CN216131966U - Heat accumulation type electric heater capable of adjusting heat release - Google Patents

Abstract

The utility model discloses a heat accumulating type electric heater capable of adjusting heat release, which comprises a shell, a main body heating assembly and a circulating heat accumulating assembly, wherein the main body heating assembly is connected and arranged at the middle position in the shell, the circulating heat accumulating assembly is connected and arranged at two sides of the main body heating assembly in the shell, the main body heating assembly comprises a power supply control module, an air outlet, a heat pipe, an air outlet channel and a double-layer grid type heat supply port, and the circulating heat accumulating assembly comprises a heat accumulating cavity, a heat regenerative channel, a mounting bracket, a ceramic heat accumulator and a turnover type heat dissipation port. The utility model relates to the technical field of heating equipment, in particular to a heat accumulating type electric heater which can accumulate heat in a heat accumulator for later use and avoid high heat release power in the later period of the heat accumulating type electric heater and the initial period of the heat release period and can regulate heat release.

Description

Heat accumulation type electric heater capable of adjusting heat release

Technical Field

The utility model relates to the technical field of heating equipment, in particular to a heat accumulating type electric heater capable of adjusting heat release.

Background

The electric heater, use the electric energy as the main energy, use modes such as resistance heating, induction heating, electric arc heating, electron beam heating, infrared heating and medium heating, supply heat for the human body through ways such as direct contact, warm air convection, far infrared radiation, etc., in order to improve the environment, reduce coal-fired pollution, the electric heater is widely used, and the electric heater usually will consume a large amount of electric energy when using, not only cost comparatively huge economically, and a large amount of electric energy wasted is a kind of pollution to the environment to a certain extent, the heat accumulation type electric heater has entered people's life because of the lower cost at this moment, reduce the power consumption when supplying the peak of power consumption and reduce the cost when the power consumption is low, thus reduced the power consumption to a certain extent, but this kind of electric heater can not carry on heat accumulation while supplying heat, also need to spend the electric energy specially when heat accumulation, the heat loss not only is energy-conserving but also waste heat energy to traditional heat accumulation formula electric heater heat accumulation stage later stage and the exothermic power in exothermic stage initial stage are too high, cause this period indoor temperature on the high side, and exothermic power decay in exothermic stage is very fast, and indoor temperature descends also very fast, and exothermic power is low excessively in exothermic stage later stage, causes the indoor temperature to be lower, and consequently the temperature fluctuation in the whole day indoor temperature is great, thereby leads to the indoor environment travelling comfort relatively poor.

SUMMERY OF THE UTILITY MODEL

In view of the above situation, in order to overcome the defects of the prior art, the utility model provides an adjustable heat-release heat-accumulating electric heater which can accumulate heat in a heat accumulator for later use during use and avoid high heat-release power in the later period of the heat-accumulating electric heater heat-accumulating stage and the initial period of the heat-release stage.

The technical scheme adopted by the utility model is as follows: the utility model relates to a heat accumulating type electric heater capable of adjusting heat release, which comprises a shell, a main body heating component and a circulating heat accumulating component, wherein the main body heating component is connected and arranged at the middle position in the shell, the circulating heat accumulating component is connected and arranged at two sides of the main body heating component in the shell, the main body heating component comprises a power supply control module, an air outlet, a heat pipe, an air outlet channel and a double-layer grid type heat supply port, the power supply control module is connected and arranged at the middle position of the inner bottom wall of the shell, the air outlet is uniformly connected and arranged on the power supply control module, the heat pipe is connected and arranged on the power supply control module and is arranged right above the air outlet, the air outlet channel is connected and arranged on the inner top wall of the shell in a penetrating way, the double-layer grid type heat supply port is embedded and arranged at the top end of the air outlet channel, the circulating heat accumulating component comprises a heat accumulating cavity, a heat returning channel, an installation support, a ceramic heat accumulator and a turnover type heat dissipation port, the heat storage cavity is arranged on two sides in the shell, the heat regeneration channel is arranged between the heat storage cavity and the air outlet channel in a penetrating mode, the mounting support is connected to the top and the bottom of the heat storage cavity, the ceramic heat accumulator is connected between the mounting support, and the turnover type heat dissipation opening is arranged on two side walls of the shell in a penetrating mode and is arranged outside the heat storage cavity.

Further, a temperature sensor is connected to the top of the shell.

Further, the temperature sensor is electrically connected with the power supply control module, and the power supply control module is electrically connected with the turnover type heat dissipation opening.

Furthermore, an insulating layer covers the inner wall of the heat storage cavity.

Further, convertible thermovent material sets up for insulation material.

The utility model with the structure has the following beneficial effects: the utility model provides an adjustable exothermic heat accumulation formula electric heater, when using, at first power control module control heat pipe and air outlet begin the heat supply, hot-blast part is blown off by double-deck grid formula heat supply mouth from the air-out passageway, rise the room internal temperature, another part hot-blast passes through backheating passageway and gets into the heat accumulation chamber, convertible thermovent is closed this moment, the ceramic heat accumulator begins the heat accumulation, after room temperature rose, the ceramic heat accumulator heat accumulation that finishes that heat accumulation was finished utilizing backheating surplus wind at this moment finishes, power control module stops the heat supply, open convertible thermovent, heat supply by the heat accumulation, do not consume the electric energy this moment, only need to keep the room internal temperature, when will distribute and finish promptly, the temperature descends, convertible thermovent closes, heat again, heat up the room, heat accumulation begins again simultaneously, so cycle, can very big reduction power consumption time, the power consumption is reduced, simultaneously, the uncomfortable feeling caused by rapid temperature change in the room is avoided, the room temperature is always stabilized in a small change interval, the energy is saved, the cost is reduced, and the environment is protected.

Drawings

Fig. 1 is a schematic view of the overall structure of a heat accumulating type electric heater capable of adjusting heat release according to the present invention.

The accompanying drawings, which are included to provide a further understanding of the utility model and are incorporated in and constitute a part of this specification, illustrate embodiments of the utility model and together with the description serve to explain the principles of the utility model and not to limit the utility model.

The heat-exchange system comprises a shell 1, a shell 2, a main body heating component 3, a circulating heat storage component 4, a power supply control module 5, an air outlet 6, a heat pipe 7, an air outlet channel 8, a double-layer grid type heat supply port 9, a heat storage cavity 10, a heat return channel 11, a mounting support 12, a ceramic heat accumulator 13, a turnover type heat dissipation port 14, a temperature sensor 15 and a heat insulation layer.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments; all other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

As shown in fig. 1, the heat accumulating type electric heater capable of adjusting heat release of the utility model comprises a shell 1, a main body heating component 2 and a circulating heat accumulating component 3, wherein the main body heating component 2 is connected and arranged at the middle position in the shell 1, the circulating heat accumulating component 3 is connected and arranged at two sides of the main body heating component 2 in the shell 1, the main body heating component 2 comprises a power supply control module 4, an air outlet 5, a heat pipe 6, an air outlet channel 7 and a double-layer grid type heat supply port 8, the power supply control module 4 is connected and arranged at the middle position of the inner bottom wall of the shell 1, the air outlet 5 is uniformly connected and arranged on the power supply control module 4, the heat pipe 6 is connected and arranged on the power supply control module 4 and right above the air outlet 5, the air outlet channel 7 is connected and arranged on the inner top wall of the shell 1 in a penetrating manner, the double-layer grid type heat supply port 8 is embedded and arranged at the top end of the air outlet channel 7, and the circulating heat accumulating component 3 comprises a heat accumulating cavity 9, Backheat passageway 10, installing support 11, ceramic heat accumulator 12 and convertible thermovent 13, hold heat chamber 9 and locate both sides in shell 1, backheat passageway 10 runs through and locates between heat chamber 9 and the air-out passageway 7, installing support 11 is connected and is located heat chamber 9 top and bottom, ceramic heat accumulator 12 is connected and is located between installing support 11, convertible thermovent 13 runs through and locates on the 1 both sides wall of shell and locate outside heat chamber 9.

Wherein, a temperature sensor 14 is connected with the top of the shell 1; the temperature sensor 14 is electrically connected with the power supply control module 4, and the power supply control module 4 is electrically connected with the turnover type heat dissipation port 13; the inner wall of the heat storage cavity 9 is covered with a heat insulation layer 15; convertible thermovent 13 material sets up for insulation material.

When the heat storage type air conditioner is used specifically, firstly, the heat pipe 6 and the air outlet 5 are controlled by the power control module 4 to start heat supply, one part of hot air is blown out from the air outlet channel 7 through the double-layer grid type heat supply port 8, the temperature in a room rises, meanwhile, the other part of hot air enters the heat storage cavity 9 through the heat return channel 10, the turnover type heat dissipation port 13 is closed at the moment, the ceramic heat accumulator 12 starts heat storage, after the temperature of the room rises, the ceramic heat accumulator 12 which finishes heat storage by utilizing the heat return residual air at the moment finishes heat storage, the power control module 4 stops heat supply, the turnover type heat dissipation port 13 is opened, heat supply is carried out by heat storage, the electric energy is not consumed at the moment, only the temperature in the room needs to be kept, when the heat storage is finished, the temperature is lowered, the turnover type heat dissipation port 13 is closed, heating is carried out again, the temperature of the room is raised, meanwhile, heat storage is started again, and the process is circulated.

The present invention and its embodiments have been described above, and the description is not intended to be limiting, and the drawings are only one embodiment of the present invention, and the actual structure is not limited thereto. In summary, those skilled in the art should appreciate that they can readily use the disclosed conception and specific embodiments as a basis for designing or modifying other structures for carrying out the same purposes of the present invention without departing from the spirit and scope of the utility model as defined by the appended claims.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Claims (5)

1. The utility model provides an adjustable exothermic heat accumulation formula electric heater which characterized in that: the heat-storage type solar water heater comprises a shell, a main body heating component and a circulating heat-storage component, wherein the main body heating component is connected and arranged at the middle position in the shell, the circulating heat-storage component is connected and arranged at two sides of the main body heating component in the shell, the main body heating component comprises a power control module, an air outlet, a heat pipe, an air outlet channel and a double-layer grid type heat supply port, the power control module is connected and arranged at the middle position of the inner bottom wall of the shell, the air outlet is uniformly connected and arranged on the power control module, the heat pipe is connected and arranged on the power control module and is arranged right above the air outlet, the air outlet channel is penetratingly connected and arranged on the inner top wall of the shell, the double-layer grid type heat supply port is embedded and arranged at the top end of the air outlet channel, the circulating heat-storage component comprises a heat-storage cavity, a heat-storage channel, a mounting bracket, a ceramic heat-storage body and a turnover type heat-dissipation port, the heat-storage cavity is arranged at two sides in the shell, the backheating passageway runs through and locates between heat accumulation chamber and the air-out passageway, the installing support connection is located heat accumulation chamber top and bottom, the ceramic heat accumulator connection is located between the installing support, convertible thermovent runs through and locates on the shell both sides wall and locate outside the heat accumulation chamber.

2. A regenerative electric heater with adjustable heat release as claimed in claim 1, wherein: and the top of the shell is connected with a temperature sensor.

3. A regenerative electric heater with adjustable heat release as claimed in claim 2, wherein: the temperature sensor is electrically connected with the power supply control module, and the power supply control module is electrically connected with the turnover type heat dissipation opening.

4. A regenerative electric heater with adjustable heat release as claimed in claim 1, wherein: and the inner wall of the heat storage cavity is covered with a heat insulation layer.

5. A regenerative electric heater with adjustable heat release as claimed in claim 1, wherein: convertible thermovent material sets up for insulation material.

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