KR0149265B1 - Local place cooling heating control electronic temperature controller with passive, automatic fan speed controlled - Google Patents

Abstract

The present invention is to control the fan manually and automatically in the cooling and heating device, and to configure the fan switch to reduce the construction cost and to automatically control the fan and valve to match the temperature that the actual heating / cooling materials to control The present invention relates to an electronic thermostat for local cooling and heating that provides energy saving and comfortable temperature. To this end, the present invention provides a supply pipe (P) for supplying cold and hot water and a flow of cold and hot water through the supply pipe (P). For driving the fan (9) and the fan (9) for blowing air from the valve (3) for shutoff, the valve driving motor (M) for controlling the opening and closing of the valve (3), and the cooling / heating coil (4). an apparatus for controlling a district cooling and heating provided by the fan motor 10 according to the set temperature from the room temperature detecting sensor (S ₁₎ for detecting a room temperature, operating the valve driving motor (M) To open up on the valve 3 detects the temperature of the first controller and the pipe (P) for controlling such that the cold water or the hot water circulating along the supply pipe (P) with a pipe temperature sensor (S ₂₎ the The fan motor 10 is automatically controlled only when the pipe temperature is lower or higher than the set temperature when cooling or heating according to the set temperature. When the cooling and heating materials are higher than the temperature of the indoor room and the heating is low, the fan operates. The fan speed is manually controlled independently of the second control unit 12 which automatically controls the air circulation fan according to the temperature of the cooling / heating material so as to prevent the temperature from rising during cooling and falling during heating to maximize energy efficiency. Is constituted by a third control unit (13).

Description

Electronic temperature controller for local cooling / heating control with manual and automatic fan speed control

1 is a diagram illustrating an embodiment in which a regional cooling and heating control system having an electronic temperature controller of the present invention is configured.

2 is a circuit diagram illustrating an embodiment of the electronic temperature controller of the present invention.

3 is a diagram illustrating an embodiment in which a local air conditioning and heating control system is constructed with an existing mechanical temperature controller and a fan speed control switch.

* Explanation of symbols for main parts of the drawings

1: Fan Speed Control Switch 2: Temperature Controller

3: valve 4: cold Heating coil

5 valve 7 temperature controller

8: pipe temperature sensor (S ₂ ) 9: fan

10: fan drive motor 11: the first control unit

12: second control unit 13: third control unit

14: valve driving motor (M)

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electronic thermostat for local cooling and heating, and more particularly, to an electronic thermostat capable of automatically and manually controlling fan speed by including an existing fan speed control switch function in a thermostat.

Figure 3 shows an embodiment of the configuration of a conventional cooling and heating control device, the configuration and operation are as follows.

Temperature controller (2) using diaphragm or bimetal is installed to set the room temperature according to the situation so that the room temperature can be detected. Also, a pipe (P) for supplying cooling and heating materials such as cooling and heating materials, and a driver for passing or blocking cooling and heating materials flowing through the cooling and heating coils (4) in response to a temperature control signal from the regulator (2). The fan speed control switch 1 is selected to blow the wind for circulating the air from the valve (M), the valve (3), and the cooling / heating coil (4). .

First, in the case of cooling in the summer, in the case of using a normally closed valve (NC-type closed state), a cooling material such as cold air or cooling water flows into the supply pipe P, and the temperature controller 2 is set. If the room temperature is higher than the temperature, cooling should be done. Therefore, contact CB is connected and the summer and winter switch is in the EF position. Therefore, power is supplied to the motor (M) of the valve (3) to open the valve to cool the cooling / heating coil (4). Let the ash flow.

At this time, the fan speed is selected according to the selection of the fan switch 1 to circulate the cool air to enable cooling. If cooling continues and the set temperature matches the room temperature, the contact point of temperature controller (2) is C It turns to A, the power supply is cut off by the motor M of the valve 3, a valve is closed, and it blocks the flow of a cooling material to the cooling / heating coil 4. As shown in FIG.

If the valve (3) is normally open (NO) (holds the valve open when the power is not applied), the contactor D F is cold connected Heating operation is possible.

That is, if the room temperature is higher than the set temperature, the contact point is C Connected to B, the power is cut off from the motor (M) of the valve (3) and the valve (3) is left open as it is possible to cool. A, D F becomes the power supply to the motor and closes the valve (3) to cool the cooling material. Do not flow to the heating coil (4) to maintain the room temperature. In the case of heating using the valve (3) of the normal closed type (NC) in winter, the heating material flows through the supply pipe (P), and the summer and winter switching switches of the temperature controller (2) If the set temperature is higher than the room temperature as F, the contact point of the temperature controller (2) is C A, D F becomes the power supply to the motor of the valve (3) When heating material is flowed to the heating coil 4 to circulate the air of the air volume determined by the fan switch 1, the heating is performed. When the set temperature is equal to the room temperature, the contact point of the temperature controller 2 is C. B, D It becomes F, and cuts off the power supply to the motor M, closes the valve 3, blocks the heating material from flowing to the cooling / heating coil, and adjusts the room temperature.

If it is composed of a normally open valve (3), the summer and winter selector switches to summer E When the contact point F is set, the normally closed (NC) valve and the normally open (NO) valve are operated in opposite directions so that they can be heated.

The above configuration is composed of a fan and a fan switch as a means for circulating the air, the selection of the fan switch (1) having a function selection of the strong, medium, weak, off and the hassle of having to manually select the speed control of the fan If the boiler or the freezer is not operated in the middle of the night, regardless of whether the temperature of the cooling / heating material becomes higher or lower than the room setting temperature, if a person does not cut off the power, the fan keeps turning in the room and the effect of heating is provided. The effect of this may result in a waste of energy. In addition, the installation of the fan switch (1) and the temperature controller (2) separately causes the hassle and construction cost increase.

Therefore, it is an object of the present invention to solve the above problems. An electronic thermostat for controlling heating is provided.

Another object of the present invention is to control the fan manually and automatically in the cooling and heating device, and to configure the fan switch integrally, local cooling that can reduce the construction cost An electronic thermostat for controlling heating is provided.

Still another object of the present invention is to provide an electronic temperature controller for controlling energy saving and comfortable temperature by automatically stopping the fan and the valve when the cooling / heating material, which is a circulating heat medium, is below the temperature to be controlled.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 shows an example of the configuration of a regional cooling and heating control apparatus having an electronic thermostat 7 according to the present invention. In the above-described configuration of FIG. The temperature controller is configured so that the fan 9 is automatically turned on and off according to the temperature of the cooling and heating material by sensing the temperature of the cooling and heating material from the sensor 8 for integrating the structure and sensing the temperature of the pipe P. It constitutes (7). When the indoor temperature is detected from the sensor 8, the temperature controller 7 drives the valve driving motor M to open and close the valve 3 appropriately to control the cooling and heating temperatures.

2 shows a specific configuration example of the temperature controller 7 of FIG.

The temperature controller 7 controls the opening and closing of the valve 3 and the valve 3 to block the flow of cold and hot water through the supply pipe P for supplying cold and hot water and the supply pipe P. A valve driving motor (M) for controlling, a fan (9) for blowing air from the cooling / heating coil (4) and a fan driving motor (10) for driving the fan to control local cooling and heating In the apparatus, the valve driving motor (M) is operated in accordance with a temperature set from an indoor temperature detection sensor (S ₁ ) for detecting an indoor temperature to open the valve (3) to allow the cold or hot water to be supplied to the supply pipe (P). The temperature of the first control unit and the pipe (P) for controlling to be circulated along the pipe is detected by a pipe temperature sensor (S ₂ ) and automatically only when the pipe temperature is lower or higher than the set temperature according to the set temperature. The fan motor 10 to control the If the ash is higher than the room temperature and low during heating, if the fan operates, the air circulation fan is automatically operated according to the temperature of the cooling and heating materials to maximize energy efficiency by preventing the room temperature from rising and cooling down. The second control unit 12 is configured to control and the third control unit 13 to control the fan speed manually regardless of the automatic. Here, the first control unit 11, the second control unit 12 and the third control unit 13 are shown to share some of the components constituting the circuit.

Referring to the operation of the temperature controller having the above configuration in detail as follows.

In the drawing, reference numeral 11 denotes a sensor S ₁ (for example, a thermistor or a resistance change sensor may be used) and a plurality of resistors, a variable resistor VR ₁ , and a first detecting the indoor temperature to control the indoor temperature. And a second comparator U ₁ , U ₂ , and the like.

The voltage V _R input to the first comparator U ₁ may be represented by Equation (1) below.

RS ₁ is a resistance value of the sensor S ₁ dummyster.

If the output V ₂ of the first comparator (U ₁₎ output V ₁ is the "high" second comparator (U ₂₎ of, if the indoor temperature is lower than the set temperature T _S is inverted becomes "low".

Anti-U ₁ outputs of the room temperature is higher than the set temperature the first comparator (U ₁₎ is a "low" In this case the output U ₂ of the second comparator (U ₂₎ is reversed is a "high". The output of the first comparator U ₁ is connected to the AND gate U ₇ and the output of the second comparator U ₂ is connected to the AND gate U ₆ .

Reference numeral 12 designates a cold on the pipe P through which the cooling and heating materials flow in order to automatically control the control of the fan 9. A plurality of resistors (R ₁₃ to R ₁₆ , R ₂₂ , R ₂ , R ₄ , R ₉ , R ₁₂ ) and third and fourth comparators (U) are attached to the pipe by attaching a sensor 8 for detecting the temperature of the heating material. ₃ , U ₄ ), the second control unit including a variable resistor (VR ₁ ).

The voltage V _P input to the third comparator U ₃ may be expressed as in Equation 2 below.

RS ₂ is a resistance value of the sensor (S ₂ , 8) dummyster.

If the pipe if the temperature is lower than the set temperature T _S the third comparator output V ₃ is a "high" output V ₄ of the fourth comparator (U ₄₎ of the (U ₃₎ is inverted becomes "low".

Contrast, the output of the pipe temperature set point third comparator is higher than the T _S (U ₃₎ V ₃ is a "low" output V ₄ of the fourth comparator (U ₄₎ is inverted becomes "high". The output of the third comparator U ₃ is connected to the end gate U ₆ , and the output of the fourth comparator U ₄ is connected to the end gate U ₇ .

The output of the end gate (U ₆ ) is cold when the valve (3) is of normal closed (NC) type. The output is "high", and if the indoor temperature is lower than the set temperature the output of the comparator (U ₂₎ of When placing the heating change-over switch to K ₁ where the temperature of the pipe is lower than the set temperature is the cooling mode, the comparator (U ₃₎ is "Low" and the output of the AND gate (U ₆ ) is "low" to connect the jumper JP ₂ to the gate of the triac (Q ₁ ), the triac (Q ₁ ) is "turned off" triac Q ₂ is also "off" and the power is cut off to the valve motor 14 to close the valve 3 to block the flow of the cooling material.

On the other hand, the output of the end gate (U ₆ ) is that the gate of the triac (Q ₆ ) is "low" through the LED (D ₆ ) when the auto switch is in the automatic position, so the triac (Q ₃ ) is also "turned off". The fan 9 is stopped to stop the air blowing.

If the room temperature is higher than the set temperature, the output of the comparator (U ₂ ) becomes "high". If the pipe temperature is lower than the set temperature, the output of the comparator (U ₃ ) is "high" and the output of the end gate (U ₆ ) is "High", the triac Q ₁ is "turned on" through the jumper JP ₂ and the firing element die solution D ₄ is fired to "turn on" the triac Q ₂ so that the valve motor ( 14) operates to open the valve (3) to flow the cooling material to lower the room temperature.

On the other hand, the output "high" signal of the AND gate (U ₆ ) is applied to the gate of the triac (Q ₆ ) via the LED (D ₆ ) so that the triac (Q ₆ ) is "turned on" and the diac (D ₅ ) "Turn on" and the fan drive motor 10 is operated to blow air into the fan 9 to perform cooling control.

Ten thousand and one night does not operate the cooling system, the output of the fault during the cooling material is so hot, the pipe temperature is higher than the set temperature comparator (U ₃₎ is the "Low" is the AND gate (U ₆₎ output is also "low" triac (Q ₂ ) (Q ₃ ) is “turned off” to stop valve motor 14 and fan drive motor 10 to prevent hot coolant from flowing and prevent hot air from circulating to improve energy management efficiency. It was made.

In heating mode, if the cooling / heating switch (Sw ₁ ) is set to the K ₂ position, when the room temperature is lower than the set temperature, the output of the comparator (U ₁ ) becomes "high" and is input to the end gate (U ₇ ) and the set temperature is set. than the output of the pipe temperature is high, the comparator (U ₃₎ is a "low" the output of the comparator (U ₄₎ of a "high" is input to the aND gate (U ₇₎ the output of the aND gate (U ₇₎ is " High "and the triac (Q ₁ , Q ₂ ) is turned" on "through the jumper (JP ₂ ) and the valve drive motor (14) is operated so that the heating material flows to the cooling / heating coil (4) to raise the room temperature and the fan. When the control is switched to the automatic position, the triac (Q ₃ , Q ₆ ) is "turned on" through the LED (D ₆ ) to operate the fan drive motor (10) to blow the air in the fan (9) To increase.

In this way, when the room temperature rises and the room temperature rises above the set value, the output of the comparator U ₁ becomes "low" and the output of the end gate U ₇ becomes "low", so that the triac (Q ₂ , Q ₁ ) "Turn off" to stop the power supply of the valve motor 14 to close the valve 3 to block the flow of the heating material.

On the other hand, the triacs (Q ₆ , Q ₃ ) were also "turned off" to cut off the fan motor power supply to stop the air blowing to prevent the room temperature from rising. In addition, if the room temperature is lower than the set temperature and the boiler temperature is lowered at midnight, and the pipe temperature is lower than the set temperature, the output of the comparator (U ₁ ) becomes "high" and the output of the comparator (U ₃ ) becomes "high". The output of comparator (U ₄ ) is "low" and the output of endgate (U ₇ ) is "low" and the valves are turned "turned off" by all triacs (Q ₁ , Q ₂ , Q ₃ , Q ₆ ). It cuts off the power supply to the motor and fan motor to block the flow of heating material lower than the set temperature and prevents the cool air from being circulated so that efficient management of energy is possible. When using a normally open valve, connect a jumper (JP ₁ ), disconnect JP ₂ , and select the cooling / heating switch to the cooling position K ₁ .

Next, the cooling operation in the case of using a normally open valve will be described. If the room temperature is lower than the set temperature and the pipe temperature is higher than the set temperature, the output V ₁ of the comparator (U ₁ ) becomes "high" and is inverted in the comparator (U ₂ ) so that the output V ₂ becomes "low" and the AND gate ( input to U ₆₎ and the output of the comparator (U ₃₎ V ₃ is the "low" is input to the aND gate (U ₆₎ the output of the aND gate (U ₆₎ is a "low", the inverter (U ₈₎ The discharge becomes "high" and the triacs (Q ₁ , Q ₂ ) are "turned on" so that power is supplied to the valve motor (14) to close the valve (3) to block the flow of cooling material, thereby producing a high temperature cooling material. Prevent flow. In addition, the output "low" signal of the end gate (U ₆ ) is "turned off" by the auto switch to the LED (D ₆ ) and the triac (Q ₃ , Q ₆ ) to stop the fan motor to circulate hot air. To improve energy efficiency.

At this time, if the room temperature is higher than the set temperature and the pipe temperature is higher than the set temperature, the output of the comparator U ₁ becomes "low" and inverted in the comparator U ₂ so that V ₂ becomes "high" and the AND gate ( U ₆ ) and the output V ₃ of the comparator U ₃ becomes "low" and the end gate U ₆ output becomes "low" and is inverted in the inverter U ₈ to become "high" and the triac ( Q1, Q2) is "turned on" to prevent the cooling material from flowing and block the flow of hot cooling material. In addition, the fan gate control also has a low output of the gate gate (U ₆ ), so the triacs (Q ₃ , Q ₆ ) are turned off to stop the operation of the fan motor to stop the forced air blowing.

If the room temperature is higher than the set temperature and the pipe temperature is lower than the set temperature, the output of the comparator (U ₂ ) becomes "low" and is inverted in the comparator (U ₂ ) so that V2 becomes "high" and the comparator (U ₃ ). Output and end gate (U ₆ ) are also "high" and are inverted in inverter (U ₈ ), whereby triac (Q ₁ , Q ₂ ) is "turned off" to stop the operation of the valve motor and cool it through the valve. Adjust the room temperature to allow ash to flow. In addition, the "high" signal at the output of the AND gate U ₆ "turns on" the triacs Q ₃ and Q ₆ to operate the fan motor so that the cool air is circulated to control the room temperature.

If the room temperature is lower than the set temperature and the pipe temperature is lower than the set temperature, the output of the comparator (U ₁ ) becomes "high", the output of the comparator (U ₂ ) becomes "low", and the output of the comparator (U ₃ ) Goes high and the AND gate U ₆ output goes low.

This signal is " high " in the inverter U ₈ to " turn on " the triacs Q ₁ and Q ₂ to drive the valve motor to close the valve to shut off the coolant. The AND gate U ₆ output "low""turnsoff" the triacs Q ₃ and Q ₆ to stop the fan motor to prevent air circulation to control the temperature.

On the other hand, in the case of heating, switch the cooling / heating switch position to the K ₂ position.

If the set temperature is higher than the room temperature and the pipe temperature is higher than the set temperature, the output of the comparator (U ₁ ) becomes "high" and is input to the end gate (U ₇ ), and the output of the comparator (U ₃ ) is "low". Is inverted in the comparator U ₄ and the “high” output V ₄ is input to the AND gate U ₇ . At this time, the output of the AND gate (U ₇ ) becomes "high" and is inverted at the inverter (U ₈ ) through the K ₂ contact and becomes "low" so that the triac (Q ₁ , Q ₂ ) is "turned off" so that the valve motor Shut off the power supply to open the valve so that the heating material flows to control the temperature.

On the other hand, the output of the AND gate (U ₇ ) "turns on" the triacs (Q ₃ , Q ₆ ) through the switch in the auto position and the LED (D ₆ ) to supply power to the fan motor to circulate air to control the temperature. do.

Ten thousand and one high and the room temperature than the set temperature, the output of when the pipe temperature is higher than the set temperature comparator (U ₁₎ is "low" and the output is "high" because the AND gate (U ₇₎ the output of the comparator (U ₄₎ is " Low "and inverts at inverter U ₈ through K ₂ to become" high "and triacs (Q ₁ , Q ₂ ) are" turned on "to drive the valve motor to close the valve to block the flow of heating material. Control so that it does not continue to rise. And the gate (U ₇ ) output "turns off" the triacs (Q ₃ , Q ₆ ) via the automatic position and LED (D ₇ ) to cut off the power to the fan motor to stop the fan to stop the air circulation Control the temperature not to increase continuously.

If the room temperature is lower than the set temperature and the pipe temperature is lower than the set temperature, the output of the comparator (U ₁ ) is "high" and the output of the comparator (U ₃ ) is "high", so it is inverted in the comparator (U ₄ ) and "low". ", And the AND gate (U ₇ ) output is" low ".

In this case, the inverter U ₈ is inverted through the K ₂ contact and the triacs Q ₁ and Q ₂ are “turned on” to drive the valve motor to close the valve to block the flow of the heating material.

Meanwhile, the output of the AND gate U ₇ "turns off" the triacs Q ₃ and Q ₆ to stop the fan.

If the room temperature is higher than the set temperature and the pipe temperature is lower than the room temperature, the output of the comparator U ₁ is "low", the output of the comparator U ₃ is "high", and the output of the comparator U ₄ is " Low ", the output of the AND gate (U ₇ ) is also" low "and is inverted by the inverter (U ₈ ) to become" high "so that the triacs (Q ₁ , Q ₂ ) are" turned on "to drive the valve motors. To close the heating material while the triacs (Q ₃ , Q ₆ ) are "turned off" to stop the fan to control the temperature.

In the above, it has been described that the temperature can be automatically controlled by using two valves of a normal open type or a normal closed type.

Next, the operation of the fan in the manual mode is explained through the configuration of the third control unit 13. When the switches SW ₂ and SW ₃ are configured from the automatic position to the manual position and the Vcc power is supplied to the decimal counter U ₅ . When the push switch (SW ₄ ) is pressed once, the output is input to the counter (U ₅ ) so that the E ₁ outputs remain “high” and E ₂ , E ₃ and E ₄ remain “low”.

At this time, since the output (E ₁ ) is "high", the LED (D ₆ ) is turned on through the manual position of the switch (SW ₃ ), and the triac (Q ₃ , Q ₆ ) is "turned on" so that the fan motor is turned strongly to obtain strong winds. Generate. When the switch SW ₄ is pressed again, the counter output E ₂ goes high and E ₁ , E ₃ and E ₄ remain low.

At this time, the output E ₂ is phase-controlled (e.g., 270 °) so as to "turn on" the triacs Q ₃ and Q ₅ via the LED D ₇ to determine the value of the resistor R ₂₀ . Fan speed is controlled to medium speed by controlling fan motor as much as controlled. When the switch (SW ₄ ) is pressed once again, the output (E ₃ ) of the counter (U ₅ ) remains "high" E ₁ , E ₂ , E ₄ keeping "low" and the E ₃ output via the LED (D ₇ ) Triacs Q ₃ and Q ₄ are "turned on".

At this time, the fan is controlled at a low speed by phase controlling the value of the resistor R ₂₁ .

In this way, the speed of the fan can be changed manually.

Pressing the switch (SW ₄ ) once again causes the output of the counter (U ₅ ) to remain “high” with E ₄ “high” and E ₁ , E ₂ , E ₃ . The output (E ₄ ) is connected to the reset terminal, clearing all counters, and returning to the initial state. The fan motor stops because the output (E ₁ , E ₂ , E ₃ ) is "low".

By configuring as described above, each time the switch (SW ₄ ) is pressed, the output terminal is sequentially switched to control the fan speed strong, medium, weak.

As described above, the present invention enables the construction of a fan speed control switch, which is composed of a conventional valve, in a temperature controller, thereby reducing construction costs due to wiring, and using a pipe temperature sensor to compare a pipe temperature with a set temperature. Equipped with automatic cold There is an advantage in that it is possible to efficiently heat the energy saving effect can be brought.

Claims (3)

Supply pipe (P) for supplying cold and hot water, valve 3 for blocking the flow of cold and hot water through the supply pipe (P) and valve drive motor for controlling the opening and closing of the valve (14) ) And the cold An apparatus for controlling local cooling and heating, comprising a fan 9 for blowing air of the heating coil 4 and a fan drive motor 10 for driving the fan, wherein the indoor temperature for detecting the indoor temperature is provided. A first control unit for controlling the cold water or hot water to circulate along the supply pipe P by opening the valve 3 by operating the valve driving motor M according to a temperature set by the detection sensor S ₁ ; By detecting the temperature of the pipe (P) with a pipe temperature sensor (S ₂ ) and automatically controls the fan drive motor 10 when the pipe temperature is lower or higher than the set temperature at the time of cooling and heating according to the set temperature If the cooling / heating material is higher than the room temperature and low during heating, the fan operates to prevent the room temperature from rising and cooling down to maximize energy efficiency. And a second control unit 12 for automatically controlling the air circulation fan according to the temperature of the heating material, and a third control unit 13 for manually controlling the fan speed regardless of the automatic. Electronic temperature controller for local cooling / heating control with automatic fan speed control. According to claim 1, wherein the sensor (S ₁ ) of the first control unit 11 is connected to the first comparator (U ₁ ) and the second comparator (U ₂ ), the output terminal of the first comparator (U ₁ ) is an end connected to the gate (U _7), and an output terminal of the second comparator (U ₂₎ is connected to the end gate (U ₆₎ these outputs driving the triacs (Q ₁₎ (Q ₂₎ drive the valve motor 13 The pipe temperature sensor S ₂ of the second controller 12 is connected to the third comparator U ₃ and the fourth comparator U ₄ , and the output terminal of the third comparator U ₃ is controlled. connected to the end gate (U ₆₎ and an output terminal of the fourth comparator (U ₄₎ is connected to the end gate (U ₇₎ the output signal of the end gate (U ₆₎ is a TRIAC (Q through the LED (D _{6) 3} ) An electronic temperature controller for local cooling and heating control, which can control the fan drive motor 10 manually and automatically, by driving (Q ₆ ) the fan drive motor 10. According to claim 1 or claim 2, wherein the third control unit 13 when switching the switch (SW ₂ , SW ₃ ) from the automatic position to the manual position in accordance with the pressing operation of the push switch (SW ₄ ) the fan blowing amount of the fan as being determined is connected to the push switch, the push switch as being the determined wind blowing amount of a fan in accordance with the pressing operation of the (SW ₄₎ (SW ₄₎ is sequentially decimal counter output terminal changes to the (U ₅₎ decimal counter The three outputs (E ₁ , E ₂ , E ₃ ) of (U ₅ ) are three LEDs (Q ₆ , Q ₇ , Q ₈ ) and triac (Q ₆ , Q) that determine the strength, medium or weak, respectively. ₅ , Q ₄ ) and the three triacs (Q ₆ , Q ₅ , Q ₄ ) are connected in series to the triac (Q ₃ ), so that the push switch SW ₄ is applied to increase or decrease. , three _{LED (Q 6, Q 7,} Q 8) that determines the drug via any one of the triacs (Q ₃₎ and a fan drive that drives the motor, which adjusts the air volume of the fan Passive and capable of district cooling automatic speed control of the fan heater of ranging and an electronic control thermostat.