CN216159346U - Heating body water cooling device of electromagnetic heating stove - Google Patents

Abstract

The utility model relates to the relevant technical field of electromagnetic heating stoves, in particular to a water cooling device for a heating body of an electromagnetic heating stove, which comprises a water cooling mechanism, a heat exchanger and a thermoelectric generator, wherein the water cooling mechanism is connected with the heat exchanger and a water pump through a water pipe, the coupling surface of the heat exchanger is tightly attached to the thermoelectric generator, and the thermoelectric generator is electrically connected with a storage battery; the water cooling mechanism is sleeved outside the heating body, the inner wall of the water cooling mechanism is a heat-conducting plate, and the heat-conducting plate is close to the electromagnetic coil of the heating body. The utility model can convert the redundant heat into electric energy for storage and standby, and effectively and quickly reduce the temperature of the heating body of the electromagnetic heating furnace.

Description

Heating body water cooling device of electromagnetic heating stove

Technical Field

The utility model relates to the technical field of electromagnetic heating stoves, in particular to a water cooling device for a heating body of an electromagnetic heating stove.

Background

The electromagnetic heating stove adopts the electromagnetic principle, namely, the heat energy generated by the eddy current generated by cutting metal by magnetic lines is used as a heat source, and the heat energy is transmitted to a heat dissipation system (such as a water heating system) so as to achieve the purpose of heating. The electromagnetic heating furnace is of a heating body structure, and the outermost side of the heating body structure is provided with an electromagnetic coil; the second layer is an insulating resin tube layer; the third layer is a heat insulation layer; the fourth layer is a heated iron pipe, and the inside is circulating water needing to be heated. In the working process of the heating body of the electromagnetic heating furnace, the distance between the electromagnetic coil and the heated iron pipe is about 20mm, and a large amount of heat is taken away by liquid after the iron pipe is heated. But a small amount of heat will be conducted through the insulation layer to the electromagnetic coil. When the electromagnetic coil continuously operates for a long time, the electromagnetic coil can generate certain heat, and the temperature rises by about 80-100 ℃. The heated iron pipe of the fourth layer can conduct a large amount of heat energy to the water inside, but a small amount of heat energy is conducted to the electromagnetic coil through the heat insulation layer, so that the temperature of the coil is continuously increased. Therefore, the heating body needs to be subjected to heat dissipation treatment, so that the temperature of the heating body is in a stable safety range.

The cooling device of the heating body of the existing electromagnetic heating stove mostly adopts air cooling or water cooling, the cooling effect of a water cooling mechanism is poor, the efficiency is low, and the redundant heat is wasted.

SUMMERY OF THE UTILITY MODEL

Aiming at the problem of the water cooling device for the heating body of the electromagnetic heating furnace at present, the utility model provides the water cooling device for the heating body of the electromagnetic heating furnace, which realizes the purpose of converting redundant heat into electric energy for storage and standby, and effectively and quickly reducing the temperature of the heating body of the electromagnetic heating furnace.

The technical scheme provided by the utility model is as follows: a heating body water cooling device of an electromagnetic heating furnace comprises a water cooling mechanism, a heat exchanger and a thermoelectric generator, wherein the water cooling mechanism is connected with the heat exchanger and a water pump through a water pipe, a coupling surface of the heat exchanger is tightly attached to the thermoelectric generator, and the thermoelectric generator is electrically connected with a storage battery; the water cooling mechanism is sleeved outside the heating body, the inner wall of the water cooling mechanism is a heat conducting plate, and the heat conducting plate is close to the electromagnetic coil of the heating body; the water cooling mechanism is hollow, an upper water storage cavity and a lower water collecting cavity are separated by a partition plate in a horizontal sealing mode, the water storage cavity is provided with an upper water inlet and is connected with the water pump, and the water collecting cavity is provided with a lower water outlet and is connected with a water inlet of the heat exchanger; the partition board is provided with an overflow port on one side close to the heat-conducting plate, and the overflow port enables water in the water storage cavity to flow into the water collection cavity along the heat-conducting plate.

The lower end face of the partition plate is provided with a plurality of condensation cones, and the condensation cones are in an inverted cone shape.

The heat-conducting plate is in the chamber upper end of catchmenting is outside protruding, the baffle is located protruding upper end, baffle length is longer than the chamber middle part width catchments.

The heat conducting plate forms a radian at the bottom of the water collecting cavity, so that the lower water outlet is positioned at the lowest position of the bottom of the water collecting cavity.

One end of the partition board, which is close to the heat conducting plate, extends upwards, and the extending height is smaller than the height of the water storage cavity.

The heat conducting plate material is silver or copper.

Compared with the prior art, the utility model has the beneficial effects that:

1. according to the utility model, the water cooling mechanism is arranged outside the heating body, the water cooling mechanism is connected with the heat exchanger, the thermoelectric generator and the water pump, water flow is in contact with the heat conducting plate in the water cooling mechanism, the temperature of the heating body is reduced through temperature conduction while the heat of the heat conducting plate is taken away, the water flow which is changed into hot water flows into the heat exchanger, then the heat energy is converted into electric energy through the thermoelectric generator for storage, the cooled water flow flows back to the water cooling mechanism through the power provided by the water pump, a circulation is formed, and the originally wasted heat is changed into usable energy.

2. According to the water cooling mechanism, the heat of the heating body is conducted to the heat conducting plate through the heat conducting plate which is close to the heating body, the heat is taken away under the water flow overflowing from the water storage cavity, and the hot water flows into the lower water outlet through the special structure of the heat conducting plate and enters the heat exchanger for heat conversion. The heat conducting plate has large area, can effectively take away heat to reduce the temperature of the heating body, does not cause energy waste, and achieves multiple purposes.

Drawings

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic sectional view of the water cooling mechanism and the heating body according to the present invention;

fig. 3 is a partial sectional structural schematic diagram of the water inlet on the water cooling mechanism of the utility model.

The device comprises a water cooling mechanism 1, a heat exchanger 2, a thermoelectric generator 3, a water pipe 4, a water pump 5, a storage battery 6, a heating body 7, a heat conducting plate 11, a partition plate 12, a water storage cavity 13, an upper water inlet 14, a water collecting cavity 15, a lower water outlet 16, an overflow port 17 and a condensation cone 18.

Detailed Description

For a better understanding of the technical solutions of the present technology, the present technology is described in detail below with reference to the accompanying drawings, and the description of the present technology is only exemplary and explanatory, and should not be construed as limiting the scope of the present technology in any way.

It should be noted that: like reference numbers and letters refer to like items in the following figures, and thus, once an item is defined in one figure, it need not be further defined and explained in subsequent figures.

It should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", and the like indicate orientations or positional relationships based on orientations or positional relationships shown in the drawings or orientations or positional relationships that are conventionally placed when the products of the art are used, and are used only for convenience in describing the technology and simplifying the description, but do not indicate or imply that the referred devices or elements must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the technology.

Furthermore, the terms "horizontal", "vertical", "overhang" and the like do not imply that the components are required to be absolutely horizontal or overhang, but may be slightly inclined. For example, "horizontal" merely means that the direction is more horizontal than "vertical" and does not mean that the structure must be perfectly horizontal, but may be slightly inclined.

In the description of the present technology, it should also be noted that, unless otherwise explicitly specified or limited, the terms "disposed," "mounted," "connected," and "connected" are to be construed broadly and may, for example, be fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present technology can be understood in a specific case to those of ordinary skill in the art.

As shown in fig. 1-3, the water cooling device for the heating body 7 of the electromagnetic heating stove comprises a water cooling device, a heat exchanger 2 and a thermoelectric generator 3, wherein the water cooling mechanism 1 is connected with the heat exchanger 2 and a water pump 5 through a water pipe 4, a coupling surface of the heat exchanger 2 is tightly attached to the thermoelectric generator 3, the thermoelectric generator 3 is in electric signal connection with a storage battery 6, and the storage battery 6 can be in electric signal connection with the heat exchanger 2 or the water pump 5 to provide power for the device.

The water cooling mechanism 1 is sleeved outside the heating body 7, the inner wall of the water cooling mechanism 1 is a heat conducting plate 11, and the heat conducting plate 11 is close to the electromagnetic coil of the heating body 7; the water cooling mechanism 1 is hollow, an upper water storage cavity 13 and a lower water collecting cavity 15 are separated from each other in a horizontally sealed mode through a partition plate 12, an upper water inlet 14 is formed in the water storage cavity 13 and connected with the water pump 5, and a lower water outlet 16 is formed in the water collecting cavity 15 and connected with a water inlet of the heat exchanger 2; the partition plate 12 is provided with a spillway 17 at a side close to the heat-conducting plate 11, and the spillway 17 enables the water in the water storage cavity 13 to flow into the water collection cavity 15 along the heat-conducting plate 11.

The terminal surface is equipped with a plurality of condensation awl 18 under baffle 12, condensation awl 18 is the obconic shape, and the water after the heating gets into to meet condensation awl 18 after the vapor that catchments the chamber 15 production rises, and condensation awl 18 is located baffle 12 below, and the temperature is low, and the shaping drippage to catchment chamber 15 can be changeed to vapor.

The heat-conducting plate 11 is in the chamber 15 upper end that catchments is outside protruding, baffle 12 is located protruding upper end, baffle 12 length is longer than the chamber 15 middle part width catchments. The water flowing out from the overflow opening 17 can directly flow to the heat conducting plate 11 to take away the heat on the heat conducting plate 11.

The heat conducting plate 11 forms a radian at the bottom of the water collecting cavity 15, so that the lower water outlet 16 is positioned at the lowest position of the bottom of the water collecting cavity 15, and hot water can flow into the heat exchanger 2 from the lower water outlet 16 conveniently.

One end of the partition plate 12 close to the heat conducting plate 11 extends upwards, and the extending height is smaller than the height of the water storage cavity 13. After water flows into the water storage cavity 13, the water overflows from the overflow port 17 of the water storage cavity 13 to the heat conducting plate 11 after enough amount, so that water flows uniformly on each position of the annular heat conducting plate 11, and cold water is prevented from directly flowing to a fixed position on the heat conducting plate 11.

The heat conducting plate 11 is made of silver or copper, and the metal material with better heat conducting property can effectively reduce the temperature of the heating body 7.

The using method of the utility model comprises the following steps: the water cooling mechanism 1 is sleeved outside the heating body 7, and the heat conducting plate 11 is adjacent to the heating body 7 and becomes hot through heat conduction; cold water flows into a water storage cavity 13 of the water cooling mechanism 1 from an upper water inlet 14, after the water storage cavity 13 is full, the water overflows from an overflow port 17 and flows onto a heat conduction plate 11 in an annular shape, the water flows downwards under the influence of gravity, the temperature of the heat conduction plate 11 is reduced through heat conduction, the water flows to a lower water outlet 16 in a water collection cavity 15 after being heated, hot water flows into a heat exchanger 2 from the lower water outlet 16, a coupling surface of the heat exchanger 2 is connected with a thermoelectric generator 3, and the thermoelectric generator 3 converts the temperature of the water flow into electric energy to be stored in a storage battery 6 or used for using the device. After the hot water is cooled in the heat exchanger 2, the hot water flows into the water storage cavity 13 from the upper water inlet 14 of the water cooling mechanism 1 again through the power provided by the water pump 5, and the next cycle is started. The flowing water can continuously cool the heat conducting plate 11, and cool the heating body 7 through the action, so that the heating body 7 is always at a proper temperature, and the danger caused by overheating is avoided.

It should be noted that there are no specific structures in the above description, and it will be apparent to those skilled in the art that various modifications, decorations, or changes can be made without departing from the technical principles of the present invention; such modifications, variations, or combinations, or applying the concepts and solutions of the technology directly to other applications without further modifications, are intended to be within the scope of the present technology.

Claims (6)

1. The utility model provides an electromagnetic heating stove heating member water cooling plant which characterized in that: the device comprises a water cooling mechanism, a heat exchanger and a thermoelectric generator, wherein the water cooling mechanism is connected with the heat exchanger and a water pump through a water pipe, a coupling surface of the heat exchanger is tightly attached to the thermoelectric generator, and the thermoelectric generator is electrically connected with a storage battery; the water cooling mechanism is sleeved outside the heating body, the inner wall of the water cooling mechanism is a heat conducting plate, and the heat conducting plate is close to the electromagnetic coil of the heating body; the water cooling mechanism is hollow, an upper water storage cavity and a lower water collecting cavity are separated by a partition plate in a horizontal sealing mode, the water storage cavity is provided with an upper water inlet and is connected with the water pump, and the water collecting cavity is provided with a lower water outlet and is connected with a water inlet of the heat exchanger; the partition board is provided with an overflow port on one side close to the heat-conducting plate, and the overflow port enables water in the water storage cavity to flow into the water collection cavity along the heat-conducting plate.

2. The electromagnetic heating stove heating body water cooling device of claim 1, characterized in that: the lower end face of the partition plate is provided with a plurality of condensation cones, and the condensation cones are in an inverted cone shape.

3. The electromagnetic heating stove heating body water cooling device of claim 1, characterized in that: the heat-conducting plate is in the chamber upper end of catchmenting is outside protruding, the baffle is located protruding upper end, baffle length is longer than the chamber middle part width catchments.

4. The electromagnetic heating stove heating body water cooling device according to claim 1 or 3, characterized in that: the heat conducting plate forms a radian at the bottom of the water collecting cavity, so that the lower water outlet is positioned at the lowest position of the bottom of the water collecting cavity.

5. The electromagnetic heating stove heating body water cooling device of claim 1, characterized in that: one end of the partition board, which is close to the heat conducting plate, extends upwards, and the extending height is smaller than the height of the water storage cavity.

6. The electromagnetic heating stove heating body water cooling device of claim 1, characterized in that: the heat conducting plate material is silver or copper.

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