, including technical, are achieved by combining all the functions performed by three separate units: a drive motor, a hydrodynamic unit and a circulation pump, in a single circulation pump with a wet rotor and with a cylindrical housing containing a stator, a separation a glass, a rotor on a shaft with an impeller at one end and a housing from the outside of which is made direct or in the form of a tight cavity contacting on the outside of the stator, the inlet channel, joint inside, through a small gap with an impeller, and with at least one with numerous through passages and / or holes rigidly fixed to it, a rotating partition in the form of a disk and / or surface of revolution, for passing the return coolant flow into the outlet channel, while in the cavities there are fixed dampers of rotational motion of the coolant.

In the proposed device, there is no need to use any other sources of thermal energy, moreover, the generation and forced circulation of the coolant directly at the location of the consumer occurs simultaneously. Here, the supplied and consumed electrical energy is completely converted into thermal energy, through mechanical, induction and hydrodynamic components directly into the coolant and into the surrounding heated local environment, with simultaneous forced circulation along the circuit or equalization of the temperature of the entire heating system at the location of the consumer.

Brief description of the drawing.

The thermal energy source, according to the sectional drawing, includes an electric circulating pump with a wet rotor, comprising a stator 1, a separation cup 2, a rotor on a shaft 3 with an impeller 4 at one end, and a housing 5; an input channel 6 connected to the outside inside the housing 5, through a small movable gap 7 with an impeller, with at least one rigidly fixed to it, with numerous through passages and / or holes, a rotating partition 8 that separates the internal cavity of the housing into the pressure part 9 from the action of the impeller and adjacent part 10, with a mechanical increase in the temperature of the coolant, for further passage into the output channel 11.

2. The device according to p. 1, characterized in that from the outside of the stator there is a cavity 12 with a coolant, tight and in contact with the stator, for preliminary heat removal and supply to the input channel.

3. The device according to p. 1, 2, characterized in that in the separated cavities made stationary radial dampers 13 of the rotational movement of the coolant.

4. The device according to p. 1, 2, 3, characterized in that the rotating partition is made in the form of a disk 8 and / or surface of revolution 14.

To complete the presentation of the proposed technical solution, the drawing shows a sealing ring 15 between the housing and the dividing glass of the electric motor with a wet rotor. Also shown is a terminal board 16 for the electrical power of the device of the invention.

The circuit with the inlet channel 12 in the form of a cochlea with a cavity in contact on the outside of the stator is shown separately by dashed lines. Solid arrows show the direction of movement of the coolant during operation of this heat source according to option 1, or without cavity 12, for example, in the form of a cochlea surrounding the stator. In the case of the proposed device according to the second embodiment, the inlet channel 6 can be moved to the beginning of the cavity adjacent to the outside of the stator, the drawing shows dashed circles of the outer and inner walls from the end, and the flow direction of the coolant is shown by broken arrows.

Implementation of a utility model.

The device operates as follows. Through the terminal box 16, electric energy is supplied to the stator windings of the electric motor, as a result of which the rotor rotates on the shaft 3 from the stator 1 of the circulation pump, through the separation cup 2 with the wet rotor, which in turn drives the impeller 4 and at least one with numerous through passages and / or holes, a rotating partition 8, which in turn divides the internal cavity of the housing into a pressure part 9 and an adjacent part 10 for further passage of the coolant into the output al impeller 11. With pump 4 is pressurized or liquid head between the partition 8 and rotating the left wall of the cylindrical body 5. The coolant flows through the inlet channel 6, or alternatively on the input channel through the fitting cavity 12, and contacting at the outer side of the stator. From the inlet channel 6, docked inside the housing, through a small gap 7 with the impeller, the liquid enters the pressure cavity, from where it passes through the passages and / or openings of the rotating partition 8, where it heats up when the flow is cut off by many holes to a certain temperature and passes into the outlet channel 11 with increased thermal energy.

In the case of the third variant of operation of the proposed device, where the stationary damper 13, rotational motion of the coolant are made in the divided cavities of the housing, it is mechanically braked or kinetic energy of the synchronous rotation of the liquid into heat is converted and additional thermal energy is transferred to the flow in the output channel.

When the proposed device, each of the options 1, 2, 3 and 4, increases the efficiency of the source of thermal energy when it is removed by the coolant, followed by simultaneous and forced supply to the consumer. Similar, with complex functions, sources of thermal energy have not been identified.

Since, according to the technical documentation of wet rotor circulation pumps, the stator windings are partially cooled by liquid between the separation cup and the wet rotor, all types of heat losses of classical electric motors in our design go to increase the temperature of the coolant and are summed when passing the proposed heat source in the output channel energy. On this basis, the effectiveness of the proposed source of thermal energy is higher than that of existing devices from the prior art.

The given device of a source of thermal energy is new, it is not known before, it is industrially applicable and safe to use when used on the basis of certified circulation pumps with a wet rotor.

Information sources:

1. "Device for receiving thermal energy" utility model RU 73457, Urpin K.V., Nikitsky V.P.

2. “Pumping Alphabet” WILO, Dortmund 2006, p. 25, sectional drawing.

Claims (4)

1. A source of thermal energy, characterized in that it includes an electric circulating pump with a wet rotor, comprising a stator, a separation cup, a rotor on the shaft, with an impeller at one end, and a casing, characterized in that the casing is provided with an inlet channel joined inside housing, through a small movable gap with an impeller, with at least one rigidly fixed to it, with numerous through passages and / or holes, a rotating partition that divides the internal cavity of the housing into the pressure part from ystviya impeller and an adjacent portion with a mechanical coolant temperature increase, for further passage to the outlet passage. 2. The device according to p. 1, characterized in that on the outside of the stator there is a cavity with a coolant, fitting and in contact with it, for preliminary heat removal and supply to the input channel. 3. The device according to any one of claims 1 and 2, characterized in that in the divided cavities of the casing, stationary dampers of rotational motion of the coolant are made. 4. The device according to any one of claims 1 to 3, characterized in that the rotating partition is made in the form of a disk and / or surface of revolution.

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