CN114738994B - High-frequency electromagnetic built-in reheating type intelligent heating integrated device - Google Patents

Abstract

The invention is suitable for the technical field of heating equipment, and provides a high-frequency electromagnetic built-in regenerative intelligent heating integrated device which comprises a shell, wherein a heating cavity is formed in the shell, an electromagnetic heating pipe assembly with an open bottom end is vertically arranged in the heating cavity, and the top end of the electromagnetic heating pipe assembly is fixedly connected with the top of the inner wall of the heating cavity. This built-in intelligent heating integrative device of recuperative heat of high frequency electromagnetism sets up electromagnetic heating pipe subassembly through the inner chamber at the heating chamber, effectively rationally with solenoid built-in, after liquid or gaseous etc. enter into the heating chamber from the input tube, it is ascending to its bottom turn down, the magnetic field is produced after the solenoid circular telegram, the heating metal pipe generates heat under the magnetic field effect, liquid or gaseous in the heating metal pipe heats, because solenoid is placed in the heating chamber, its self-heating's temperature also is fully utilized, make the more abundant, high-efficient conversion of electric energy heat energy, electromagnetic heating effect and work efficiency have been improved.

Description

High-frequency electromagnetic built-in reheating type intelligent heating integrated device

Technical Field

The invention belongs to the technical field of heating equipment, and particularly relates to a high-frequency electromagnetic built-in regenerative intelligent heating integrated device.

Background

Electromagnetic heating is also called electromagnetic induction heating, namely electromagnetic heating technology, and the principle of electromagnetic heating is that an alternating magnetic field is generated through an electronic circuit board component part, when an iron-containing container is placed on the container, alternating magnetic force lines are cut on the surface of the container, alternating current (namely vortex) is generated at a metal part at the bottom of the container, the vortex enables carriers at the bottom of the container to randomly move at a high speed, and the carriers collide with atoms and rub with each other to generate heat energy, so that an effect of heating objects is achieved, and the iron-containing container generates heat by itself, so that the heat conversion rate is particularly high and can reach 95 percent at most.

In the prior art, the high-frequency electromagnetic heating device is characterized in that a high-frequency induction coil is directly wound on the periphery of a heating cylinder, after the high-frequency induction coil is electrified, the heating cylinder generates heat energy to heat liquid or gas and the like in the heating cylinder, so that the heating effect is achieved, but because the coil is arranged on the periphery of the heating cylinder, the temperature of the coil cannot be utilized, a lot of heat is lost intangibly, meanwhile, the internal structure of the heating cylinder is simple, the heat in the heating cylinder cannot be recycled, the use power is high, and the heating efficiency is low.

Disclosure of Invention

The invention provides a high-frequency electromagnetic built-in reheating type intelligent heating integrated device, and aims to solve the problems of high power and low heating efficiency caused by the fact that the temperature of a coil and the temperature in a heating barrel cannot be utilized in the prior art.

The invention discloses a high-frequency electromagnetic built-in reheating type intelligent heating integrated device, which comprises a shell, wherein a heating cavity is formed in the shell, an electromagnetic heating pipe assembly with an open bottom end is vertically arranged in the heating cavity, and the top end of the electromagnetic heating pipe assembly is fixedly connected with the top of the inner wall of the heating cavity;

the electromagnetic heating pipe assembly is internally and vertically provided with a superconducting assembly, the superconducting assembly comprises a hollow cylindrical superconducting cylinder, and superconducting liquid is arranged in the superconducting cylinder;

the top of the side wall of the heating cavity is communicated with an input pipe penetrating to the outside of the shell, and the top of the heating cavity is communicated with an output pipe penetrating to the outside of the shell;

one side of the shell is provided with a controller.

Preferably, the electromagnetic heating pipe assembly comprises a heating metal pipe and an electromagnetic coil, and the electromagnetic coil is arranged in the side wall of the heating metal pipe body in a surrounding mode.

Preferably, the electromagnetic heating pipe assembly comprises a heating metal pipe, an electromagnetic coil and an outer metal pipe, wherein the electromagnetic coil is arranged between the heating metal pipe and the outer metal pipe and surrounds the outer surface of the heating metal pipe.

Preferably, an annular plate for blocking the gap is arranged at the bottom end of the gap between the heating metal tube and the outer metal tube.

Preferably, superconducting brackets are respectively arranged on two sides of the inner wall of the heating metal tube, and the other end of each superconducting bracket is fixedly connected with the outer wall surface of the superconducting cylinder.

Preferably, a control panel is arranged on the surface of the controller, and a power line is arranged on the controller.

Preferably, a connecting wire is connected between the controller and the electromagnetic coil, and a wire slot for the connecting wire to run is formed in the inner cavity of the shell.

Preferably, the outer ends of the input pipe and the output pipe are both provided with connectors.

Preferably, the housing is made of an electromagnetic shielding material, and the surface of the housing is coated with a heat-insulating coating.

Advantageous effects

Compared with the prior art, the invention has the beneficial effects that:

(1) According to the high-frequency electromagnetic built-in reheating type intelligent heating integrated device, the electromagnetic heating pipe component is arranged in the inner cavity of the heating cavity, so that the electromagnetic coil is effectively and reasonably built-in, after liquid or gas and the like enter the heating cavity from the input pipe, the electromagnetic coil descends to the bottom of the heating cavity and ascends, a magnetic field is generated after the electromagnetic coil is electrified, the heating metal pipe heats, the liquid or gas in the heating metal pipe is heated, and the self-heating temperature of the electromagnetic coil is fully utilized due to the fact that the electromagnetic coil is placed in the heating cavity, so that electric energy is fully and efficiently converted into heat energy, and the electromagnetic heating effect and the working efficiency are improved.

(2) According to the high-frequency electromagnetic built-in reheating type intelligent heating integrated device, the superconducting assembly is arranged in the electromagnetic heating pipe assembly, after liquid or gas is heated by the electromagnetic heating pipe assembly, heat is conducted to superconducting liquid through the superconducting cylinder, the superconducting liquid can automatically and quickly heat up, heat is conducted to the liquid or gas through the superconducting cylinder, the heated area of the liquid or gas in the heating metal pipe is enlarged, the heating speed is increased, when the temperature of the liquid or gas reaches a control point, the power supply automatically returns to zero, at the moment, the superconducting assembly also has residual heat to keep heat storage, part of heat can be accumulated again when the power supply returns to zero when the power supply is electrified again, and the heat is repeatedly recovered, so that the heating effect of the device is extremely high-efficiency and energy-saving.

Drawings

FIG. 1 is a schematic elevational view in cross-section of the present invention;

FIG. 2 is a schematic diagram of an embodiment of the present invention;

FIG. 3 is a schematic view of an electromagnetic heating tube assembly according to the present invention;

FIG. 4 is a top view of an electromagnetic heating tube assembly and superconducting assembly of the present invention.

In the figure: 1-shell, 2-heating cavity, 3-heating metal pipe, 4-solenoid, 5-outer metal pipe, 6-superconductive tube, 7-superconductive liquid, 8-input tube, 9-output tube, 10-controller, 11-annular plate, 12-superconductive support, 13-control panel, 14-power cord, 15-connecting wire, 16-wire casing, 17-connector.

Detailed Description

The present invention will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present invention more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the invention.

Referring to fig. 1-4, the present invention provides a technical solution: the high-frequency electromagnetic built-in reheating type intelligent heating integrated device comprises a shell 1, wherein a heating cavity 2 is formed in the shell 1, an electromagnetic heating pipe assembly with an open bottom end is vertically arranged in the heating cavity 2, and the top end of the electromagnetic heating pipe assembly is fixedly connected with the top of the inner wall of the heating cavity 2;

the shell 1 is a vertically placed cuboid, the shell 1 can be placed on the ground, the shell 1 can be separated from the ground through the connecting component and fixedly installed on the wall, the cavity of the heating cavity 2 is hollow, the electromagnetic heating pipe component is integrally in a cylinder shape with an open bottom end, and the electromagnetic heating pipe component is communicated with the heating cavity 2 through the opening at the bottom end of the electromagnetic heating pipe component, so that liquid, gas and the like entering the heating cavity 2 can be better contacted with the electromagnetic heating pipe component, and the heating range of the electromagnetic heating pipe component is enlarged.

The electromagnetic heating pipe assembly is vertically provided with a superconducting assembly, the superconducting assembly comprises a hollow cylindrical superconducting cylinder 6, and superconducting liquid 7 is arranged in the superconducting cylinder 6;

after the liquid or gas enters the heating cavity 2 and is heated by the electromagnetic heating pipe component, heat is conducted to the superconducting liquid 7 through the superconducting cylinder 6, the superconducting liquid 7 can automatically and quickly heat up, heat is conducted to the liquid or gas through the superconducting cylinder 6 in a reverse mode, the heated area of the liquid or gas in the heating metal pipe 3 is enlarged, the heating speed is accelerated, when the temperature of the liquid or gas reaches a control point, the power supply automatically returns to zero, at the moment, the superconducting component also has residual heat to keep heat storage, part of heat can be accumulated again when the power supply is electrified for the second time, the heat storage is replenished again when the power supply returns to zero, and the heating effect of the device is extremely high, high efficiency and energy conservation.

The top of the side wall of the heating cavity 2 is communicated with an input pipe 8 penetrating to the outside of the shell 1, and the top of the heating cavity 2 is communicated with an output pipe 9 penetrating to the outside of the shell 1;

liquid or gas enters the heating cavity 2 through the input pipe 8, and is output to the outside of the shell 1 through the output pipe 9 after heating.

One side of the housing 1 is provided with a controller 10.

The controller 10 controls the rectifying circuit to convert the 50HZ/60HZ alternating current into direct current voltage, and then the direct current voltage is converted into high-frequency voltage with the frequency of 20KHZ-40KHZ through the control circuit, and the high-speed changing current can generate a high-speed changing magnetic field through the electromagnetic coil 4.

In this embodiment, the liquid or gas enters the heating cavity 2 through the input tube 8, goes down to the bottom thereof and goes up, the electromagnetic coil 4 in the electromagnetic heating tube assembly is electrified to generate a magnetic field, so that the heating metal tube 3 heats, the liquid or gas in the heating metal tube 3 heats, meanwhile, the heat is conducted to the superconducting liquid 7 through the superconducting tube 6, the superconducting liquid 7 automatically and rapidly heats up, the heat is conducted to the liquid or gas through the superconducting tube 6 again, the heated area of the liquid or gas in the heating metal tube 3 is enlarged, the heating speed is increased, when the temperature of the liquid or gas reaches a control point, the power supply automatically returns to zero, at this time, the superconducting assembly still has residual heat to keep accumulating heat, and when the power supply returns to zero again, part of heat can be accumulated again, so that the heat is reciprocally recovered, and finally the heated liquid or gas is output to the outside of the casing 1 through the output tube 9.

Further, the electromagnetic heating pipe assembly comprises a heating metal pipe 3 and an electromagnetic coil 4, and the electromagnetic coil 4 is arranged in the side wall of the heating metal pipe 3 in a surrounding mode.

As shown in fig. 1, in the present embodiment, when the electromagnetic coil 4 is energized, a magnetic field is generated, and the heating metal tube 3 generates heat by the magnetic field, thereby heating the liquid or gas in the heating metal tube 3.

The principle of the electromagnetic heating assembly is the prior art and will not be described in detail.

Further, the electromagnetic heating tube assembly comprises a heating metal tube 3, an electromagnetic coil 4 and an outer metal tube 5, wherein the electromagnetic coil 4 is arranged between the heating metal tube 3 and the outer metal tube 5 and surrounds the outer surface of the heating metal tube 3.

As shown in fig. 2, in this embodiment, the outer metal tube 5 is sleeved outside the heating metal tube 3, the electromagnetic coil 4 is circumferentially disposed on the outer surface of the heating metal tube 3, and the electromagnetic coil 4 can be protected by the outer metal tube 5, so that the electromagnetic coil 4 is prevented from being directly exposed in water, and meanwhile, the electromagnetic coil 4 is disposed in a gap between the heating metal tube 3 and the outer metal tube 5, so that the installation difficulty of the electromagnetic coil 4 is reduced.

Further, an annular plate 11 for blocking the gap is provided at the bottom end of the gap between the heating metal tube 3 and the outer metal tube 5.

In the present embodiment, the gap between the heating metal tube 3 and the outer metal tube 5 can be blocked by providing the annular plate 11, so that the electromagnetic coil 4 in the gap is prevented from contacting water, and the service life of the electromagnetic coil 4 is prolonged.

Further, two sides of the inner wall of the heating metal tube 3 are respectively provided with a superconducting bracket 12, and the other end of the superconducting bracket 12 is fixedly connected with the outer wall surface of the superconducting cylinder 6.

In the present embodiment, the number of superconducting brackets 12 is four or more, and the superconducting brackets 12 are fixedly connected to both sides and both ends of one side of the superconducting cylinder 6, respectively, so that the superconducting assembly can be fixed to the heating metal tube 3 by providing the superconducting brackets 12, thereby avoiding displacement of the superconducting assembly.

Further, a control panel 13 is disposed on the surface of the controller 10, and a power cord 14 is disposed on the controller 10.

In the present embodiment, the control panel 13 is provided with a display, keys, etc., and the controller 10 is provided with a power line 14, and the controller 10 can be supplied with power by connecting the power line 14 to a power source.

Further, a connecting wire 15 is connected between the controller 10 and the electromagnetic coil 4, and a wire slot 16 for routing the connecting wire 15 is arranged in the inner cavity of the housing 1.

In this embodiment, through setting up connecting wire 15, the electric current is conducted to solenoid 4 through connecting wire 15, makes solenoid 4 produce the magnetic field of high-speed variation, opens wire casing 16 in the inner chamber of shell 1 and makes things convenient for connecting wire 15 to walk the line.

Further, the outer ends of the input pipe 8 and the output pipe 9 are respectively provided with a connector 17.

In the present embodiment, the input pipe 8 and the output pipe 9 can be connected to other connection components by providing the connection head 17, respectively, so that liquid, gas, or the like can be more efficiently input and output.

Further, the housing 1 is made of an electromagnetic shielding material, and the surface of the housing 1 is coated with a heat-insulating coating.

In the embodiment, the surface of the shell 1 is coated with a layer of nano-scale ceramic heat insulation coating with the thickness of 1.5 mm, so that the shell 1 is not easy to dissipate heat during heat insulation, and the heat dissipation in the shell 1 is avoided.

The working principle and the using flow of the invention are as follows: after the invention is installed, liquid or gas enters the heating cavity 2 through the input pipe 8, flows downwards to the bottom of the heating cavity and flows upwards, the electromagnetic coil 4 is electrified to generate a magnetic field, the heating metal pipe 3 heats the liquid or gas in the heating metal pipe 3, meanwhile, the heat is conducted to the superconducting liquid 7 through the superconducting cylinder 6, the superconducting liquid 7 automatically and rapidly heats up, the heat is conducted to the liquid or gas through the superconducting cylinder 6 reversely, the heating area of the liquid or gas in the heating metal pipe 3 is enlarged, so as to accelerate the heating speed, when the temperature of the liquid or gas reaches a control point, the power supply automatically returns to zero, at the moment, the superconducting component also has residual temperature to keep heat storage, part of heat can be accumulated again when the power supply returns to zero, the heat is replenished again when the power supply returns to zero, and finally the heated liquid or gas is output to the outside of the shell 1 through the output pipe 9.

The foregoing description of the preferred embodiments of the invention is not intended to be limiting, but rather is intended to cover all modifications, equivalents, and alternatives falling within the spirit and principles of the invention.

Claims (6)

1. The utility model provides a built-in compound hot type intelligent heating integrative device of high frequency electromagnetism which characterized in that: the electromagnetic heating device comprises a shell (1), wherein a heating cavity (2) is formed in the shell (1), an electromagnetic heating pipe assembly with an open bottom end is vertically arranged in the heating cavity (2), and the top end of the electromagnetic heating pipe assembly is fixedly connected with the top of the inner wall of the heating cavity (2);

the electromagnetic heating pipe assembly is vertically provided with a superconducting assembly, the superconducting assembly comprises a hollow cylindrical superconducting cylinder (6), and superconducting liquid (7) is arranged in the superconducting cylinder (6);

the top of the side wall of the heating cavity (2) is communicated with an input pipe (8) penetrating to the outside of the shell (1), and the top of the heating cavity (2) is communicated with an output pipe (9) penetrating to the outside of the shell (1);

a controller (10) is arranged on one side of the shell (1);

the electromagnetic heating pipe assembly comprises a heating metal pipe (3), an electromagnetic coil (4) and an outer metal pipe (5), wherein the electromagnetic coil (4) is arranged between the heating metal pipe (3) and the outer metal pipe (5) and is circumferentially arranged on the outer surface of the heating metal pipe (3);

the bottom end of the gap between the heating metal tube (3) and the outer metal tube (5) is provided with an annular plate (11) for blocking the gap.

2. The integrated high-frequency electromagnetic built-in regenerative intelligent heating device as set forth in claim 1, wherein: the two sides of the inner wall of the heating metal tube (3) are respectively provided with a superconducting bracket (12), and the other end of the superconducting bracket (12) is fixedly connected with the outer wall surface of the superconducting cylinder (6).

3. The integrated high-frequency electromagnetic built-in regenerative intelligent heating device as set forth in claim 1, wherein: the surface of the controller (10) is provided with a control panel (13), and the controller (10) is provided with a power line (14).

4. The integrated high-frequency electromagnetic built-in regenerative intelligent heating device as set forth in claim 1, wherein: a connecting wire (15) is connected between the controller (10) and the electromagnetic coil (4), and a wire slot (16) for the connecting wire (15) to run is arranged in the inner cavity of the shell (1).

5. The integrated high-frequency electromagnetic built-in regenerative intelligent heating device as set forth in claim 1, wherein: the outer ends of the input pipe (8) and the output pipe (9) are respectively provided with a connector (17).

6. The integrated high-frequency electromagnetic built-in regenerative intelligent heating device as set forth in claim 1, wherein: the shell (1) is made of electromagnetic shielding materials, and the surface of the shell (1) is coated with a heat preservation coating.