JPH0239695B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION Technical Field The present invention relates to a planar heating device such as a floor heating carpet.

BACKGROUND ART In typical prior art, heating wires are placed inside a flat sheet-like body and floor heating is performed by energizing the heating wires with electric power. With such prior art, floor heating can only be performed during the period when the heating wires are energized, resulting in excessive electrical energy consumption and high running costs.

Purpose An object of the present invention is to provide a planar heating device that consumes as little energy as possible.

Embodiment FIG. 1 is a plan view of the basic structure of the present invention, and FIG. 2 is a sectional view taken along the cutting plane line - in FIG. 1. The heating device 1 has a rectangular planar shape, for example, and is installed on a floor 2 in a room. In this heating device 1, a cushion layer 3 made of a heat insulating material, a flat heat storage layer 40, and a carpet layer 5 made of felt or the like are laminated in this order from the bottom surface to the top surface. Heat storage layer 40
Heating wires 6 serving as heating means for heating the heat storage layer 40 are buried in a zigzag pattern over the entire surface of the heating device 1 between the heating device 1 and the heat insulating cushion layer 3 . A temperature detection means 7 is provided near the heating wire 6. In addition, in FIG. 1, the heating wire 6 is shown as a solid line for ease of illustration.

The heat storage layer 40 includes a heat storage material 4 and a cover body 8 that seals the heat storage material 4. The heat storage material 4 is made of a substance that can utilize latent heat and has a melting point at heating temperature. Examples of heat storage substances include inorganic materials such as CaCl _{2.6H 2} O, CaCO _{3.10H 2} O,
Examples include NaHPO ₄ .12H ₂ O, Na ₂ SO ₄ .10H ₂ O, and organic materials include paraffin and polyethylene glycol. These substances have a long temperature duration near their melting point and can store a large amount of heat in proportion to their volume, so they are suitable as the heat storage material 4 used in the present invention. The heat storage material 4 is sealed in a cover body 8 made of a plastic film such as nylon polyethylene or polyester. Therefore, even when the heat storage material 4 changes from a solid phase to a liquid phase, leakage is prevented. Instead of sealing the cover body 8, a non-woven material may be impregnated with a heat storage material.
In this way, the feeling of walking on the upper surface of the floor heating device 1 can be made good, and when the heat storage material 4 becomes liquid, it is prevented from being concentrated in one place.

The heating wire 6 is connected to a daytime AC power source M1 and a nighttime AC power source M2 via a day/night changeover switch SW1. Also switch SW1 and heating wire 6
An AC power supply M1, which is applied to the heating wire 6, is connected between the
Switch to cut off power from M2
SW2 is provided.

FIG. 3 is a block diagram showing a control mechanism for controlling the heating operation of the heating device 1. As shown in FIG. The output of the temperature detection means 7 is given to the processing circuit 10, and the ON/OFF operation of the switch SW2 is controlled by the processing circuit 10. The processing circuit 10 is also given an output from a clock means 11. With this, switch SW1
The switching mode changes, and AC power source M1 and AC power source M2 are switched. To explain more specifically, a predetermined time period W (Figs. 4 and 8)
(See figure) For example, between 10pm and 7am, the switch
Common contacts m1 and m2 of SW1 are fixed contacts p2 and p
4 side, and the power from the AC power source M2 energizes the heating wire 6. In addition, during the remaining time outside the time period W, the common contacts m1 and m2 of the switch SW1 are in contact with the fixed contacts p1 and p3, and the heating wire 6 is energized by the AC power source M1.

FIG. 4 is a graph showing the conduction cut off state of the switches SW1 and SW2 and the temperature rise state related thereto. Referring also to FIG. 3, when the time announced by the clock means 11 reaches a predetermined time t1, for example, 22:00, the switch SW1
As shown in FIG. 1, it is switched to the AC power source M2 for nighttime use. At time t0 before this predetermined time t1, switch SW2 operates as shown in FIG.
It is in the ON state, even after time t1.
It continues to be in the ON state. In this state, when the temperature detected by the temperature detection means 7 reaches the upper limit discrimination level l1 at time t2 as shown in FIG. 4, the switch is activated as shown in FIG.
SW2 becomes OFF state. Therefore, as shown in FIG. 4, the temperature decreases, and when the temperature detecting means 7 detects that the lower limit discrimination level l2 has been reached, the switch SW is turned on as shown in FIG. 4, 2.
2 is turned ON again. By this, heating wire 6
The temperature rises again as shown in FIG. In this way, such a series of operations is repeated until time t4, when the night power supply M2 is switched to the commercial AC power supply M1. In this way, from time t1 to time t4, the melting point temperature K0 of the heat storage material 4 is controlled to be approximately maintained at a predetermined temperature K1 of, for example, 40° C. or higher. In this manner, during the time period W, the heat storage material 4 receives a large amount of heat from the heating wire 6, changes its phase from solid to liquid, and stores heat. For example, when the heat storage material 4 is CaCl ₂ 6H ₂ O, the latent heat is 43Kcal/Kg, and when it is paraffin, the latent heat is 43Kcal/Kg.
50Kcal/Kg, therefore, a small temperature increase will accumulate a large amount of heat in a small volume.

When the time announced by the clock means 11 reaches a predetermined time t4, for example 7 o'clock, the fourth
As shown in FIG. 1, the switch SW1 is switched to the commercial AC power source M1 for daytime use. At this time, since the temperature detected by the temperature detection means 7 is higher than the melting point K0, the switch SW2 is turned off as shown in FIG. 42. After that, the time t5 when the heat storage material 4 completes the phase change from the liquid phase to the solid phase
Until then, switch SW2 continues to maintain the OFF state. The time from time t4 to time t5 is
Generally, it is about 7 to 8 hours. In this way, from time t4 to time t5, the amount of heat stored in the heat storage material during the night is gradually radiated, and therefore there is no need to use commercial AC power for daytime use. Instead of using expensive electricity, low-cost late-night electricity can be used to heat the room, making it possible to reduce costs. Furthermore, since the temperature of the heat storage material 4 is raised relatively slowly, it is possible to maintain a comfortable heating temperature for a long time.

After the heat storage material 4 changes from liquid to solid, the power source M
1 is used as an auxiliary. That is, after time t5, the switch SW2 is turned on again, and the heating wire 6 is again energized by the power from the AC power source M1. This causes the temperature to rise again and the time
When the upper limit discrimination level l3 is reached at t6, the switch SW2 is turned off. Therefore, the temperature decreases, and at time t7 the lower limit discrimination level is reached.
When l4 is reached, switch SW2 is turned on. By repeating this series of operations after time t7, the heating temperature reaches the discrimination level l1,
The temperature K2 is roughly maintained near the melting point K0 between l2. In this way, after time t5, the heat storage material 4
does not get very warm, and most of the heat is used for heating. Also, even if the temperature drops too much, the latent heat of the heat storage material 4 will be utilized, and the heating temperature will reach the melting point.
The temperature will not rise above K0, thus preventing the occurrence of a situation where a pedestrian or the like will suffer a burn injury.

FIG. 5 is a plan view of one embodiment of the present invention, and FIG. 6 is a sectional view taken along the section line - in FIG. This embodiment is similar to the previously described configuration, and corresponding parts are provided with the same reference numerals. What should be noted is that this heating device 20 has a heating wire 21 connected to a commercial AC power source M1 for daytime use, and an AC power source M2 for nighttime use.
A heating wire 22 for late-night use is used. In FIG. 5, for ease of illustration, the heating wire 21 is shown as a solid line, and the heating wire 22 is shown as a broken line. The heating wire 21 is buried between the heat storage layer 40 and the carpet layer 5, and the heating wire 22 is buried between the heat storage layer 40 and the heat insulation cushion layer 3, which is a heat insulation layer. The heating wire 21 is equipped with a temperature detection means 23, and the other heating wire 22 is equipped with a temperature detection means 24.

The heating wire 21 is connected to the daytime commercial AC power source M1 via the switch SW3, and the heating wire 22
AC power supply M2 for night use is connected via switch SW4.
It is connected to the.

FIG. 7 is a block diagram showing a control mechanism for controlling the heating operation of the heating device 20. Temperature detection means 2
3 and 24 and the outputs from the clock means 11 are given to the processing circuit 10, and the processing circuit 10 controls the ON/OFF operation of the switches SW3 and SW4.

FIG. 8 is a graph showing the conduction cut off state of the switches SW3 and SW4 and the temperature rise state related thereto. The heating operation of the heating device 20 will be explained with reference to FIG. 7 as well. When the time t1 predetermined by the clock means 11 is reached, the switch SW4 is turned on as shown in FIG. 81, and the switch SW3 is turned off as shown in FIG. 82. Therefore, the heating wire 22 is an AC power source M for night use.
8.3.
The temperature rises as shown in . When the temperature reaches the discrimination level l1 at time t2, Fig. 81
As shown, the switch SW4 is in the OFF state.
Therefore, the temperature decreases as shown in FIG. 83, and when it reaches the lower limit discrimination level l2 at time t3, the switch SW4 is turned ON again.
The heating wire 22 is energized again and the temperature increases. In this way, a predetermined time after time t3
Such an operation is repeated until t4, for example, 7 o'clock, and the temperature is maintained at a temperature K1 that is approximately equal to or higher than the melting point K0 of the heat storage material 4. In this manner, a large amount of heat from the heating wire 22 is stored in the heat storage material 4 during the time period W from time t1 to time t4.

At time t4, the switch SW4 is turned off as shown in FIG. 8, and both the heating wire 21 and the heating wire 22 are de-energized until time t5. During the period from time t4 to time t5, floor heating is performed by gradually releasing the amount of heat stored in the heat storage material 4. As shown in FIG. 8, the switch SW3 is turned on at time t5, and the heating wire 21 is energized by the power from the AC power source M1. As a result, the temperature rises again as shown in FIG. 83, and when it reaches the upper limit discrimination level l3 at time t6, the switch SW3 is turned off again as shown in FIG. 82, and the heating wire 21 is de-energized. Therefore, the temperature decreases again, and at time t7, the lower limit discrimination level is reached.
When l4 is reached, switch SW3 is turned ON again. After that, this series of operations will be repeated again at the time.
By repeating the heating until t1, the heating temperature is approximately maintained at a temperature K2 near the melting point temperature.

In this way, in this embodiment, daytime heating can be performed using low-cost late-night electricity.
Furthermore, since a large amount of heat is required for temperature fluctuations exceeding the melting point K0 of the heat storage material 4, temperature fluctuations are slow and comfortable. Moreover, the comfortable temperature maintenance period when the temperature drops is also maintained for a relatively long time. Furthermore, the heat insulating cushion layer prevents heat from radiating downward, making it possible to increase thermal efficiency. Further, since the heating wire 22 powered by the nighttime AC power supply M2 is disposed between the heat storage layer 40 and the heat insulating cushion layer 3, heat can be efficiently transferred to the heat storage material 4.

The heating device according to the present invention is not only used for floor heating, but can also be widely used as a device for heating by being attached to a surface such as a ceiling or a wall.

Effects As described above, according to the present invention, the heat storage material 4 included in the heat storage layer 40 is heated to a temperature K1 higher than its melting point K0.
In addition, since the second heating wire 22 is energized and heated to melt it, the heat storage material 4
It is possible to heat the material 4 at the same time as heating, and when the power is turned on after heating, the latent heat of the heat storage material 4 can be used to take the heat. In addition, the second heating wire 22
is disposed between the heat storage layer 40 and the heat insulation layer 3, so the heat insulation layer 3 prevents heat from being radiated downward, and the generated heat can be efficiently transmitted to the heat storage layer 40. Therefore, consumption of electrical energy can be reduced as much as possible.

Since the heat storage layer 40 can store a large amount of thermal energy due to the latent heat of the heat storage material 4, daytime heating can be achieved by heating the second heating wire 22 using low-cost late-night electricity. It is possible to reduce the cost required for heating.

A first heating wire 21 is disposed above the heat storage layer 40, and the melting point of the heat storage material 4 is lowered by energizing the heat storage layer 40.
Since it is possible to maintain the temperature K2 near K0,
Heating can be continued even after the heat stored in the heat storage material 4 is radiated. When the heating temperature exceeds the melting point K0 of the heat storage material 4, it is absorbed as latent heat by the heat storage material 4, so that the heating temperature by the first heating wire 21 is unlikely to exceed the melting point K0. Therefore, even if the carpet layer 5 is touched by the human body, there is no risk of low-temperature burns, and the safety is high. Further, since heat is transferred to the surface of the heating device through the carpet layer 5, heating can be rapidly performed by energizing the first heating wire 21.

[Brief explanation of drawings]

FIG. 1 shows a heating device 1 having the basic configuration of the present invention.
FIG. 2 is a cross-sectional view taken from the cutting plane line - in FIG. 1, FIG. 3 is a block diagram showing the control mechanism for controlling the heating temperature of the heating device, and FIG. A graph showing the conduction cut off state of SW2 and the related temperature increase state, FIG. 5 is a plan view of the heater 20 according to an embodiment of the present invention, and FIG.
The figure is a sectional view taken from the cutting plane line - in FIG. 5, FIG. 7 is a block diagram showing the control mechanism that controls the heating operation of the heater 20, and FIG.
It is a graph which shows the cutoff state of SW4 and the temperature rise state related to this. 1,20...Heater, 4...Heat storage material, 6,2
1, 22... Heating wire, 7, 23, 24... Temperature detection means, 10... Processing circuit, 11... Clock means,
SW1, SW2, SW3, SW4...Switch, M
1, M2...AC power supply.

Claims (1)

[Claims] 1. (a) A flat heat storage layer 40 including a heat storage material 4 having a melting point K0 near the heating temperature; is heated so that the temperature is approximately maintained at a temperature K2 near the melting point K0.
(c) a second heating wire 21 disposed below the heat storage layer 40 for heating the heat storage layer 40 so that the temperature of the heat storage layer 40 is approximately maintained at a temperature K1 equal to or higher than the melting point K0;
(d) a felt carpet layer 5 laminated on the upper side of the first heating wire 21; (e) a heat insulating material laminated on the lower side of the second heating wire 22. A planar heating device characterized by comprising a heat insulating layer 3 consisting of.