JP4434998B2 - Indoor temperature control system - Google Patents

Description

  The present invention relates to a system that automatically controls indoor temperature of a house or the like, particularly indoor temperature in summer, to an appropriate temperature.

  Conventionally, air conditioners, ceiling fans, and the like have been used to keep the indoor temperature in summer comfortable. However, all of these devices adjusted the temperature and rotation speed appropriately by operating the switches attached to each device depending on human senses, but adjust them while considering the relationship between the devices. This is difficult, and it is very troublesome to finely adjust the temperature according to the indoor / outdoor temperature, etc., which changes with the passage of time, and there is a waste of electricity consumption.

  SUMMARY OF THE INVENTION An object of the present invention is to provide a control system that can automatically operate an air conditioner or the like in accordance with indoor and outdoor temperatures to keep the room at a comfortable temperature.

  In order to solve the above problems, in the indoor temperature control system of the present invention, at least a top light, a ceiling fan, and an air conditioner are installed in a house, an indoor upper temperature detecting means, an indoor lower temperature detecting means, and an outdoor temperature. A configuration in which detection means is provided and a controller for controlling opening / closing of the top light, forward / reverse rotation of the ceiling fan and operation stop of the air conditioner based on signals from these detection means is employed.

  Means for comparing the indoor upper temperature and the indoor lower temperature by signals from the upper temperature detecting means and the lower temperature detecting means, and this indoor temperature and outdoor temperature detecting means with any one of the upper temperature and lower temperature or an average value as the indoor temperature. The controller is provided with means for comparing the outdoor temperature from the vehicle, and means for comparing the indoor temperature with a constant set temperature. Based on the comparison results, the top light is opened and closed, the ceiling fan is rotated forward and backward, and the air conditioner is operated. Means for controlling the stop can be provided in the controller.

  As mentioned above, the air conditioner can be automatically operated and the room can be kept at an appropriate temperature by a simple means that only detects the temperature of the upper and lower parts of the room and the outside of the room. It can be used for energy saving.

Embodiments of the present invention will be described below with reference to the accompanying drawings. FIG.1 and FIG.2 is the schematic of the apparatus installed in a house. As shown in FIG. 1, a top light T ₁ is installed on the ceiling 2 of the house 1 and can be opened and closed in accordance with a signal given to the controller C ₁ . Note the top light T ₁ at the time comes with rain sensor rainfall issues a signal to the controller C _1, which is to close the skylight T _1. Moreover, the top light with a blind mentioned later can be used.

A ceiling fan T ₂ is installed in the vicinity of the top light T ₁ and inside the ceiling 2. The ceiling fan T ₂ rotates forward and backward at an appropriate rotational speed according to a signal given to the controller C ₂ , and is converted into the air in the room 3. An upward flow or a downward flow is caused. An air conditioner T ₃ is installed at an appropriate location in the room 3, and the controller C ₃ performs cooling and stopping operations.

On the other hand, a temperature sensor D ₁ is installed at an appropriate location in the upper portion of the room 3, and a temperature sensor D ₂ is also installed at an appropriate location in the lower location of the room 3. Further outdoor appropriate location, for example, a temperature sensor D ₃ in floor are installed. These temperature sensors D ₁ , D ₂ , D ₃ may generate a signal of the measured temperature, or turn on the signal when the set temperature is exceeded or becomes lower than the set temperature. It may be emitted (may be an OFF signal).

As shown in FIG. 2, an intake fan T ₄ and an exhaust fan T ₅ may be provided so that indoor ventilation can be performed efficiently. Further, an electric awning T ₆ can be provided on the terrace or the like to control the shading of sunlight. These devices are provided with controllers C ₄ , C ₅ and C ₆ , respectively.

As shown in FIG. 3, the temperature sensors D ₁ , D ₂ , and D ₃ send signals to the controller C installed in the room by wire or wirelessly, and the controller C performs calculations based on these signals, and the controller Control signals are output to C ₁ , C ₂ , and C ₃ to operate the toplight T ₁ , ceiling fan T ₂ , and air conditioner T _3, and control is performed to keep the room at an appropriate temperature. When the number of control devices increases as shown in FIG. 2, the detection means D _n such as a temperature sensor that sends a signal to the controller C increases, and the control means C _n that controls the devices also increases. Of course detector D _n are hygrometer not limited to temperature sensors, the use of such optical sensors is possible.

Specific means for controlling the room temperature as described above will be described with reference to FIGS. As shown in FIG. 4, first, in steps S ₁₀ , S ₁₁ , and S ₁₂ , the temperature difference X between the upper part and the lower part of the room, the temperature difference Y between the outdoor part and the room, and the difference Z between the room temperature and the set temperature are determined. This difference Z determines whether the indoor environment is cool or hot. These determinations are made based on input signals from the temperature sensors D ₁ , D ₂ , D ₃ . Hereinafter, when simply referred to as room temperature, the average value of the temperature sensors D ₁ and D ₂ may be taken, or the temperature of only the temperature sensor D ₂ may be taken. In addition, a thermometer can be installed separately.

Next, it is determined whether or not the temperature difference X between the indoor upper part and the lower part is equal to or greater than K ₁ (constant) (step S ₁₃ ). For example, if K ₁ = 3 ° C., if the temperature difference is less than 3 ° C., it is determined in step S ₁₄ whether the indoor / outdoor temperature difference Y is lower or higher than K ₂ (constant). If K ₂ = 0, it is determined only whether the room temperature is lower or higher than the outside air. When the room temperature is higher than outside air, (which now and K ₃ = 0) determines the room temperature is higher or lower than the set temperature at step S _15. Here, the set temperature is a limit temperature as to whether or not the indoor environment can be felt cool.

If the room is cool, proceed to step S ₁₆ , step S ₁₇ , and step S ₁₈ , stop the ceiling fan T ₂ , open the top light T ₁ , introduce outside air into the room, and stop the air conditioner T _3. Keep it. These operations are performed by command signals from the controller C to the controllers C ₂ , C ₁ , and C ₃ . If the room is hot, the ceiling fan T ₂ is rotated to generate an upward flow in step S ₁₉ , the top light T ₁ is opened, and the room air is exchanged with outside air. Air conditioner T ₃ remains stopped.

When the indoor temperature at the step S ₁₄ is determined to not higher than the outside air temperature, it determines whether the indoor environment cool in step S _20. If Suzushikere indoor environment, ceiling fans T ₂ is stopped in step S _21, closing the top light T ₁ at step S _22. If the indoor environment is not cool, the process proceeds in the order of steps S ₂₃ , S ₂₄ , and S ₂₅ , the ceiling fan T ₂ is rotated to cause an upward flow, the top light T ₁ is opened, and the ceiling fan T ₂ is ventilated. And carry out the cooling operating the air conditioner T _3.

If there is no difference between the top and bottom for example 3 ° C. above room at the step S _13, the process proceeds to step S ₃₀ in FIG. 5, see the temperature difference between the outdoor and indoor. If towards the indoor temperature is lower, the process proceeds to step S _31, determines whether the room temperature is a set temperature or less. If the temperature is equal to or lower than the set temperature, the process proceeds in order to steps S ₃₂ , S ₃₃ , and S ₃₄ , the ceiling fan T ₂ is stopped, the top light T ₁ is closed, and the air conditioner T ₃ is stopped. When the room temperature is equal to or higher than the set temperature, the process proceeds to steps S ₃₅ , S ₃₆ , and S ₃₄ in order, the ceiling fan T ₂ is rotated to cause an upward flow, the top light T ₁ is opened, and the ceiling fan T ₂ opens the room air. Ventilate. Air conditioner T ₃ may remain stopped.

When the temperature of the room is higher than the outdoor in the step S ₃₀ determines whether the indoor temperature is a set temperature or less in step S _37. If the set temperature or less, in order the process proceeds to step _{S 38, S 39, S 34} , stops the ceiling fan T _2, closing the top light T _1, to stop the air conditioner T _3. That is, the room is maintained as it is.

When the room temperature is determined to exceed the set temperature in the step S _37, sequentially proceeds to steps _{S 40, S 41, S 42} , to cause a downward flow by rotating the ceiling fan T _2, top light T ₁ closes, it performs cooling by operating the air conditioner T _3. By these operations, the room is shut off from the outside air, and the cooling air by cooling returns to the space along with the downward flow and can maintain a uniform room temperature.

In the processing steps S _{10 to} S ₄₂ as described above, the values of K ₁ , K ₂ , and K ₃ can be variously selected. Further, depending on those values, it is possible to select the stepwise opening / closing degree of the toplight T ₁ and the rotational speed of the ceiling fan T ₂ , and the operation of the air conditioner T ₃ to be strong, medium, or weak. . Further, when the toplight T ₁ with a blind is used, the sunlight can be detected by the optical sensor, and the blind can be opened and closed.

Schematic diagram showing the equipment used in the indoor temperature control system Schematic diagram showing other examples of equipment Block diagram showing control method of indoor temperature control system Flow chart showing processing steps of indoor temperature control system Flow chart showing processing steps of indoor temperature control system

Explanation of symbols

1 house 2 roof 3 indoor D ₁ , D ₂ , D ₃ temperature sensor T ₁ top light T ₂ ceiling fan T ₃ air conditioner C ₁ , C ₂ , C ₃ controller C controller S _{10 to} S ₄₂ processing steps

Claims (1)

A top light T ₁ , a ceiling fan T ₂ , and an air conditioner T ₃ are installed in the house 1. A temperature sensor D ₁ provided at the upper part of the room, a temperature sensor D ₂ provided at the lower part of the room, and a temperature sensor D ₃ provided outside the room. The controller C performs an operation according to the signal of the above, and controls the indoor temperature by combining the opening / closing of the top light T ₁ , the forward / reverse rotation and stop of the ceiling fan T ₂ , and the operation and stop of the air conditioner T _3. An indoor temperature control system that uses steps.
(1) A step of determining an indoor upper and lower temperature difference X, an outdoor and indoor temperature difference Y, and an indoor temperature and set temperature difference Z based on input signals from the temperature sensors D ₁ , D ₂ , and D ₃ .
(2) A step of determining whether or not the temperature difference X between the indoor upper part and the lower part is equal to or greater than K ₁ (constant).
(3) A step of determining whether or not the indoor / outdoor temperature difference Y is less than K ₂ (constant) if the temperature difference X is greater than or equal to K ₁ in step (2).
(4) A step of determining whether or not the temperature difference Z between the room temperature and the set temperature is less than K ₃ (constant) when it is determined in step (3) that the indoor / outdoor temperature difference Y is less than K ₂ .
(5) When it is determined in step (4) that the temperature difference Z between the room temperature and the set temperature is less than K ₃ (constant), the ceiling fan T ₂ is stopped, the top light T ₁ is opened, and the outside air is exhausted. It was introduced into the chamber, stopping the air conditioner T _3.
(6) When it is determined in step (4) that the temperature difference Z between the room temperature and the set temperature is equal to or greater than K ₃ (constant), the ceiling fan T ₂ is rotated to generate an upward flow, and the top light Opening T ₁ , replacing room air with outside air, and stopping air conditioner T ₃ .
(7) When it is determined in step (3) that the indoor / outdoor temperature difference Y is equal to or greater than K ₂ , it is determined whether the temperature difference Z between the room temperature and the set temperature is less than K ₃ (constant). Step.
(8) A step of stopping the ceiling fan T ₂ and closing the top light T ₁ when it is determined in step (7) that the temperature difference Z between the room temperature and the set temperature is less than K ₃ (constant).
(9) When it is determined in step (7) that the temperature difference Z between the room temperature and the set temperature is equal to or greater than K ₃ (constant), the ceiling fan T ₂ is rotated to cause an upward flow, and the top light T Opening ₁ and ventilating with ceiling fan T ₂ and operating air conditioner T ₃ for cooling.
(10) A step of determining whether the indoor / outdoor temperature difference Y is equal to or greater than K ₂ (constant) if the temperature difference X is less than K ₁ in step (2).
(11) When it is determined in step (10) that the indoor / outdoor temperature difference Y is equal to or greater than K ₂ (constant), it is determined whether the temperature difference Z between the room temperature and the set temperature is less than K ₃ (constant). Step to do.
(12) If it is determined in step (11) that the temperature difference Z between the room temperature and the set temperature is less than K ₃ (constant), the ceiling fan T ₂ is stopped, the top light T ₁ is closed, and the air conditioning is performed. step to stop the machine T _3.
(13) When it is determined in step (11) that the temperature difference Z between the room temperature and the set temperature is equal to or greater than K ₃ (constant), the ceiling fan T ₂ is rotated to cause an upward flow and the top light T ₁ And ventilating the indoor air with the ceiling fan T ₂ and leaving the air conditioner T ₃ stopped.
(14) Whether or not the temperature difference Z between the indoor temperature and the set temperature is less than K ₃ (constant) when it is determined in step (10) that the indoor / outdoor temperature difference Y is less than K ₂ (constant). Determining.
(15) If it is determined in step (14) that the temperature difference Z between the room temperature and the set temperature is less than K ₃ (constant), the ceiling fan T ₂ is stopped, the top light T ₁ is closed, and the air conditioner step to stop the T _3.
(16) When it is determined in step (14) that the temperature difference Z between the room temperature and the set temperature is equal to or greater than K ₃ (constant), the ceiling fan T ₂ is rotated to cause a downward flow, and the top light T close _1, step of cooling by operating the air conditioner T _3.

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