JP2001035636A - Charged electric heater - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an electric heater usable outdoors. SOLUTION: If there is a sufficient time to spare before going out, a condensed cartridge 6 is fitted into a slot portion 23 of a charge unit 2 and a power plug 51 is inserted into a socket provided in each house. Then, a direct current is supplied from a regular power supply part 5 to the condensed cartridge 6 to charge an electric double layered capacitor 61. If there is no time to spare, the condensed cartridge 6 is fitted into the slot portion 23 of the charge unit 2 and the charge unit 2 is fixed to the roof of an automobile. Then, a direct current is supplied from a wind power generation part 3 and a solar battery part 4 to the condensed cartridge 6 to change the electric double layered capacitor 61. When the electric double layered capacitor 61 is charged, the condensed cartridge 6 is pulled off and fitted into a slot portion 13 of an electric heater body 1. Then, a direct current is supplied from the electric double layered capacitor 61 to a heating wire 11 to generate heat in the heating wire 11.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[0001] The present invention relates to a rechargeable electric heater.

[0002]

2. Description of the Related Art Conventionally, when heat is generated for cooking or the like outdoors,
It is common to use a burner using liquefied petroleum gas or the like as fuel. However, burning liquefied petroleum gas or the like generates carbon monoxide, carbon dioxide, and the like, which contributes to deterioration of the environment in a long term, which is not preferable.

Therefore, there is a demand for a technique for generating heat without generating carbon monoxide, carbon dioxide, and the like.
The present invention has been made to meet such a demand, and has as its object to provide a rechargeable electric heater that can be used outdoors.

[0004]

Means for Solving the Problems and Effects of the Invention In order to achieve such an object, a rechargeable electric heater according to the present invention comprises an electric heating means which generates heat when a DC current flows, a capacitor, and a capacitor. Charging means for charging, wherein a direct current is supplied to the electric heating means from the capacitor charged by the charging means, thereby causing the electric heating means to generate heat. Here, the electric heating means is, for example, an electric path in which an electric heating wire such as a nichrome wire is formed in a coil shape or the like.

[0005] In the rechargeable electric heater according to the present invention,
The capacitor charged in advance by the charging means supplies a DC current to the electric heating means, and the electric heating means generates heat by the flow of the DC current. Therefore, for example, if a capacitor is charged in advance in each home, heat can be generated outdoors without generating carbon monoxide, carbon dioxide, and the like. If the capacitance of the capacitor and the number of capacitors connected in series and in parallel are selected according to the amount of power consumed by the electric heating means, the electric heating means can generate heat stably by the DC current supplied from the capacitor.

[0006] At present, an electric double layer capacitor (Electric-Double-Layer-Capacitor) having a large capacitance and stable discharge characteristics has been put to practical use. This electric double layer capacitor has the advantages that it can be charged in a short period of time, has little performance degradation due to repeated charging and discharging, and can maintain its charging and discharging characteristics for a long period of time. Therefore, as described in claim 2, if an electric double layer capacitor is used as a capacitor constituting the rechargeable electric heater according to the present invention,
DC current can be supplied to the electric heating means more stably.

According to a third aspect of the present invention, in the rechargeable electric heater according to the present invention, the capacitor comprises:
It is good to be constituted so that separation from the electric heating means and the charging means is possible. When the rechargeable electric heater according to the present invention is configured in this manner, first, the capacitor is connected to the charging means for charging, then the capacitor is separated from the charging means, and then the capacitor is electrically heated. Means for supplying a direct current from the capacitor to the electric heating means. That is, only the condenser needs to be moved, and the electric heating means and the charging means may be installed in a specific place. If a plurality of capacitors are prepared, one capacitor can be connected to the charging means and charged while another capacitor is connected to the electric heating means to supply a direct current. Therefore, it is very convenient.

According to a fourth aspect of the present invention, in the rechargeable electric heater according to the present invention, the charging means includes a power generating means for generating a DC current by itself, and the DC power generated by the power generating means. Preferably, the capacitor is configured to be charged by current. Here, the power generation means is, for example, one that converts light energy into electric energy,
A motor that rotates a motor to convert mechanical energy into electrical energy.

When the rechargeable electric heater according to the present invention is configured as described above, the capacitor is charged by the direct current supplied from the power generation means. Therefore, the capacitor can be charged even outdoors.

[0010]

DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of the present invention will be described below with reference to the drawings. First, the configuration of the rechargeable electric heater of the present embodiment will be described. FIG. 1 is a schematic configuration diagram for explaining the configuration of a rechargeable electric heater, and FIG. 2 is a plan view (a) and a front view (b) for explaining the appearance of a charging unit.
It is.

As shown in FIG. 1, the rechargeable electric heater of this embodiment includes an electric heater main body 1, a charging unit 2, and a power storage cartridge 6. The electric heater body 1
A heating wire 11, a switch 12, a power input terminal T1,
And a ground terminal T2. Further, the electric heater main body 1 is provided with a slot portion 13 into which the electric storage cartridge 6 is fitted.

The heating wire 11 generates Joule heat when a current flows. One end of the heating wire 11 is connected to a power input terminal T1 via a switch 12, and the other end is grounded. The switch 12 is a well-known switch that switches between conduction and non-conduction. The power input terminal T1 is provided at a position where the power storage cartridge 6 is connected to a positive electrode terminal T8 described later in a state where the power storage cartridge 6 is fitted into the slot portion 13. The ground terminal T2 is provided at a position connected to a negative terminal T9 described later in a state where the power storage cartridge 6 is fitted in the slot portion 13, and is grounded.

As shown in FIGS. 1 and 2, the charging unit 2 includes a housing 21, a fixture 22, a wind power generator 3,
Solar cell unit 4, ordinary power supply unit 5, power output terminal T6
And a ground terminal T7. The charging unit 2 also has a slot 2 for fitting the power storage cartridge 6.
3 are provided.

The housing 21 is for protecting the circuit elements and the like constituting the wind power generation unit 3, the solar cell unit 4, and the ordinary power supply unit 5. The attachment 22 is for fixing the charging unit 2 to a roof of an automobile (not shown). The power output terminal T6 is connected to the power storage cartridge 6 by the slot 2.
3 and a positive electrode side terminal T8 described later.
Are connected to the power output terminals T3, T4, and T5 described later. Ground terminal T7
Is provided at a position connected to a negative electrode side terminal T9 described later in a state where the power storage cartridge 6 is fitted into the slot portion 13 and is grounded.

The wind power generator 3 includes a three-phase AC motor 31,
It includes a wind turbine 31P, a three-phase full-wave rectifier circuit 32, a smoothing capacitor 33, a resistor 34, a buffer 35, and a power output terminal T3. The three-phase AC motor 31 is a wind turbine 31P
Is a well-known device that generates a three-phase alternating current by rotating in response to wind. The three-phase full-wave rectifier circuit 32 is a well-known one that rectifies the three-phase AC current generated by the three-phase AC motor 31. The smoothing capacitor 33 is generated by the three-phase AC motor 31 and generated by the three-phase full-wave rectifier circuit 32.
This is to remove the AC component of the three-phase AC current rectified by the above to make the DC current substantially complete. Buffer 3
5 is to reduce the resistance value as viewed from the input side and increase the resistance value as viewed from the output side, so that current does not flow from the power output terminal T3 toward the inside of the wind power generation unit 3. The output side is connected to the power output terminal T3, and the input side is grounded via the resistor. The buffer 35 is specifically composed of a diode, F
It is configured by ET or the like.

The solar cell unit 4 includes a plurality of solar cells 41,
It includes a buffer 42 and a power output terminal T3. The solar cell 41 is an energy conversion device that converts light energy into electric energy, and a plurality of solar cells 41 are connected in series. The buffer 42 is for preventing a current from flowing from the power output terminal T4 toward the inside of the solar cell unit 4 similarly to the buffer 35. The output side is connected to the power output terminal T4, and the input side is Is connected to the positive electrode side of the solar cell 41.

The ordinary power supply unit 5 includes a power plug 51, a transformer 52, a single-phase full-wave rectifier circuit 53, a smoothing capacitor 54, a resistor 55, a buffer 56, and a power output terminal T.
5 is provided. The power plug 51 is a well-known one that is inserted into an outlet (not shown) provided in each house or the like. The transformer 52 is a well-known transformer that transforms an alternating current supplied from a power plant (not shown) via an outlet and a power plug 51. Three-phase full-wave rectifier circuit 3
2 is a well-known device for rectifying the AC current transformed by the transformer 52. The smoothing capacitor 54 removes the AC component of the single-phase AC current that has been transformed by the transformer 52 and rectified by the single-phase full-wave rectifier circuit 53, and converts the AC component into a substantially complete DC current. The buffer 56
Like the buffers 35 and 42, this is for preventing a current from flowing from the power output terminal T5 toward the inside of the ordinary power supply unit 5. The output side is connected to the power output terminal T5, and the input side is connected to a resistor. 55 is grounded.

The storage cartridge 6 includes an electric double layer capacitor 61, a positive terminal T8, and a negative terminal T9. The electric double layer capacitor 61 has a positive electrode connected to the positive electrode terminal T8 and a negative electrode connected to the negative electrode terminal T9. The positive electrode side terminal T8 is connected to the power input terminal T1 of the electric heater main body 1 in a state where the electric storage cartridge 6 is fitted into the slot portion 13 of the electric heater main body 1, and the electric storage cartridge 6 is connected to the slot portion 23 of the charging unit 2. It is provided at a position where it is connected to the power output terminal T6 of the charging unit 2 when fitted into The negative electrode side terminal T9 is connected to the ground terminal T2 of the electric heater main body 1 in a state where the electric storage cartridge 6 is fitted into the slot portion 13 of the electric heater main body 1, and the electric storage cartridge 6 is connected to the slot 23 of the charging unit 2. It is provided at a position connected to the ground terminal T7 of the charging unit 2 in the fitted state, and is grounded. In addition, in FIG.
Although the number of electric double-layer capacitors is shown, in actuality, the number of electric double-layer capacitors
They will be connected in parallel.

Next, a specific procedure for actually using the rechargeable electric heater of the present embodiment will be described. First,
If there is enough time, before going out, the power storage cartridge 6 is fitted into the slot 23 of the charging unit 2 and the power plug 51 is inserted into an outlet provided in each house or the like. Then, a direct current is supplied from the ordinary power supply unit 5 to the power storage cartridge 6, and the electric double layer capacitor 61 is charged.

On the other hand, when there is no time, the power storage cartridge 6 is fitted into the slot 23 of the charging unit 2 and the charging unit 2 is fixed to the roof of the automobile. Then drive this car and go out. Then, the windmill 31
P rotates in response to the wind, and a direct current is supplied from the wind power generation unit 3 to the power storage cartridge 6 so that the electric double-layer capacitor 6
1 is charged. If the weather is good, the solar battery 41 receives sunlight, and a direct current is supplied from the solar battery unit 4 to the power storage cartridge 6 to charge the electric double layer capacitor 61.

When the electric double layer capacitor 61 is charged, the electric storage cartridge 6 is removed from the slot 23 of the charging unit 2 and the electric storage cartridge 6 is fitted into the slot 13 of the electric heater body 1. When the switch 12 is turned on, a DC current is supplied from the electric double layer capacitor 61 to the heating wire 11, and the heating wire 11 generates heat.

In this embodiment, the heating wire 11 corresponds to the above-described electric heating means, the charging unit 2 corresponds to the above-described charging means, and the wind power generation unit 3 and the solar cell unit 4 correspond to the above-described power generation means. I do. Next, the effect of the rechargeable electric heater of the present embodiment will be described.

In the rechargeable electric heater of this embodiment, the electric double layer capacitor 61 charged by the charging unit 2 supplies a DC current to the heating wire 11 and the DC current flows to generate heat. I do. Therefore, heat can be generated without generating carbon monoxide, carbon dioxide, and the like.

The electric storage cartridge 6 is provided in the electric heater main body 1.
And the charging unit 2, so that the electric heater main body 1 and the charging unit 2 may be installed in a specific place. In addition, if a plurality of power storage cartridges are prepared, another power storage cartridge is connected to the charging unit 2 to charge while one DC power supply cartridge is connected to the electric heater main body 1 to supply DC current. Can be kept. Therefore, it is very convenient.

Further, since the charging unit 2 includes the wind power generation unit 3 and the solar cell unit 4 that generate DC current by itself, the charging unit 2 can charge the electric double layer capacitor 61 even outdoors. As described above, one embodiment of the present invention has been described, but the present invention is not limited to the above-described embodiment at all, and it is needless to say that the present invention may be implemented in various modes.

For example, the rechargeable electric heater of the embodiment is divided into three members, that is, an electric heater main body 1, a charging unit 2, and an electric storage cartridge 6, but the electric heater main body 1 and the electric storage cartridge 6 are combined into one member. May be integrated.

[Brief description of the drawings]

FIG. 1 is a schematic configuration diagram for explaining a configuration of a rechargeable electric heater according to an embodiment.

FIG. 2 is a plan view (a) and a front view (b) for explaining the appearance of the charging unit.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Electric heater main body 2 ... Charging unit 3 ... Wind power generation part 4 ... Solar cell part 5 ... Normal power supply part 6 ... Electric storage cartridge 11 ... Electric heating wire 12 ... Switch 13
… Slot part 21… Housing 22… Mounting tool
23 ... Slot part 31 ... Three-phase AC motor 31P
... Windmill 32 ... Three-phase full-wave rectifier circuit 33 ... Smoothing capacitor 34 ... Resistance 35 ... Buffer 41 ... Solar cell 42 ... Buffer 51 ... Power plug 52 ...
Transformer 53 Single-phase full-wave rectifier circuit 54 Smoothing capacitor 55 Resistor 56 Buffer 61 Electric double layer capacitor T1 Power input terminal T2 Ground terminal T3 Power output terminal T4 Power output terminal T5 Power output terminal T6 … Charging terminal T7…
Ground terminal T8: Positive terminal T9: Negative terminal.

Claims (4)

[Claims] An electric heating means for generating heat when a DC current flows, a capacitor, and a charging means for charging the capacitor, wherein a DC current is supplied from the capacitor charged by the charging means to the electric heating means. A rechargeable electric heater characterized by causing the electric heating means to generate heat when supplied. 2. The rechargeable electric heater according to claim 1, wherein an electric double layer capacitor is used as the capacitor. 3. The rechargeable electric heater according to claim 1, wherein the capacitor is configured to be separable from the electric heating unit and the charging unit. 4. The charging device according to claim 1, wherein the charging unit includes a power generating unit that generates a DC current by itself, and charges the capacitor with the DC current generated by the power generating unit. The rechargeable electric heater as described.