KR20240016000A - Heat control device and method of electric mat - Google Patents

Abstract

The present invention relates to a heat quantity control device for an electric mat, comprising: a plurality of heating zones divided into a mat and heated individually with heating wires built into the mat; A temperature sensor provided on the mat to measure the temperature of the heating areas; and a temperature controller including a mode selection unit that selects the heating area and sets the target temperature, a control unit that controls power supply to the heating area according to the selection of the mode selection unit, and a power supply unit that supplies power to the heating area. In the heating area selected through the mode selection unit, the amount of heat generated is controlled through power changes while the power supply is maintained.

Description

Heat control device and method of electric mat {Heat control device and method of electric mat}

The present invention relates to a heat quantity control device and control method for an electric mat, and more specifically, to an electric mat that divides the mat into a plurality of heating zones and stably controls the heat amount in each heating zone while minimizing power loss. It relates to heat control devices and control methods.

In general, electric mats include electric blankets, electric blankets, and electric blankets that 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. Electric mats are still widely used today due to their simple structure and ease of use.

Existing electric mats have one temperature controller and one heating wire built in, regardless of whether they are for one person or two people. In the case of these electric mats, the entire mat generates heat equally, so if there is only one user, heat is generated in unnecessary parts, resulting in increased power consumption. 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, an electric mat with an independent heating area has been developed and used so that two people can use one mat at the same time. By dividing the heating zone into multiple areas and allowing each to be controlled independently, unnecessary power consumption that occurs when only one person uses the mat on a two-person mat can be reduced, and when two people use it at the same time, they can comfortably adjust to their individual constitutions and desired temperature. There are advantages to using it.

Meanwhile, electric mats are used on the principle that heating wires for heat generation are wired inside and when power is applied to the heating wires, the current flowing through the heating wires generates heat by the resistance of the heating wires. The temperature of the heating wire continues to rise when power is applied, and if there is no means to control it, the temperature may rise above the user's desired temperature. If the heat generation continues in this state, a short circuit or fire may occur.

Commonly used electric mats are equipped with temperature control means to control the temperature so that the temperature does not rise any further when the temperature reaches a specific temperature desired by the user. The temperature control means places a temperature sensing means inside the mat to detect temperature changes in the mat, and measures the temperature of the mat through the temperature sensing means. When the measured temperature reaches the specific temperature desired by the user, the power supply is stopped to prevent the temperature from rising any further. When the temperature of the mat falls below the specific temperature desired by the user, the temperature is supplied again to maintain a constant temperature. Temperature control is mainly used to control the temperature.

However, in the case of a conventional method of completely turning off the power and then turning it back on to maintain the temperature, power loss is bound to increase as the on/off cycle is repeated.

The present invention was developed to solve the problems of the prior art as described above. By dividing the heating area, only the area needed by the user can be heated, and the amount of heat in each divided area can be stably controlled while minimizing power loss. The purpose is to provide a heat control device and control method for an electric mat.

A device for controlling the amount of heat of an electric mat according to a preferred embodiment of the present invention for achieving the above object includes a plurality of heating zones that are formed in segments on the mat and each has a heating wire built into it to be individually heated; A temperature sensor provided on the mat to measure the temperature of the heating areas; and a temperature controller including a mode selection unit that selects the heating area and sets the target temperature, a control unit that controls power supply to the heating area according to the selection of the mode selection unit, and a power supply unit that supplies power to the heating area. In the heating area selected through the mode selection unit, the amount of heat generated is controlled through power changes while the power supply is maintained.

The temperature sensor includes a heating temperature sensor that is located adjacent to the heating wire and measures the heating temperature of the heating wire.

The mode selection unit includes a heating temperature mode that sets the heating temperature of the heating element.

When selecting the heating temperature mode, the current temperature of the heating wire is measured through the heating temperature sensor regardless of the external conditions of the mat. If the measured temperature does not reach the set temperature, the heating wire continues to generate heat, and the difference between the measured temperature and the set temperature is measured. Correspondingly, heat generation is controlled.

The temperature sensor further includes a surface on sensor installed on the surface of the mat to measure the mat surface temperature.

The mode selection unit includes a surface temperature mode that sets the surface temperature of the mat.

When selecting the surface temperature mode, the heat generation amount of the heating line is controlled to change according to external conditions acting on the mat surface.

The device for controlling the amount of heat of an electric mat according to a preferred embodiment of the present invention further includes a plurality of pressure sensors provided in each heating zone to measure the pressure applied to the mat by the user.

The mode selection unit further includes a pressure response mode that controls the heating temperature of each heating zone in response to changes in pressure applied to the mat from the user.

When selecting the pressure response mode, the heating area to which the highest pressure is applied is controlled to be heated to a relatively high temperature, and the heating area to which relatively low pressure is applied is controlled to be heated to a low temperature.

A method of controlling the amount of heat of an electric mat according to a preferred embodiment of the present invention includes the steps of a) preparing by turning on the power of the temperature controller; b) selecting a desired heating area among a plurality of heating areas through the mode selection unit of the temperature controller and selecting an additional operating mode; c) setting the target temperature of the selected heating zone; d) heating the selected heating zone; e) measuring the current temperature of the heating zone through a temperature sensor; e) comparing the set temperature of the heating zone with the current temperature; f) in the case of a heating area where the current temperature has reached the set temperature, the primary heat quantity control for target temperature control is terminated; and g) in the case of a heating area where the current temperature does not reach the set temperature, heating the heating area while continuously supplying power to the heating element and controlling the amount of power until the target temperature is reached.

The mode selection unit includes a heating temperature mode that sets the heating temperature of the heating wire. When the heating temperature mode is selected, the current temperature of the heating wire is measured through a heating temperature sensor regardless of the external conditions of the mat, and the measured temperature is at the set temperature. If it is not reached, the heating element continues to generate heat, and heat generation is controlled in response to the difference between the measured temperature and the set temperature.

The mode selection unit includes a surface temperature mode that sets the mat surface temperature reflecting changes in the conditions of the mat surface. When the surface temperature mode is selected, the surface temperature is measured through a surface temperature sensor at a specific point in time when there are no external conditions on the mat surface. Based on the relationship between the mat surface temperature and the temperature of the heating wire measured through the heating temperature sensor, the heat generation amount of the heating wire changes according to the change in the relationship between the mat surface temperature value and the temperature value of the heating wire measured when external conditions act on the mat surface. to adjust the mat surface temperature to the set temperature.

The mode selection unit includes a pressure response mode that controls the heating temperature of each heating zone in response to changes in pressure applied to the mat from the user. When selecting the pressure response mode, the heating zone to which the highest pressure is applied is relatively The heating area is heated to a high temperature, and a heating area to which a relatively low pressure is applied based on this heating area is heated to a low temperature.

According to the heat control device and control method of the electric mat of the present invention, the following effects can be obtained.

First, the heating area of the mat is divided into a plurality of areas and the heating temperature is controlled for each, so when two people use it, there is an advantage that they can use it according to their individual constitution or desired temperature. In addition, when only one person uses it, unnecessary power consumption can be reduced because only the necessary parts are heated.

Second, in the process of raising and maintaining the heating area of the mat to the target temperature, the heat generation amount is controlled by changing the amount of power while continuously supplying power without turning the power on/off, thereby reducing unnecessary power consumption.

Third, by allowing selection of various modes such as heating temperature mode, surface temperature mode, and pressure response mode, various needs of customers can be met and unnecessary power consumption can be minimized.

Figure 1 is a configuration diagram showing a heat quantity control device for an electric mat according to a preferred embodiment of the present invention.
FIG. 2 is a diagram showing the configuration of the mode selection unit shown in FIG. 1.
Figure 3 is a diagram showing how the heating area is divided into various ways on the mat.
Figure 4 is a plan view of a portion of the mat cut away to show the temperature sensor mounted on the inside and surface of the mat.
Figure 5 is a diagram showing a pressure sensor mounted on a mat.
Figure 6 is a diagram schematically showing a process diagram according to a method for controlling the amount of heat of an electric mat according to a preferred embodiment of the present invention.
Figure 7 is a flowchart specifically showing the process of controlling the amount of heat through the method of controlling the amount of heat of the electric mat according to a preferred embodiment of the present invention.
Figure 8 is a diagram showing the alternating control when the heat quantity is controlled simultaneously in a plurality of heating zones through the heat quantity control method of the electric mat according to another embodiment of the present invention.

Hereinafter, the heat quantity control device and control method of an electric mat according to a preferred embodiment of the present invention will be described in detail with reference to the attached drawings.

Figure 1 of the attached drawing is a configuration diagram showing a heat quantity control device for an electric mat according to a preferred embodiment of the present invention.

As shown, the heat quantity control device of the electric mat according to a preferred embodiment of the present invention includes a plurality of heating zones 20 formed on the mat 10 and temperature sensors 30 and 40 mounted on the mat 10. ), a pressure sensor 50 mounted on the mat 10, and a temperature controller 60 connected to the mat 10.

The heating area 20 can be divided into various shapes on the mat 10, and each heating line 21 is built into the mat 10 to be individually heated. The partition form and detailed description of the heating area 20 will be described later.

The temperature sensors 30 and 40 measure the heating temperature of the heating wire 21 built into the mat 10 and the surface temperature of the mat 10, and are comprised of the heating temperature sensor 30 and the surface temperature sensor 40. It is composed. The heating temperature sensor 30 is provided adjacent to the heating wire 21 and measures the heating temperature around the heating wire 21. The surface temperature sensor 40 is provided on the surface of the mat 10 and measures the surface temperature of the mat 10.

The pressure sensor 50 is provided in each heating area 20 of the mat 10 and measures the pressure applied to the mat 10 by the user when the user uses the mat 10. The arrangement form and detailed description of the pressure sensor 50 will be described later.

The temperature controller 60 controls the process in which power supplied from the outside is supplied to each device and the heating line 21 of the heating area 20, and includes a mode selection unit 61, a control unit 62, and a power source. Includes a supply unit (63). The mode selection unit 61 selects various operation modes, such as selection of the heating area 20 and target temperature setting. The control unit 62 controls the entire process from supplying power from the outside to heating the mat 10. The power supply unit 63 controls the amount of current supplied to the heating line 21 of each heating area 20 through the temperature controller 60.

FIG. 2 of the attached drawings is a diagram showing the configuration of the mode selection unit shown in FIG. 1.

The mode selection unit 61 allows the user to select various operation modes, including heating area selection mode 611, heating temperature mode 612, surface temperature mode 613, time setting mode 614, and pressure response mode. Includes (615).

The heating area 20 to be heated can be selected through the heating area selection mode 611. Only one heating area 20 may be selected, or a plurality of heating areas 20 may be selected.

Through the heating temperature mode 612, the temperature of the heating line 21 in the heating area 20 is set and controlled to be maintained for a certain period of time regardless of the outside of the mat 10 or user conditions.

Through the surface temperature mode 613, the surface temperature of the mat 10 is set and controlled to be maintained for a predetermined period of time in response to the outside of the mat 10 or user conditions. To control the surface temperature of the mat 10, the amount of heat generated by the heating line 21 is controlled in conjunction with external or user conditions.

The heating time of the selected heating area 20 can be set through the time setting mode 614.

The heating temperature of the heating area 20 is controlled to change in response to a change in pressure applied to the mat 10 by the user through the pressure response mode 615.

Figure 3 of the attached drawings is a view showing how the heating area is divided into various ways on the mat.

As shown in (a) of FIG. 3, the heating area 20 may be divided into left and right halves on the mat 10, and may be divided into upper and lower halves as shown in (b), and in (c) It may be divided into four parts as shown. On the other hand, by further dividing the heating area divided into four parts into small heating areas as in (d), heating may be controlled for each large heating area or may be subdivided into small heating areas. . The heating area 20 is not limited to the division example shown in the drawing and may be divided into various forms.

A heating element 21 is built into each heating area 20 to perform individual heating. Of course, in the case of heating areas 20 that are heated simultaneously, some of the heating lines 21 may be shared. In this case as well, the power supply to the shared heating line 21 can be cut off and heating can be controlled for each heating area 20.

As described above, the heating area 20 to be heated is selected through the heating area selection mode 611 that constitutes the mode selection unit 61 of the temperature controller 60.

Figure 4 of the attached drawing is a plan view of a part of the mat cut away to show the temperature sensor mounted on the inside and surface of the mat.

The heating temperature sensor 30 is provided adjacent to the heating wire 21 and measures the heating temperature around the heating wire 21. As described above, the heating areas 20 are provided with respective heating lines 21, and a heating temperature sensor 30 is also provided for each heating line 21 to measure the heating temperature of each heating line 21. . A plurality of heating temperature sensors 30 are installed at intervals along the heating line 21 to measure the temperature throughout the heating line 21.

The surface temperature sensor 40 is provided on the surface of the mat 10 and measures the surface temperature of the mat 10. Like the heating temperature sensor 30, a plurality of surface temperature sensors 40 are provided for each heating zone 20 and measure the temperature for each heating zone 20. The surface temperature sensor 40 is evenly distributed in each heating zone 20 and measures the temperature of the heating zone 20 as a whole.

As described above, the mode selection unit 61 of the temperature controller 60 includes a heating temperature mode 612.

When selecting the heating temperature mode 612, the current temperature of the heating wire 21 is measured through the heating temperature sensor 30 regardless of the external conditions of the mat 10, and if the measured temperature does not reach the set temperature, the heating wire (21) is continuously measured. 21) generates fever. By controlling the amount of power in response to the difference between the measured temperature and the set temperature, the heating temperature of the heating line 21 is adjusted to the set temperature.

As described above, the mode selection unit 61 of the temperature controller 60 includes the surface temperature mode 613.

In the surface temperature mode 613, when the conditions of the surface of the mat 10 change, the heating temperature of the heating line 21 changes accordingly. In other words, when a thick and warm blanket is covered on the surface of the mat 10 compared to when a thin blanket is covered, the surface temperature of the mat 10 becomes relatively higher, and when a person is lying on the mat 10 than when there is no person, there are two people rather than one person. When a person lies down, the surface temperature of the mat 10 becomes relatively high.

In this case, even if the heat generation amount of the heating line 21 is reduced, the surface temperature of the mat 10 relatively easily reaches the set temperature. Therefore, unnecessary power loss can be reduced.

Figure 5 of the attached drawing is a diagram showing a pressure sensor mounted on a mat.

As described above, each heating area 20 is provided with a plurality of pressure sensors 50 that measure the pressure applied to the mat 10 by the user when the user lies down or sits on the mat 10.

The pressure sensor 50 is provided for each heating area 20, and may be provided one at a time, or may be provided in multiple units to precisely measure pressure.

As described above, the mode selection unit 61 of the temperature controller 60 is equipped with a pressure response mode 615 that controls the heating temperature of each heating area 20 in response to the change in pressure applied to the mat 10 by the user. is included.

When the pressure response mode 615 is selected, the heating area where the user's body is mostly located at the time of use is heated to a relatively high temperature compared to the heating area where the user's body is mostly located. In this way, unnecessary power loss can be reduced by actually increasing the temperature of the part used by the user and lowering the temperature of other parts.

When the pressure response mode 615 is selected, the heating temperature of the corresponding heating area 20 changes in response to a change in the user's position on the mat 10.

Figure 6 of the attached drawings is a diagram schematically showing a process diagram according to a method for controlling the heat quantity of an electric mat according to a preferred embodiment of the present invention, and Figure 7 is a diagram schematically showing a process chart according to a method for controlling the heat quantity of an electric mat according to a preferred embodiment of the present invention. This is a flowchart that specifically shows the process of controlling calories.

As shown in Figure 6, the method of controlling the amount of heat of an electric mat according to a preferred embodiment of the present invention includes a preparation step (S10), an operation mode selection step (S20), a target temperature setting step (S30), and a heating zone heating step. (S40), a current temperature measurement step (S50), a set temperature comparison step with the current temperature (S60), and a heat quantity control termination step (S70).

In the preparation step (S10), when the user turns on the power button (not shown) provided on the temperature controller 60, power is supplied to the temperature controller 60, allowing the user to select an operation mode.

In the operation mode selection step (S20), the heating area to be heated is selected and then the desired operation mode is selected from among various additional operation modes. Additional operating modes include exothermic temperature mode (612), surface temperature mode (613), and pressure response mode (615). The operation mode selection method can be either analog or digital.

In this embodiment, the operation mode is selected through a display (not shown) provided on the temperature controller 60, and when each operation mode is selected based on this embodiment, the subsequent control process will be examined. .

When selecting fever temperature mode (612)

The user selects the heating area to be heated, selects the heating temperature mode 612 among the additional operation modes, and then sets the temperature and time of the heating line 21.

When the target temperature and heating time of the heating element 21 are set and the start button (not shown) is pressed, power is supplied to the selected heating area 20 and heating begins.

While heating of the heating area 20 is in progress, the heating temperature sensor 30 measures the heating temperature around the heating line 21, and goes through a process of repeatedly comparing this with the target set temperature.

By comparing the set temperature and the measured temperature, if the measured temperature is equal to or higher than the set temperature, the heat quantity control of the corresponding heating line 21 is primarily terminated, and if the measured temperature is lower than the set temperature, the heat of the corresponding heating line, that is, the heating area, is terminated. Continue heating.

While the heat quantity control for the heating line 21 of the corresponding heating area is in progress, the heat quantity change is achieved through the power quantity change in the process of continuously supplying power. In particular, the set temperature and the currently measured temperature are repeatedly compared, and the amount of heat generated is controlled by changing the amount of power corresponding to the ratio of the two temperature differences.

Meanwhile, even if the primary heat control is terminated because the measured temperature of the heating element 21 is equal to or higher than the target temperature, secondary heat quantity control is performed to maintain the temperature steadily for a preset time. In this process, the temperature is kept constant by controlling the amount of heat generated through changes in the power of the heating wire 21.

When selecting surface temperature mode (613)

The user selects the heating area to be heated, selects the surface temperature mode 613 among the additional operation modes, and then sets the surface temperature and time of the mat 10.

When the target surface temperature and heating time of the mat 10 are set and a start button (not shown) is pressed, power is supplied to the selected heating area 20 and heating begins.

While heating of the heating area 20 is in progress, the surface temperature sensor 40 measures the temperature of the surface of the mat 10, and goes through a process of repeatedly comparing this with the target set temperature.

By comparing the set temperature and the measured temperature, if the measured temperature is equal to or higher than the set temperature, the heat quantity control of the corresponding heating line 21 is primarily terminated, and if the measured temperature is lower than the set temperature, the heat of the corresponding heating line, that is, the heating area, is terminated. Continue heating.

Since the subsequent process is the same as the heating temperature mode 612, description will be omitted.

Meanwhile, external conditions act on the surface of the mat 10, and the surface temperature may change depending on the external conditions. For example, when a thick and warm blanket is covered on the surface of the mat 10 rather than a thin blanket, the surface temperature of the mat 10 becomes relatively higher, and when a person is lying on the mat 10 than when there is no person, there are two people rather than one person. When a person lies down, the surface temperature of the mat 10 becomes relatively high.

Temperature-related conditions act in both directions on the surface of the mat 10. That is, the internal temperature condition caused by the heat generated by the heating line 21 is given at the lower part, and the external temperature condition caused by the blanket or the user is given at the upper part.

Therefore, assuming that there is no external temperature condition given to the surface of the mat 10, the same operation as the heating temperature mode 612 is performed because the amount of heat loss generated while heat is transferred from the heating line 21 to the surface of the mat 10 is constant. It can be called a mode. However, in the surface temperature mode 613 where external temperature conditions are given, the external temperature conditions may change at any time, so the heat amount control of the heating line 21 must also change at any time in order to adjust the target surface temperature of the mat 10 accordingly. .

When selecting pressure response mode (615)

The user selects the heating area to be heated, selects the pressure response mode 615 among the additional operation modes, and then sets the heating temperature/time of the heating line 21 or sets the surface temperature and time of the mat 10. . In the pressure response mode 615, the temperature of the heating line 21 or the surface temperature and time of the mat 10 are set.

At this time, the target set temperature may be set differentially between a plurality of heating areas to be heated, or may be set differentially for each part of the same heating area.

In other words, the target temperature can be set differently even in the same heating area depending on the range in which the user actually uses the mat. The target temperature can be set high in the area where the user's weight is placed, and the target temperature can be set low in the area where the user's weight is not placed.

For example, by setting the target temperature in two stages, the heating line or mat surface temperature is set as high as 50℃ in the area where the user's weight is placed, and the heating line or mat surface temperature is set as low as 30℃ in the area where the user's weight is not placed. You can set it. The target temperature setting step can be modified into various steps other than step 2.

Therefore, the target temperature setting in the pressure response mode 615 is set for each stage, but it is not limited to this and the target temperature difference for each stage is set consistently in advance so that the user can only select the highest target temperature or the lowest target temperature. It can also be configured to automatically set the target temperature for each stage.

When the target temperature and heating time of the surface of the heating wire 21 or the mat 10 are set and the start button (not shown) is pressed, the pressure acting on the surface of the mat 10 is measured through the pressure sensor 50, and the selected heating Power is supplied to zone 20 and heating begins.

The target temperature for each part in the selected heating area 20 is automatically set according to the pressure measured through the pressure sensor 50, and the amount of power supplied to each part varies accordingly. In areas where high pressure is applied, the target temperature is set high and the amount of power supplied increases, and in areas where pressure is relatively low or not applied, the target temperature is set low and the amount of power supplied is reduced.

As the user moves on mat 10, the high target temperature zone may change. This is automatically converted according to the pressure measured by the pressure sensor 50.

The heating temperature sensor 30 or the surface temperature sensor 40 measures the heating temperature of the heating wire 21 or the temperature of the surface of the mat 10, and goes through a process of repeatedly comparing this with the target set temperature.

By comparing the set temperature and the measured temperature, if the measured temperature is equal to or higher than the set temperature, the heat quantity control of the corresponding heating line 21 is primarily terminated, and if the measured temperature is lower than the set temperature, the heat of the corresponding heating line, that is, the heating area, is terminated. Continue heating.

Since the subsequent process is the same as the heating temperature mode 612 and the surface temperature mode 613, description will be omitted.

FIG. 8 of the attached drawings is a diagram showing alternate control when simultaneously controlling the heat amount of a plurality of heating zones through the heat amount control method of an electric mat according to another preferred embodiment of the present invention. Here, the two heating zones are referred to as zone A and zone B, respectively.

As shown, according to another embodiment of the present invention, the power supplied from the temperature controller 60 is not supplied simultaneously to zones A and B, but is supplied sequentially, and is turned on according to a set time (preferably 6 seconds). )/OFF can be alternately controlled in a repetitive manner.

That is, when the power supply to zone A is turned on, the power supply to zone B is turned off. When the power supply to zone A is turned off, the power supply to zone B is turned on. In this way, in zones A and B, power is supplied using an alternating control method in which the power is turned on and off repeatedly.

The alternating cycle of power supplied to zones A and B is determined by the alternating time input through the alternating time input unit (not shown) of the temperature controller 60. It is desirable to determine the alternating time within a temperature range that can quickly reach the set temperature while minimizing temperature deviation when power is supplied to the heating wire 21.

As described above, the heat control device and control method of the electric mat according to the 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.

10: Mat 20: Heating area
21: heating line 30: heating temperature sensor
40: surface temperature sensor 50: pressure sensor
60: Temperature controller 61: Mode setting unit
62: control unit 63: power supply unit
611: Heating area selection mode 612: Heating temperature mode
613: Surface temperature mode 614: Time setting mode
615: Pressure response mode

Claims (14)

A plurality of heating zones are formed in segments on the mat and each has a heating element built into the mat to be individually heated;
A temperature sensor provided on the mat to measure the temperature of the heating areas; and
A temperature controller including a mode selection unit that selects the heating area and sets a target temperature, a control unit that controls power supply to the heating area according to the selection of the mode selection unit, and a power supply unit that supplies power to the heating area; Includes,
A heat quantity control device for an electric mat, characterized in that the heat generation amount is controlled through a change in power while the power supply is maintained in the heating area selected through the mode selection unit. According to claim 1,
The temperature sensor is located adjacent to the heating line and includes a heating temperature sensor that measures the heating temperature of the heating line. According to clause 2,
The mode selection unit includes a heating temperature mode for setting the heating temperature of the heating line. According to clause 3,
When selecting the heating temperature mode, the current temperature of the heating wire is measured through the heating temperature sensor regardless of the external conditions of the mat, and if the measured temperature does not reach the set temperature, the heating wire continues to generate heat, and the measured temperature and the set temperature are measured. A heat quantity control device for an electric mat, characterized in that heat generation is controlled in response to the difference between the two. According to clause 4,
The temperature sensor is installed on the surface of the mat and further includes a surface on sensor that measures the surface temperature of the mat. According to clause 5,
The mode selection unit includes a surface temperature mode for setting the surface temperature of the mat, a heat quantity control device for the electric mat. According to clause 6,
When selecting the surface temperature mode,
A heat quantity control device for an electric mat, characterized in that when external conditions act on the surface of the mat, the heat quantity of the heating wire is controlled to change accordingly. According to any one of claims 2 to 7,
A heat quantity control device for an electric mat, further comprising a plurality of pressure sensors provided in each of the heating zones to measure the pressure applied to the mat by the user. According to clause 8,
The mode selection unit,
A pressure response mode that controls the heating temperature of each heating zone in response to changes in pressure applied to the mat by the user. A heat control device for an electric mat, further comprising a. According to clause 9,
When selecting the pressure response mode, the heating area to which the highest pressure is applied is controlled to be heated to a relatively high temperature, and the heating area to which relatively low pressure is applied is controlled to be heated to a low temperature. Calorie control device. a) Preparing by turning on the power of the temperature controller;
b) selecting a desired heating area among a plurality of heating areas through a mode selection unit of the temperature controller and selecting an additional operating mode;
c) setting the target temperature of the selected heating zone;
d) heating the selected heating zone
e) measuring the current temperature of the heating zone through a temperature sensor;
e) comparing the set temperature of the heating zone with the current temperature;
f) in the case of a heating area where the current temperature has reached the set temperature, the primary heat quantity control for target temperature control is terminated; and
g) In the case of a heating area where the current temperature does not reach the set temperature, heating the heating area while continuously supplying power to the heating element and controlling the amount of power until the target temperature is reached; including, heat amount of the electric mat Control method. According to claim 11,
The mode selection unit includes a heating temperature mode that sets the heating temperature of the heating line,
When selecting the heating temperature mode, the current temperature of the heating wire is measured through the heating temperature sensor regardless of the external conditions of the mat, and if the measured temperature does not reach the set temperature, the heating wire continues to generate heat, and the measured temperature and the set temperature are measured. A method of controlling the amount of heat in an electric mat, characterized in that the amount of heat is controlled in response to the difference between the two. According to claim 11,
The mode selection unit includes a surface temperature mode that sets a mat surface temperature reflecting changes in conditions of the mat surface,
When selecting the surface temperature mode,
At a specific point in time when there are no external conditions on the mat surface, the relationship between the mat surface temperature measured through the surface temperature sensor and the temperature of the heating line measured through the heating temperature sensor is used as the basis, and external conditions act on the mat surface. A method of controlling the heat amount of an electric mat, characterized in that the heat generation amount of the heating wire is changed according to the change in the relationship between the mat surface temperature value measured and the temperature value of the heating wire to adjust the mat surface temperature to the set temperature. The method of claim 12 or 13,
The mode selection unit includes a pressure response mode to control the heating temperature of each heating zone in response to changes in pressure applied to the mat by the user,
When selecting the pressure response mode, the heating area to which the highest pressure is applied is heated to a relatively high temperature, and the heating area to which a relatively low pressure is applied based on this heating area is heated to a low temperature. , Method of controlling heat content of electric mat.

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