KR20230134794A - Heating device of mat and its control method - Google Patents

Abstract

The present invention relates to a heating device for a mat that supplies power to divided areas, formed to be divided on a mat, in an alternating manner to perform individual heating, wherein the heating device for the mat comprises: a plurality of heating areas formed to be divided on the mat and individually heated; and a controller that individually controls the power supply to each heating area. The controller alternately supplies/blocks (on/off) power through alternating control between the heating areas when at least two of the heating areas are in an operation condition. Electricity charge can be decreased.

Description

Heating device of mat and its control method {Heating device of mat and its control method}

The present invention relates to a mat heating device and its control method. More specifically, a mat heating device and its control method for forming a mat into divided areas and supplying power to each of the divided areas in an alternating manner to individually heat them. It's about.

In general, thermal mats include electric blankets, electric blankets, electric blankets, etc., which are mainly used for heating in the winter. Heating wires are placed at predetermined intervals inside the mattress made of a sheet-shaped fiber material, and the heating wires are supplied with a power supply. When applied, heat is generated and the temperature increases. Thermal mats are still widely used today due to their simple composition and ease of use.

Existing heating mats have one temperature control switch and one heating wire built in, regardless of whether they are for one person or two people. In the case of such a heating mat, since the entire mat generates heat equally, there is a problem in that if there is only one user, heat is generated in unnecessary parts and power consumption increases. Additionally, when two people use it, there is the inconvenience of not being able to use it according to each person's constitution or desired temperature and having to use it at the same temperature.

To solve this problem, a heating mat with an independent heating area has been developed and used so that two people can use one mat at the same time. Prior art related to this is disclosed in prior documents such as Domestic Patent No. 10-1970796, Domestic Patent No. 10-2223454, Domestic Patent No. 10-0761783, and Domestic Published Patent No. 10-2004-0096459. there is.

In the case of the technology disclosed in prior literature, the heating zone is divided into multiple areas and each can be controlled independently, thereby reducing unnecessary power consumption that occurs when only one person uses a two-person mat, and when two people use it simultaneously, each It has the advantage of being easy to use according to your body type or desired temperature.

Despite having these advantages, according to the prior art, there is still a problem that unnecessary power consumption occurs. For reference, Figure 1 is a diagram showing the thermal efficiency that can be obtained when power is supplied to divided heating areas of the mat according to the prior art.

For example, if there are two divided heating zones 10 and 11 as shown in FIG. 1 and the power supplied through the regulator 20 is 100W, when heating the two heating zones 10 and 11 simultaneously, each heating zone 50W of power is supplied to (10) and (11). Since thermal efficiency can be obtained in response to the amount of power supplied, if the expected thermal efficiency through 100W of power supplied through the regulator 20 is 100%, the thermal efficiency actually obtainable in each heating zone 10 and 11 is At 50% each, the total thermal efficiency becomes 100%, which is the same as the expected thermal efficiency.

According to this prior art, when the power demand from the divided heating zone increases, the amount of power supplied from the outside to the divided heating zone must also increase proportionally. Therefore, there is a problem that an additional power regulator must be installed or replaced with a power regulator with a larger capacity. In addition, there is a problem in that the power consumption value increases and the electricity bill increases.

The present invention was developed to solve the problems of the prior art as described above. When the mat is divided into a plurality of heating zones and heated, even if the power demand required from the divided zones increases, stable power supply is provided without additional equipment or an increase in electricity costs. The purpose is to provide a mat heating device and its control method that can expect heating efficiency.

A mat heating device according to a preferred embodiment of the present invention for achieving the above object includes a plurality of heating zones divided and individually heated on the mat; and a controller that individually controls the power supply to each heating zone. The controller controls the supply/blocking (on/off) of power between the heating zones when at least two of the heating zones are in operation condition. It is characterized by alternating control.

The mat heating device according to a preferred embodiment of the present invention further includes a temperature sensor that measures the current temperature of each of the heating zones, and the controller measures the current temperature of the heating zones measured through the temperature sensor and the preset set temperature. It is characterized by individually controlling the power supply to each heating zone by comparing .

When the current temperature of the heating area reaches the set temperature, power supply is cut off under stop conditions, and when the current temperature does not reach the set temperature, power is supplied under run conditions.

Alternating control of power supply/off applied to heating zones is applied between individual heating zones, or between a plurality of groups grouped into at least one heating zone.

The alternating power control time achieved through the regulator is 5 to 7 seconds.

A method of controlling a heating device for a mat according to a preferred embodiment of the present invention includes the steps of: a) supplying power to a plurality of divided heating zones through a regulator; b) setting the target temperature of each heating zone with a controller; c) measuring the current temperature of each heating zone through a temperature sensor; d) Comparing the current temperature and the set temperature for each heating zone; e) cutting off the power supply to the heating area in a stop condition where the measured temperature has reached the set temperature; and f) when there are at least two heating zones under operating conditions in which the measured temperature does not reach the set temperature, the supply/blocking (on/off) of power supplied to the heating zones is controlled alternately between the heating zones. Includes ;

When power is supplied to the heating zones in the operating condition through step f), the entire power supplied from the controller is supplied to the individual heating zones that are in the ON state, and the entire amount of power is supplied between the heating zones in the operating condition. It takes place in turns.

The method of controlling a heating device for a mat according to a preferred embodiment of the present invention further includes the step of g) setting the control time of power alternation to 5 to 7 seconds through a regulator.

According to the heating device and its control method for the mat of the present invention, when the divided heating zones are in operating condition, power supply/cutoff is controlled alternately between the heating zones, so that power is supplied to the heating zones in the operating condition. When turned on, all of the power supplied from the regulator is supplied to the individual heating zones in the on state, and the entire amount of power is supplied alternately between the heating zones in the operating condition.

Using this control method, the thermal efficiency obtained from individual heating zones can be significantly increased compared to the prior art. That is, assuming that the power supplied through the regulator while alternating control is in progress is 100W, the entire power of 100W is supplied alternately and repeatedly to the heating zones. Therefore, while alternating control is in progress, thermal efficiency equivalent to 100W can be obtained in each heating zone, and overall thermal efficiency of 200% can be obtained.

Therefore, in the present invention, the thermal efficiency that can be obtained from a plurality of regulators in the prior art can be sufficiently obtained with one regulator, so the self-power demand increases while heating the mat, or auxiliary heating is added by providing a separate auxiliary heating device. Even so, power can be supplied stably without power expansion, and electricity bills can be prevented from rising.

Figure 1 is a diagram showing the thermal efficiency that can be obtained when power is supplied to divided heating areas of a mat according to the prior art.
Figure 2 is a configuration diagram showing a heating device for a mat according to an embodiment of the present invention.
Figure 3 is a diagram showing a temperature sensor disposed in the heating area of Figure 2.
Figure 4 is a diagram showing how the power supplied from the regulator to the heating area is alternately controlled.
Figure 5 is a diagram showing the power supply state when some of the divided areas are in a stop condition.
Figure 6 is a graph experimentally showing the temperature change of the heating wire according to the alternating time when heating using a mat heating device according to an embodiment of the present invention.
Figure 7 is an enlarged graph showing the temperature change of the heating wire in the 120-130 minute section shown in Figure 6.
Figure 8 is a graph experimentally showing the change in surface temperature of the mat according to the alternating time when the mat is heated using a heating device according to an embodiment of the present invention.
Figure 9 is an enlarged graph showing the change in surface temperature of the mat in the 120-130 minute period shown in Figure 8.
Figure 10 is a diagram showing the thermal efficiency that can be obtained using a mat heating device according to an embodiment of the present invention.
Figure 11 is a flowchart showing the process of heating by a method of controlling a heating device for a mat according to an embodiment of the present invention.
Figure 12 is a configuration diagram showing a heating device for a mat according to another embodiment of the present invention.
Figure 13 is a configuration diagram showing a heating device for a mat according to another embodiment of the present invention.

Hereinafter, a mat heating device and its control method according to preferred embodiments of the present invention will be described in detail with reference to the attached drawings.

Figure 2 is a configuration diagram showing a heating device for a mat according to an embodiment of the present invention, and Figure 3 is a diagram showing a temperature sensor disposed in the heating area of Figure 2.

As shown, the mat heating device according to an embodiment of the present invention includes two heating zones 100 and 110, a temperature sensor 200, and a controller 300.

The heating areas 100 and 110 are formed to divide the mat 1 to be heated into left and right sides, and power is supplied to each to perform individual heating. The heating areas 100 and 110 can have various embodiments, such as embedding the heating wire 120 inside a heating pipe filled with or flowing with a heat medium, or embedding the heating wire 120 in a panel. .

These heating areas 100 and 110 may be formed in a form that is divided into left and right sides of the mat 1 so that the temperature can be adjusted individually when there are two users, as shown in FIG. 2, and in another embodiment to be described later (FIG. As shown in 12), the mat 1 may be divided into upper and lower parts so that the heating temperature applied to the upper and lower body can be varied when used by one person.

A plurality of temperature sensors 200 are disposed in each heating area 100 and 110 to measure the temperature of the heating element 120. The temperature sensor 200 continuously measures the current temperature of the heating area 100 and 110 and provides the data. It is transmitted to the control unit 330 of the controller 300, which will be described later. A plurality of temperature sensors 200 are provided and arranged at intervals adjacent to the heating wire 120, and measure the temperature throughout the heating wire 120.

The controller 300 is connected to the mat 1 and fixed to the head of the bed frame, or placed on the mat 1 or on the indoor floor, and controls heating by controlling the power supply to the heating areas 100 and 110. It includes a power supply unit 310, a temperature setting unit 320, and a control unit 330.

The power supply unit 310 is configured to receive power from an external power source and individually supply power to the heating zones 100 and 110, and is automatically controlled by the control unit 330.

The temperature setting unit 320 is configured to individually set the heating temperature of each heating zone 100 and 110.

The control unit 330 is connected to various devices of the controller 300 and the temperature sensor 200 and controls the entire heating process from start to end. That is, power supply to various devices and the heating zones 100 and 110, comparison of the set temperature and the current temperature of the heating zones 100 and 110, and supply of power to various devices and the heating zones 100 and 110. Controls all operating processes, including power off.

The controller 300 is equipped with a power button (not shown) that is operated first to start heating, and is used to input the alternating control time of power supply/off when each heating zone 100 and 110 is in operation condition. An alternating time input unit (not shown) may be additionally provided.

Figure 4 is a diagram showing how the power supplied from the regulator to the heating area is alternately controlled. Here, the two heating zones 100 and 110 are referred to as A heating zone 100 and B heating zone 110, respectively.

As shown, according to the present invention, the power supplied from the regulator 300 is not supplied simultaneously to the A heating area 100 and the B heating area 110, but is supplied sequentially and is turned on/off ( OFF) is alternately controlled in a repetitive manner.

That is, when the power supply to the A heating zone 100 is turned on, the power supply to the B heating zone 110 is turned off, and when the power supply to the A heating zone 100 is turned off, the power supply to the B heating zone 110 is turned off. The power supply is turned on. In this way, in the A heating zone 100 and the B heating zone 110, power is supplied through an alternating control method in which power is turned on and off repeatedly.

The alternating cycle of power supplied to the A and B heating zones 100 and 110 is determined by the alternating time input through the alternating time input unit (not shown) of the controller 300. The alternation time is preferably determined within a temperature range that can quickly reach the set temperature while minimizing temperature deviation when power is supplied to the heating wire 120. Experimental examples of alternating times are shown in Figures 6 to 9 and will be described later.

Figure 5 is a diagram showing the power supply state when some of the divided areas are in a stop condition.

From the beginning, only one of the A and B heating areas (100 and 110) is heated, or power is supplied in an alternating control method to heat both the A and B heating areas (100 and 110), and then one of the heating areas (100) (110) is heated. When the current temperature measured in reaches the set temperature and becomes a stop condition, the power supply to one zone is turned off, as shown in FIG. 5.

The heating zone in the operating condition that has not yet reached the stop condition remains on and continues to supply power.

Figure 6 is a graph experimentally showing the temperature change of the heating wire according to the alternating time when heating the mat using an alternating heating device according to an embodiment of the present invention. Figure 7 is an enlarged graph showing the temperature change of the heating wire in the 120-130 minute section shown in Figure 6.

In this experiment, the alternating time was set at 2-second intervals in the range of 2 to 10 seconds, and all conditions except the alternating time were the same. The target set temperature of the heating element 120 is 50°C. The heating zone is divided into left and right, and the conditions of the left and right heating zones are also the same. In Figure 7, additional measurements are shown when the alternating time is 5 seconds and 7 seconds.

When the alternating time is controlled to 2 seconds (a) and 4 seconds (b), it can be seen that although the temperature change is small, the temperature of the heating wire 120 does not reach the target temperature and remains only at a slight fever even as time passes. When the alternating time is 2 seconds (a), the reaching temperature of the heating wire 120 is around 30°C, and when the alternating time is 4 seconds (b), the reaching temperature of the heating wire 120 is around 40°C.

When the alternating time is controlled to 8 seconds (d) and 10 seconds (e), the temperature change is smaller than that of normal control (f), but it is lower than when the alternating time is 5 to 7 seconds (g) (c) (h). Temperature changes appear large. If the temperature of the heating element 120 changes rapidly, power consumption increases as a result.

When the alternating time is controlled to 5 to 7 seconds (g) (c) (h), the temperature deviation appears a little larger compared to when the alternating time is 4 seconds (b), but the temperature of the heating wire 120 is the target. Since the temperature is stably controlled at around 50℃, power consumption can be minimized while achieving the desired thermal efficiency. Among the alternating time ranges of 5 to 7 seconds (g) (c) (h), the temperature change is the smallest at 6 seconds (c) and the temperature of the heating wire 120 is maintained closest to 50°C.

For reference, general control (f) is a control method that completely cuts off the power supply when the mat is heated to the set temperature and supplies power again when the mat cools. For example, if the user sets the temperature of the heating element to 50°C, power is initially supplied to the mat to heat the heating element. Afterwards, when the heating wire reaches the target temperature, the power supply to the mat is cut off. Even if the power supply is cut off, the temperature of the once-heated heating element rises higher than the target temperature and then gradually cools and decreases. Afterwards, when the heating wire falls below the target temperature, power is supplied to the mat again. However, since the heating wire does not immediately reach the target temperature, the temperature of the mat falls further and then increases again. This process is shown in general control (f) in Figure 6.

That is, in the case of general control (f), the temperature range of the heating wire is very large. Even if the power supply is cut off, the temperature of the heating wire does not fall immediately, but rather increases further and then gradually falls. Conversely, even when power is resupplied, it does not rise immediately but rather falls further and then gradually rises. In the case of general control (f), the temperature change is rapid, so power loss is inevitable.

Figure 8 is a graph experimentally showing the change in surface temperature of the mat according to the alternating time when the mat is heated using an alternating heating device according to an embodiment of the present invention. Figure 9 is an enlarged graph showing the change in surface temperature of the mat in the 120-130 minute period shown in Figure 8.

The change in surface temperature of the mat in the process of obtaining the results of FIG. 6 is shown in FIG. 8, and the change in surface temperature of the mat in the process of obtaining the results of FIG. 7 is shown in FIG. 9. The average temperature of the entire mat 1 was measured by placing a plurality of measurement sensors on the surface of the mat 1 to cover the temperature measurement of the entire mat 1.

As a result of the experiment, based on the change in surface temperature of the mat during general control (f), the mat surface temperature was low at 2 seconds (a), 4 seconds (b), 8 seconds (d), and 10 seconds (e). The temperature fluctuation deviation (slush) is not large and shows good results compared to the general control (f).

Based on the change in surface temperature of the mat during general control (f), the mat surface temperature was high at 5 seconds (g), 6 seconds (c), and 7 seconds (h), and continued to rise over time. It also shows that the temperature fluctuations are small. It can be seen that when the alternating time is 6 seconds (c), the mat surface temperature is the highest and the temperature fluctuation deviation is also the smallest.

As a result, when the alternating control time is 5 to 7 seconds, the temperature deviation is small and the mat surface temperature is high, resulting in low power loss and excellent heating efficiency. In particular, it can be seen that the alternating control time of 6 seconds is most desirable in terms of power loss and heating efficiency.

Figure 10 is a diagram showing the thermal efficiency that can be obtained using the alternating heating system of the mat according to an embodiment of the present invention.

Assuming that the power supplied through the regulator 300 while alternating control is in progress is 100W, the entire amount of power of 100W is supplied alternately and repeatedly to the A and B heating zones 100 and 110. Therefore, while alternating control is in progress, thermal efficiency corresponding to 100 W can be obtained in each heating zone (100) (110), and if the thermal efficiency that can be obtained in each of the individual heating zones (100) (110) is 100%, the overall efficiency is 200 W. % thermal efficiency can be obtained.

On the other hand, as described above, according to the prior art, when 100W of power is supplied to the two heating zones through the regulator, the power supplied to each heating zone is 50W. Therefore, in each heating zone, only thermal efficiency corresponding to 50W can be expected individually, and only 100% thermal efficiency can be obtained overall.

Therefore, assuming that all heating conditions other than the power supply method are the same, thermal efficiency can be expected to be nearly doubled simply by changing the power supply method from the constant supply method to the alternating control method.

Figure 11 is a flowchart showing the process of heating by a method of controlling a heating device for a mat according to an embodiment of the present invention.

A method of controlling a heating device for a mat according to an embodiment of the present invention includes supplying power to the heating areas 100 and 110 (S10); Setting the temperature of the heating zone 100 (110) (S20) (S21); Steps (S30) (S31) of measuring the temperature of the heating zone (100) (110); Comparing the measured temperature and the set temperature of the heating area (100) (110) (S40) (S41); Cutting off the power supply when the measured temperature of the heating area (100) (110) reaches the set temperature (S50); and alternately controlling the power supplied to the heating zones 100 and 110 until the measured temperature of the heating zones 100 and 110 reaches the set temperature.

When the user turns on the power button of the controller 300 provided at the head of the bed, power is supplied to each heating zone 100 and 110 and heating of the mat begins (S10).

Afterwards, the user sets the target temperature of each heating zone 100 and 110 through the temperature setting unit 320 of the controller 300 (S20) (S21) and sets the alternating control time through the alternating time input unit. .

The current temperature (measured temperature) of each heating zone 100 and 110 is measured through the temperature sensor 200 and continuously transmitted to the control unit 330 of the controller 300 (S30) (S31). The current temperature transmitted to the control unit 330 goes through a process of comparing with the set temperature (S40) (S41).

That is, after checking whether the currently measured temperature has reached the preset target temperature, if the target temperature has been reached, the power supply is cut off to cut off the power supply to the relevant heating area (S50). If the target temperature is not reached, power continues to be supplied, and the process of comparing the current measured temperature and the target set temperature is repeated until the target temperature is reached to check whether power supply is interrupted (S60) (S61). .

If the current measured temperature of each heating zone (100) (110) does not reach the set temperature, power is supplied alternately rather than simultaneously to all heating zones (100) (110).

That is, power supply is turned on/off in each heating zone 100 and 110 at predetermined time intervals. When the power of the A heating zone 100 is turned on, the power of the B heating zone 110 is turned off, and when the power of the A heating zone 100 is turned off, the power of the B heating zone 110 is turned on. This process is repeated.

The alternating power control time is achieved through an alternating time input unit (not shown) of the controller 300. As seen in the above-described experimental example, the temperature difference between the heating wire and the mat surface is the smallest and the target temperature can be reached as close as possible. Considering such factors, it is set between 5 and 7 seconds. Most preferably, it is set to 6 seconds.

Figure 12 is a configuration diagram showing a heating device for a mat according to another embodiment of the present invention.

The heating zones 100 and 110 divided into the mat 1 may be divided into left and right sections of the mat 1 to enable individual temperature control when there are two users, as shown in FIG. 2. When used by one person, the mat 1 may be divided into upper and lower parts so that the heating temperature applied to the upper and lower body can be varied, as shown in FIG. 12.

Figure 13 is a configuration diagram showing a heating device for a mat according to another embodiment of the present invention.

As shown, according to the mat heating device according to another embodiment of the present invention, the mat can be divided into four heating zones 100, 110, 140, and 150.

At this time, the A heating area 100 and B heating area 110 are grouped into one group, and the C heating area 140 and D heating area 150 are grouped into another group to alternately control power supply for each group. It may be possible to group the A heating area 100 and the D heating area 150 into one group and the B heating area 110 and the C heating area 140 into another group to alternately control power supply for each group. It may be possible. Not limited to this, power supply may be alternately controlled by grouping B, C, and D heating zones 110, 140, and 150 into one group and heating zone A 100 into another group.

The number of heating areas divided into divided areas and the number of heating areas forming a group can be modified in various ways depending on the shape of the mat or heating pattern.

As described above, the mat heating device and its control method according to preferred embodiments of the present invention have been described in detail with reference to the accompanying drawings, but the present invention is not limited to the above-described embodiments and may vary within the scope of the patent claims. It can be modified and implemented.

100,110,140,150; Heating zone 130; electric heating wire
200; temperature sensor 300; regulator
310; power supply unit 320; Temperature setting unit
330; control unit

Claims (8)

A plurality of heating zones are divided and individually heated on the mat; and
It includes a regulator that individually controls power supply to each heating zone,
The controller is a mat heating device, characterized in that when at least two of the heating zones are in an operating condition, the controller alternately controls power supply/blocking (on/off) between the heating zones. According to claim 1,
It further includes a temperature sensor that measures the current temperature of each of the heating zones,
The controller is a mat heating device, characterized in that it individually controls power supply to each heating zone by comparing the current measured temperature of the heating zone measured through the temperature sensor with a preset set temperature. According to claim 2,
A mat heating device in which power supply is cut off under a stop condition when the current temperature of the heating area reaches the set temperature, and power is supplied under an operating condition when the current temperature does not reach the set temperature. According to claim 1,
A heating device for a mat configured so that alternating control of power supply/off applied to the heating zones is applied between individual heating zones, or between a plurality of groups grouped into at least one heating zone. The method according to any one of claims 1 to 4,
A mat heating device, characterized in that the alternating power control time achieved through the regulator is 5 to 7 seconds. a) supplying power to a plurality of divided heating zones through a regulator;
b) setting the target temperature of each heating zone with the controller;
c) measuring the current temperature of each heating zone using a temperature sensor;
d) comparing the current temperature and the set temperature for each heating zone;
e) cutting off the power supply to the heating area in a stop condition where the measured temperature has reached the set temperature; and
f) When there are at least two heating zones under operating conditions in which the measured temperature does not reach the set temperature, the supply/blocking (on/off) of power supplied to the heating zones is controlled alternately between the heating zones; A method of controlling a heating device for a mat comprising a. According to claim 6,
When power is supplied to the heating zones in the operating condition through step f), the entire amount of power supplied from the controller is supplied to the individual heating zones that are in the ON state, and the entire amount of power is supplied to the heating zones where the operating condition is to supply the entire amount of power. A method of controlling a heating device for a mat, characterized in that it is performed alternately. According to claim 6 or 7,
g) setting the alternating power control time to 5 to 7 seconds through the regulator; a method of controlling a heating device for a mat further comprising a.

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