JP2884874B2 - Air conditioner - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an air conditioner equipped with a variable displacement compressor, in which the air temperature of the outdoor heat exchanger at the start of the defrosting operation and the defrosting prohibited time are determined by the operating frequency. It relates to a harmony device.

[0002]

2. Description of the Related Art FIGS.
BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a refrigerant circuit diagram showing a configuration of a conventional air conditioner disclosed in Japanese Patent No. 6843, an electric circuit diagram showing an internal configuration of a controller of the air conditioner and peripheral circuits thereof, and a flowchart showing an operation of the controller. . 6, 101 is a compressor, 102 is a four-way valve, 103 is an indoor heat exchanger, 104 is a heating capillary, 105 is an outdoor heat exchanger, 106 is an accumulator, 107 is a capillary for cooling and defrosting, 1
08 and 109 are check valves, 110 is a temperature sensor, 111 is a temperature sensor 110 connected, a timer function (not shown) for integrating the elapsed time during heating and defrosting, and a defrost inhibition time t _DS and defrosting time. This is a controller that sets a start temperature T _S and an end temperature T _E and generates a signal for switching between defrost and heating operations.

FIG. 7 shows the configuration of the controller 111. FIG. 7 is an electric circuit diagram of a main part mainly including the controller 111. In the figure, reference numeral 111 denotes a controller by a microcomputer, which receives signals from a temperature sensor 110 and a room temperature sensor 112 by an input circuit 113, and
The data is output to the PU 114 (central processing unit).

[0004] The controller 111 is provided with a timer 115, and data is exchanged between the timer 115 and the CPU 114. The output of the CPU 114 is supplied to a relay coil 117 and a semiconductor relay 118 through an output circuit 116. The relay coil 117 has a contact 121, and the contact 121 and the solenoid valve 120 are connected in series between both poles of the power supply 123. The solenoid valve 120 is connected to the relay coil 11
The contact 121 opens and closes in accordance with the energization and de-energization of 7, thereby being excited or de-energized.

The semiconductor relay 118 and the indoor fan 1
19 is connected in series between the power supplies 123. The semiconductor relay 118 receives the signal from the output circuit 116, changes the duty ratio of the indoor fan 119, and changes the rotation speed.

[0006] A primary coil of a transformer 122 is connected between both poles of the power supply 123.
The second primary coil applies a voltage to each member of the controller 111. FIG. 8 shows a control flowchart of the controller 111, where T _S is a defrost start temperature,
T _E defrosting end temperature, t _DS defrosting inhibition time, t _Dmax defrosting maximum time, T _S1 defrosting start at room temperature, T _S2 at room temperature after t _a minute from the start of defrosting, [Delta] T _R1 ( = T _S2 -T _S1) at room temperature change after t _a minute, T
_1, T ₂ is the pipe temperature detected by the temperature sensor 110, t ₁ the heating elapsed time, time to t _a is room detected from the start of defrosting, Delta] t _D defrosting time,
ΔT _R indicates an initially set allowable change in room temperature.

When the power is turned on, the controller 111
_Are the initial set values T _S , T _E , t _Dmax ,
Set t _a , ΔT _R, etc. And step 202
Sets the first defrost inhibition time t _DS1 . From the next time, the defrost inhibition time t _DS changes. Then the temperature sensor 110 provided in the piping of the outdoor heat exchanger 105, to detect the pipe temperature T ₁ (step 203). If the heating operation is performed in step 204, step 205
In step 2, the elapsed time t ₁ of the heating is integrated, and the integrated time t ₁ and the set first defrost inhibition time t _DS1 are set in step 2.
Compare with 06. Further, the pipe temperature T ₁ and the defrost start temperature T _S are compared in step 207. When t ₁ ≧ t _DS1 and T ₁ ≦ T _S, as well as generating a defrost switching signal Output proceeds to step 208, it clears the t _1. Under this condition, the heating operation is continued. On the other hand, if the defrost operation is being performed in step 204, the process proceeds to step 209, where the room temperature T _S1 at the start of defrost is detected, the defrost time Δt _D is integrated in step 210, and the defrost is started in step 211. , The room temperature T _S2 after t _a is detected, and the pipe temperature T ₂
Is detected. Compares the piping temperature T ₂ and the defrost completion temperature T _E at Step 213, if T ₂ ≧ T _E, the process proceeds to step 215, the process proceeds to step 214 If not T ₂ ≧ T _E, and the defrosting time Delta] t _D The maximum defrost time t _Dmax is compared. At step 214, Δt _D > t
If it is not _Dmax , the process returns to step 210 and Δt _D ≧ t
If it is _Dmax , the process proceeds to step 215. In step 215, the above-described change in room temperature ΔT _R1 (= T _S2 −T _S1 ) is calculated, and the process proceeds to step 216. In step 216, the next defrost inhibition time t is calculated from the calculated room temperature change ΔT _R1.
Calculate _DS . For example, the room temperature change ΔT _R1 is compared with the initially set allowable room temperature change ΔT _R, and when ΔT _R1 > ΔT _R , the next defrost inhibition time t _{DS is set} to t _DS = t _DS1 −
is set to be shorter than the first defrost inhibition time t _DS1 . α is a correction time arbitrarily determined. When ΔT _R1 = ΔT _R , t _DS = t _{DS1 When} ΔT _R1 <ΔT _R , t _DS = t _DS1 + α is set. Next, in step 217, when the heating switching signal is output, the defrost time is cleared.
As described above, the room temperature during the defrosting start, calculates a degree of room temperature reduction by the room temperature t _a minute after the start of the defrosting, to determine the next defrost prohibition time t _DS by the room temperature reduced degree.

Further, a technique for performing efficient defrosting by combining the heat exchanger temperature and the accumulated operation time is disclosed in Japanese Patent Application Laid-Open No. 59-1.
No. 50271 and JP-A-60-133248.

[0009]

As described above, the conventional air conditioner operates at a constant temperature regardless of the operating frequency of the variable capacity compressor because the piping temperature of the outdoor heat exchanger at the start of defrosting is kept constant. Despite the fact that frost formation is progressing when operating at a low frequency, the piping temperature of the outdoor heat exchanger does not reach the defrost start temperature and the heating operation is continued without shifting to the defrost operation, The amount of frost increases. Defrosting progresses and eventually reaches the defrosting start temperature, and the defrosting operation is performed. However, the defrosting time becomes extremely long, and the indoor temperature drops rapidly, impairing comfort. In the case of a heat storage type air conditioner, all the heat of the heat storage material is consumed before defrosting is completely completed, and residual frost is left.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and has a low defrosting time, no residual frost, a high efficiency of operation and a comfortable indoor environment at any operation frequency. It is an object of the present invention to obtain an air conditioner capable of improving the air conditioner.

[0011]

SUMMARY OF THE INVENTION An air conditioner according to the present invention has a variable-capacity compressor that changes an operation frequency outside a commercial frequency range in accordance with an air-conditioning load to change a capacity, a four-way valve, and indoor heat. Exchanger, a flow control device, a refrigeration cycle to which the outdoor heat exchanger is sequentially connected, a temperature sensor provided in a pipe of the outdoor heat exchanger, and the temperature sensor is connected,
A built-in timer and outputs a switching signal for heating and defrosting operation, and starts defrosting at an operation frequency including outside the commercial frequency range of the variable capacity compressor when a preset defrost inhibition time has elapsed. And a controller for determining the pipe temperature of the outdoor heat exchanger.

Further, in an air conditioner in which a variable capacity compressor, a four-way valve, an indoor heat exchanger, a flow control device, and an outdoor heat exchanger are sequentially connected to form a circulation cycle, piping of the outdoor heat exchanger is provided. And a temperature sensor connected to the temperature sensor and having a built-in timer, outputs a switching signal for heating and defrosting operation, and performs the next preset heating operation based on the previous defrosting operation time and then performs frosting. And a controller for performing a take-off operation.

[0013]

The air conditioner according to the present invention can be carried out at an optimum timing even when the pipe temperature does not drop so much, for example, even when frost is formed when the operating frequency is low.

In addition, when the defrosting time is extremely long, the defrosting operation is forcibly performed early so that defrosting is surely performed, the residual frost is efficiently performed, and the indoor comfort is further improved.

[0015]

[Embodiment 1] An embodiment of the present invention will be described below with reference to the drawings. FIG.
FIG. 2 is a refrigerant circuit diagram showing the configuration of one embodiment. In FIG. 1, 1 is a compressor, 2 is a four-way valve, 3 is an indoor heat exchanger,
4 is an expansion valve which is a flow control device, 5 is an outdoor heat exchanger, 6
The solenoid valve defrost, the piping temperature sensor 7, 8 are connected to a pipe temperature sensor 7, a timer function for accumulating elapsed time during heating and defrost (not shown), defrost prohibition time t _ds, Defrost start temperature T _S , end temperature T _e , defrost (electromagnetic valve for defrost open)
This is a controller that generates a signal for switching the heating operation and generates an operation frequency signal for the compressor.

FIG. 2 shows the configuration of the controller 8. FIG.
FIG. 3 is an electric circuit diagram of a main part mainly including the controller 8. In the figure, reference numeral 8 denotes a controller by a microcomputer, which receives a signal from a pipe temperature sensor 7 by an input circuit 9 and outputs the signal to a CPU 10. The controller 8 controls the timer 1
1 is provided to exchange data between the timer 11 and the CPU 10. The output of the CPU 10 passes through an output circuit 12 to the compressor 1 and the semiconductor relay 1.
3. The semiconductor relay 13 and the defrost solenoid valve 6 are connected in series between the power supplies 15. The semiconductor relay 13 receives the signal of the output circuit 12 and opens and closes the defrost electromagnetic valve 6. Further, a primary coil of the transformer 14 is connected between both poles of the power supply 15,
The secondary coil of the transformer 14 supplies a voltage to each member of the controller 8.

FIG. 3 is a control flowchart of the controller 8, wherein Ts is a defrosting start temperature, Te is a defrosting end temperature, tds is a defrosting inhibition time, and T1 and T2 are temperature sensors 7
The pipe temperature detected by the equation (1) and t1 indicate the elapsed heating time.

Next, the operation will be described. Now power 1
5 is ON the controller 8 sets the T _e in step 21. Then, in step 22, a defrosting inhibition time t _ds is set. From the next time, t _ds fluctuates. Then detecting the pipe temperature T ₁ of the temperature sensor 7 provided in the piping of the outdoor heat exchanger 5 (step 23). If the heating operation is further performed (step 24), the elapsed time t _{1 of the} heating is set at step 25.
And the accumulated time t ₁ is compared with the initially set defrost inhibition time t _ds in step 26. In step 7, when t ₁ ≧ t _ds , the current operating frequency of the compressor 1 is calculated. The defrosting start temperature T _S is set by the following. For example, FIG.
As shown in (2), when the operation frequency is 50 Hz, the defrosting start temperature T _S becomes −1 ° C. Then, in step 28, it is compared with the pipe temperature T ₂ and the defroster start temperature T _S T ₁ ≦ T _S
When, at the next clock frost Toki signal output, clear the t ₁ (step 29). When the condition is not satisfied, the heating operation is continued. On the other hand, if you are defrosting operation, performs multiplication of defrost time t _d at step 30, to detect the pipe temperature T ₂ in step 31, the pipe temperature T ₂ at step 32
Is compared with the defrosting end temperature. If T ₂ ≧ T _e , the integration of the defrosting time is ended in step 33. The integration time Δt
_d is compared with a preset defrost time t _d1 (step 34), and if Δt _d ≦ t _d1 , the next defrost inhibition time t _ds =
t _ds + α (step 35), eg, α = 10 minutes, and Δ
If t _d > t _d1 , it is compared with another preset defrost time t _d2 (step 36). If Δt _d ≧ t _d2 , the next defrost inhibition time t _ds = t _ds −α (step 37), Δt _d
If <T _d2 , the next defrost prohibition time t _ds = t _ds (no change) is set (step 38). Then step 39
In, a heating switching signal is output to clear the defrost time. As described above, the value of the pipe temperature at the start of defrosting is determined by the operating frequency of the compressor 1 when switching to the defrosting operation. The flow of the refrigerant during the defrosting operation will be described with reference to FIG. During the heating operation, the compressor 1 returns to the compressor 1 via the four-way valve 2, the indoor heat exchanger 3, the expansion valve 4, the outdoor heat exchanger 5, and the four-way valve 2. The flow is discharged from the compressor 1, a part of the flow is passed to the outdoor heat exchanger 5, and frost formed on the outdoor heat exchanger is dissolved.

Embodiment 2 FIG. In the first embodiment, the pipe temperature at the start of defrosting is determined based on the operating frequency of the compressor 1, but as shown in FIG. 5, steps 40 to 44 are inserted between step 33 and step 34 in FIG. I do. At step 40, the defrost operation time t _d3 (for example, 10 minutes) is compared with a preset defrost operation time t
_{If d} ≧ t _d3 , the next defrost prohibition time is set to t
After performing the heating operation for _ds0 (for example, 30 minutes, usually 60 to 120 minutes) (Steps 41 to 43), the defrosting operation is forcibly started (Step 44) regardless of the pipe temperature.

[0020]

As described above, according to the present invention, a variable capacity compressor, a four-way valve, an indoor heat exchanger, which varies the capacity by changing the operating frequency outside the commercial frequency range according to the air conditioning load, A refrigeration cycle in which a flow control device and an outdoor heat exchanger are sequentially connected, a temperature sensor provided in a pipe of the outdoor heat exchanger, and the temperature sensor are connected, a timer is built in, and switching between heating and defrosting operation is performed. A signal is output, and control is performed to determine the piping temperature of the outdoor heat exchanger at the start of defrosting according to the operating frequency including the range outside the commercial frequency of the variable capacity compressor when a preset defrosting prohibition time has elapsed. Because of the provision of the heat exchanger, the effect that defrosting can be performed at an optimum timing even when the pipe temperature does not decrease significantly despite the fact that frost is formed when the operating frequency is low is obtained.

Also, in an air conditioner in which a variable capacity compressor, a four-way valve, an indoor heat exchanger, a flow control device, and an outdoor heat exchanger are sequentially connected to form a circulation cycle, piping for the outdoor heat exchanger is provided. And a temperature sensor connected to the temperature sensor and having a built-in timer, outputs a switching signal for heating and defrosting operation, and performs the next preset heating operation based on the previous defrosting operation time and then performs frosting. With a controller that performs defrosting operation, when the defrosting time is extremely long, the defrosting operation is forcibly performed early so that defrosting can be performed reliably, without residual frost, efficiently, and indoor comfort The effect that the property can be improved is acquired.

[Brief description of the drawings]

FIG. 1 is a refrigerant circuit diagram of an air conditioner according to an embodiment of the present invention.

FIG. 2 is an electric circuit diagram showing an internal configuration of a controller in an air conditioner according to an embodiment of the present invention and circuits around the controller.

FIG. 3 is a flowchart showing an operation of a controller of the air conditioner according to one embodiment of the present invention.

FIG. 4 is a diagram showing a relationship between an operating frequency and a defrosting start temperature of the air conditioner according to one embodiment of the present invention.

FIG. 5 is a flowchart showing an operation of a controller of an air conditioner according to another embodiment of the present invention.

FIG. 6 is a refrigerant circuit diagram of a conventional air conditioner.

FIG. 7 is an electric circuit diagram showing an internal configuration of a controller in a conventional air conditioner and circuits around the controller.

FIG. 8 is a flowchart showing an operation of a controller of the conventional air conditioner.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Compressor 2 Four-way valve 3 Indoor heat exchanger 4 Expansion valve 5 Outdoor heat exchanger 6 Defrosting solenoid valve 7 Temperature sensor 8 Controller

──────────────────────────────────────────────────続 き Continued on the front page (72) Inventor Toshihiro Tanaka 3-181-1, Oka, Shizuoka-shi Mitsubishi Electric Corporation Shizuoka Works (72) Inventor Yasuo Imajo 3-181, Oka, Shizuoka-shi Mitsubishi Electric Inside Shizuoka Works (72) Inventor Hideaki Nagatomo 3-18-1, Oka, Shizuoka-shi Mitsubishi Electric Corporation Inside Shizuoka Works (72) Inventor Isao Funayama 3-1-1, Oka, Shizuoka-shi Mitsubishi Electric Corporation (72) Inventor Hidenori Ishioka 3-1-1, Oka, Shizuoka-shi Mitsubishi Electric Corporation Shizuoka Works (56) References JP-A-62-261845 (JP, A) JP-A-62-116843 (JP, A) JP-A-62-46150 (JP, A) (58) Fields investigated (Int. Cl. ⁶ , DB name) F25B 47/02 570 F24F 11/02 101

Claims (2)

(57) [Claims] 1. A variable capacity compressor, a four-way valve, an indoor heat exchanger, a flow control device, and an outdoor heat exchanger that vary the operating frequency by changing the operating frequency outside the commercial frequency range according to the air conditioning load. A connected refrigeration cycle, a temperature sensor provided in the pipe of the outdoor heat exchanger, and a temperature sensor connected to the refrigeration cycle. The timer has a built-in timer, and outputs a switching signal for heating and defrosting operation. A controller that determines the piping temperature of the outdoor heat exchanger at the start of defrosting by the operating frequency including outside the commercial frequency range of the variable capacity compressor when the removal prohibition time has elapsed. Air conditioner. 2. Variable capacity compressor, four-way valve, indoor heat exchange
, A flow control device, and an outdoor heat exchanger
The outdoor heat
The temperature sensor provided in the exchanger piping and this temperature sensor
A heater is connected, a timer is built-in, and heating and defrosting are performed.
Output the switching signal of the rotation, and according to the previous defrosting operation time
A system that performs defrosting operation after performing the preset heating operation next time
The air conditioner according to claim 1, further comprising a controller.
Sum equipment.