JPS60122849A - Air conditioner - Google Patents

Abstract

PURPOSE:To perform the optimum air conditioning even when the temperature change is slow like in an intermediate stage when an operation signal from a temperature sensing element by causing to perform a forced heating operation for a certain duration in a certain interval so as to forcibly circulating the air in the room. CONSTITUTION:When the operation is started under a condition where the room temperature Ta is Ta<T100, a room fan 16, a compressor 20, a outside fan 18 and an electric heater 21 are energized, and the compressor 20 is operated at 100% of its capacity. When the room temperature Ta becomes higher than a temperature T80 since, the compressor 20 operates at 80% of its capacity. When the room temperature Ta is further lowered to temperature T0, the compressor 20 and outside fan 18 are turned OFF, and only the room fan 16 is operated. Then, a 9min timer is started. If the air conditioning load is small at this time and the temperature reduction is so slow that the room temperature Ta is still above the set temperature Ts after the 9min timer has timed up, a 3min timer starts counting after the 9min, and the compressor 20, outside fan 18 and room fan 16 are energized to start the operation.

Description

Detailed Description of the Invention (a) Industrial Application Field The present invention relates to a heat pump cycle constructed by sequentially connecting a compressor, a condenser, a pressure reducing device, and an evaporator in an annular manner with refrigerant piping. This relates to operational control during prevention.

(b) Prior Art In general, this type of air conditioner is equipped with a temperature sensing element in the conditioned room to detect the room temperature and control the operation of the compressor. For example, when the room temperature is lower than the set value, the compressor, outdoor fan, and indoor fan are operated to perform heating operation, and when the room temperature is higher than the set value, the compressor, outdoor fan, and only the indoor fan are operated. The air in the conditioning room was circulated. Although such operation control is generally well-known control, in this case, the indoor fan continues to blow air even when the compressor is stopped, so that the user feels a feeling of cold air. Therefore, as shown in Japanese Utility Model Publication No. 53-1632, when the temperature sensing element is activated and the compressor is stopped, the indoor fan is changed from high speed (strong wind) operation to low speed (weak wind or breeze) operation to prevent this feeling of cold air. something was invented. However, when the indoor fan of such an air conditioner is installed above the room to be conditioned, such as a ceiling-mounted, wall-mounted, or ceiling-mounted type, warm air accumulates above, making it difficult for the temperature sensing element to return to normal. The user feels uncomfortable because the conditioned room is divided into layers of warm air and cold air.

(c) Purpose of the Invention In view of such problems and busy schedules, the present invention provides a heating system that forcibly circulates indoor air by performing forced heating operation for a certain period of time at predetermined intervals when no operation signal is output from the temperature sensing element. It provides a harmonizer.

B) Structure of the Invention The present invention provides an air conditioner in which a compressor, a condenser, a pressure reducing device, and an evaporator are sequentially connected in a ring through refrigerant piping to form a heat pump cycle. A thermo circuit unit that outputs an operating signal, a timer circuit unit that outputs an operating signal for a certain period of time after a predetermined time after the compressor stops, and a gate that operates the compressor using the operating signal from the thermo circuit unit or the timer circuit unit. It is equipped with a circuit section and a control section that operates the indoor 7 unmotor in a light or weak wind operation when the compressor is stopped, thereby preventing separation of warm air and cold air in the room to be conditioned.

(E) Embodiments Below, embodiments of the present invention will be explained based on FIGS. 1 to 3. In FIG. 1, (1) is a step-down transformer that lowers the voltage supplied from an AC power supply (2) 3) is a constant voltage circuit, which consists of a rectifying element (4) that rectifies the output of the step-down transformer (1), a smoothing capacitor (5), a resistor (6), and a Zener diode (8). ) Lotus~
This circuit is composed of a temperature sensing element (9) and a resistor aQ which are connected in series to a constant voltage circuit (3). aυ is an analog/digital (A/D) converter, which converts the analog voltage generated between the temperature sensing element (9) and the resistor α0 into a digital value, and then outputs the digital value to the microprocessor a. This microprocessor a is energized by the relays (IR) to (7R) based on the output of the A/D converter α specific power and key switch α31 to start operation, change the room temperature set value, timer operation, etc. is under control. However, (14), ai is a relay (IR) to (7R
) driver circuit.

Switching contacts (IRυ to (3R1) and normally open contacts (4R, ) to (7RI) of these relays (IR) to (7R)
The following mechanical elements are controlled by: That is, αe is an indoor fan motor that has terminals with wind speeds of 1 strong wind, 1 medium wind (wealth), weak wind (L), and light wind (L, L).
Switching contacts (IR,) to (3R,) and setting switches (
17) changes the wind speed. α It is a dark house outdoor fan motor and is controlled by a normally open contact (5RI). 0 is a solenoid valve, which is controlled by a normally open contact piece (6R,), and this solenoid valve handle sets the operating capacity of the compressor to 80%. Further, the compressor is controlled by a normally open contact piece (4R,). (2υ is an electric heater, controlled by a normally open contact (7RI).

The microprocessor u snore timer circuit section, gate circuit section, and control section are configured with software and internal processing is stored therein. Further, this microprocessor aa operates based on the flowchart shown in FIG.

In other words, if the indoor temperature is Tα and the set temperature is '%, then 6 room temperature (Tα) (set temperature CT & ) at the start of operation.
”, then further judge whether the difference is 2 degrees or more and set the operating capacity of the compressor (to) to 100%, or energize the solenoid valve 4 to increase the operating capacity of the compressor (2 (to) to 80%). %.At this time, at the same time as the outdoor fan (8) is operated, the indoor fan (161) is operated at the set air speed. Furthermore, it is determined whether 6 room temperature (Tα) - set temperature (TI) ≧1", and if 6 room temperature (T) - set temperature (TI) ≧1", then only the indoor fan (161) is operated with 6 "breeze". Room temperature (T
α) - If the set temperature (T#) ≧ 1, only the indoor fan 4 is operated with a "light breeze" and at the same time the 9-minute timer starts measuring. Before the 9-minute timer times out, the room temperature (T
When α) becomes lower than the set temperature (TJP), normal operation, that is, operation with the operating capacity of the compressor (2ω) set to 100% or 80%, is performed.In addition, when the 9-minute timer times out, the next The 3-minute timer starts counting. During these 3 minutes, the operating capacity of the compressor section is set to 80%.
In addition, the outdoor fan 00 and the indoor fan 00 are operated at the set wind speed. In this case as well, when the room temperature (Tα) reaches 6 room temperature (Tα) (set temperature (T#)), the same normal operation as above is performed. Furthermore, when the 3-minute timer times out, the 9-minute timer starts counting again. Then, the above-mentioned 9-minute and 3-minute operations are repeated.

In addition, the above timer times of 9 minutes and 3 minutes are 1 of the compressor QO).
It is determined by the capacity at 00% operation, the thickness of the air conditioning load, and the size of each heat exchanger.

The operation of the air conditioner configured in this way will be explained based on FIG. 1. Room temperature (Tα) is Tα<Too. When the operation starts at the time of ', the relays (IR), (4R), (
5R) and (7R) are turned ON, and at the same time, relay (6R) is turned OFF. Therefore, indoor fan a0, compressor fan, outdoor fan 081. Electric heater C! When the power is turned on, the compressor end operates at 100% capacity. Thereafter, as shown in FIG. 3, when the room temperature (Tα) becomes higher than the temperature (Tao), the compressor (4) operates at 80% capacity. After this,
Furthermore, the room temperature (Tα) becomes low F and the temperature (To ) (T/
-Tα≧1), relays (4R), (5R), (6
R) is turned off, the compressor (201) and the outdoor fan are de-energized, and only the indoor fan (161) is set to operate.

Next, the 9 minute timer starts running. At this time, if the air conditioning load is small and the room temperature (Tα) decreases slowly, the room temperature (Tα) will remain at the set temperature (T-?) even if the 9-minute timer times out.
) That's it. Therefore, after these 9 minutes, the 3 minute timer starts counting and at the same time relays (IR), (4R), (
5R, ) and (6R) are turned ON, and the compressor end, the outdoor fan, and the indoor fan (161) are energized and start operating.

In this way, the compressor (20+) is operated at 80% operating capacity to heat the conditioning room and circulate the air in the conditioning room at predetermined intervals.

(f) Effects of the Invention As described above, the present invention provides an air conditioner in which a compressor, a pressure reducing device, and an evaporator are sequentially connected in a ring through refrigerant piping to form a heat pump cycle. A thermo circuit section that outputs operating signals for the compressor, a timer circuit section that outputs operating signals for a certain period of time after a predetermined period of time after the compressor stops, and an operating signal from the thermo circuit section or timer circuit section that operates the compressor. Equipped with a gate circuit that controls the temperature and a control unit that sets the indoor fan motor to 6-breeze or 6-weak air when the compressor stops operating, the optimal air conditioning phase can be achieved even when the temperature changes slowly, such as during the middle of the season. Furthermore, it is possible to prevent separation of warm air and cold air in an air conditioner room, and to appropriately control the operation of the air conditioner without causing malfunctions.

[Brief explanation of drawings]

Fig. 1 is an electric circuit diagram of an air conditioner showing an embodiment of the present invention, Fig. 2 is a flowchart showing the operation of the microprocessor shown in Fig. 1, and Fig. 3 is an electric circuit diagram of an air conditioner shown in Fig. 1. It is a temperature change diagram showing the change in room temperature when used. (8)...Thermo circuit section, αri...microprocessor, (16)...indoor fan, (201...
compressor.

Claims (1)

[Claims] (1) In a heat pump cycle configured by sequentially connecting a compressor, condenser, pressure reducing device, and evaporator in a ring with refrigerant piping, a thermo circuit outputs a compressor operation signal based on the temperature of the conditioned room. a timer circuit section that outputs an operating signal for a certain period of time after a predetermined period of time after the compressor stops; a gate circuit section that operates the compressor with an operating signal from the thermo circuit section or the timer circuit section; An air conditioner characterized by comprising: a control unit that operates an indoor fan motor in a breeze or weak breeze mode when the operation is stopped.