JPH10197110A - Frosted state discriminating device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To enable a frosted state of an evaporator to be uniformly discriminated by a method wherein if a difference between an outlet temperature and an inlet temperature detected is not higher than a predetermined temperature including and in the vicinity of 0 deg.C, its state is discriminated as a frosted state and this is outputted. SOLUTION: An inlet temperature t1 of refrigerant flowing into an evaporator 11 constituting a refrigerating circuit 10 is detected by an inlet temperature sensor 1 and then an outlet temperature t2 of the refrigerant flowing out of the evaporator 11 is detected by an outlet temperature sensor 2. The temperatures t1 , t2 detected by each of these sensors 1 and 2 are inputted to an output section 3 assembled in a control section comprised of a microcomputer or the like. When a difference between the temperatures t2 and t1 is not higher than a predetermined valve, 0 deg.C, for example, i.e., under the condition of t2 <=t1 . A judgement of frosted state is made and outputted. With such an arrangement as above, it is possible to discriminate a frosted state of the evaporator 11 in a uniform manner and further to improve an accuracy in discrimination.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a frost determination device for determining a frost condition of an evaporator constituting a refrigeration circuit, and is used for, for example, an environmental test device and a refrigerator.

[0002]

2. Description of the Related Art In an environmental test apparatus or a refrigerator using a refrigeration circuit, a device for judging frost on an evaporator is provided, and when it is judged that frost is present, a defrost operation is performed or a frost indication or an alarm is issued. Or As such a frost determination device, conventionally, a device that determines the operating time using a timer, a device that detects a change due to frost of air resistance passing through the evaporator using a pressure gauge or a blower meter, A device for directly measuring the thickness of frost, a device for measuring and judging the pressure and temperature (pipe temperature) of the refrigerant flowing from the evaporator to the compressor, and the like are generally employed.

However, in such an apparatus, when using a timer, the degree of frosting varies depending on the operating state of the refrigeration apparatus, the degree of moisture load, and the like, so that accurate frosting determination cannot be performed. In the measurement of the air resistance of the evaporator, pressure fluctuation occurs due to the effect of dynamic pressure, etc., so that it is necessary to increase the differential pressure to prevent erroneous detection, and there is an air flow that bypasses the evaporator. For this reason, the determination cannot be made until the amount of frost increases, and similarly, there is a problem that the frost determination cannot be accurately performed.

[0004] In measuring the thickness of frost, the air flow passing through the evaporator varies, so that the amount of frost differs between a place with a large amount of air and a place with a small amount of air. Otherwise, the measurement position cannot be determined, and there is a problem that a uniform apparatus configuration and accurate judgment cannot be made.

[0005] In an apparatus for measuring the temperature of a pipe or the like, the temperature of the pipe rapidly drops when frost is formed. For example, there is a method of detecting a rate of change in the temperature of the pipe. However, in this method, when the temperature difference between the air temperature and the evaporating temperature is reduced in the process of lowering the set temperature and lowering the temperature, the pipe temperature also decreases, so that this phenomenon cannot be clearly distinguished from frost. , There is a risk of misjudgment. There is also a method of setting a reference value of the pipe temperature corresponding to the air temperature to be controlled, and judging frost by a difference from this temperature.However, since the pipe temperature varies depending on the magnitude of the cooling load, Unless such conditions are taken into consideration for each device, an appropriate reference temperature cannot be set, and there is a problem in that uniform accurate determination cannot be made.

[0006]

SUMMARY OF THE INVENTION The present invention solves the above-mentioned problems in the prior art, and can uniformly judge the state of frost formation on an evaporator and improve the accuracy of the judgment. The task is to provide

[0007]

According to the present invention, there is provided a frost determining apparatus for determining a frost state of an evaporator constituting a refrigeration circuit, wherein the temperature of a refrigerant entering the evaporator is detected. An inlet temperature detecting means, an outlet temperature detecting means for detecting a temperature of the refrigerant flowing out of the evaporator, and a difference between the outlet temperature detected by the outlet temperature detecting means and the inlet temperature detected by the inlet temperature detecting means is 0 ° C. And an output unit for judging a frosted state when the temperature falls below a predetermined temperature in the vicinity thereof and outputting this.

[0008]

FIG. 1 shows an example of a refrigeration circuit to which the present invention can be applied and an apparatus for judging frost. The frost determination device is a device that determines the frost state of the evaporator 11 that constitutes the refrigeration circuit 10, and the inlet temperature t of the refrigerant that enters the evaporator 11.
₁ the inlet temperature sensor 1 as the inlet temperature detecting means for detecting the temperature t of the outlet temperature sensor 2, the sensor 1 detects each as an outlet temperature detection means for detecting an outlet temperature t ₂ of the refrigerant leaving the evaporator 11 _An output unit which inputs ₁ and t ₂ and outputs a judgment when the difference between t ₂ and t ₁ is a predetermined value, for example, 0 ° C. or less, that is, when t ₂ ≦ t ₁ , that is, a frosted state is determined. 3 and the like.

[0009] The refrigeration circuit of the present embodiment is provided outside the evaporator 11.
A compressor 12, a condenser 13, an expansion valve 14, an electromagnetic valve 15 for hot gas for defrosting the evaporator 11, a defrost control unit 16, and the like are provided. In addition, a pressure adjusting valve and a solenoid valve for non-frost operation, an intermediate injection system for preventing compressor heating, and the like are appropriately provided as necessary according to the use of the refrigeration circuit.

The inlet / outlet temperature sensors 1 and 2 are
1 may be provided in itself, or may be provided in the middle of a pipe connected thereto. The output unit 3, which forms a part of the frost determination device, may be configured as a circuit as an independent instrument, but is usually controlled by a refrigeration circuit or a microcomputer including the microcomputer, for example, of an environmental test device. Built into the department.

The refrigeration circuit having the above-mentioned frost determination device is used, for example, as a part of an air conditioner of an environmental test device, in which an evaporator 11 includes a heater (not shown), a humidifier, a circulating blower and the like. A cooler is provided in the air-conditioned room of the environmental test device. The operation of these devices is controlled in the environmental test apparatus according to the set temperature and humidity in the test chamber.

The refrigerant is decompressed by the expansion valve 14 and introduced into the evaporator 11 as a saturated liquid at that pressure, where it exchanges heat with external circulating air and evaporates. Then, at the outlet of the evaporator 11, in order to prevent the liquid from returning to the compressor 12, the vapor is usually vaporized to a superheat degree of about 5 to 15 ° C. When the set temperature of the circulating air is lowered from such an operating state, in the case of the above-described environmental test apparatus, the output of the heater for temperature control is lowered, the temperature of the circulating air is lowered, and the temperature difference between the refrigerant and the refrigerant is reduced. And the superheat degree of the refrigerant vapor decreases, so that the expansion valve 14 further depressurizes the refrigerant to lower the saturation temperature, thereby maintaining the superheat degree and maintaining the circulating air at the target set temperature. I have.

When the operation is performed at an evaporation temperature of 0 ° C. or less,
When frost is formed on the evaporator 11 and the frost becomes thicker than a certain thickness and a so-called frost state occurs, the solid frost acts as a heat insulating material to prevent heat exchange between the refrigerant and the circulating air. Does not completely evaporate, and a liquid return phenomenon occurs.
At this time, the refrigerant at the evaporator outlet is at a temperature close to the saturation temperature corresponding to the pressure at that point without being overheated. Such a state is maintained as long as the frost is not eliminated. As a result, the pressure drop of the refrigerant in the evaporator 11, the refrigerant outlet temperature t ₂ will tend to decrease slightly than the inlet temperature t _1.

In this embodiment, when t ₂ ≦ t ₁ as described above, the sensors 1 and 2 detect these temperatures, and the output unit 3 outputs this as frost. This output is used for defrost operation control, frost alarm, frost indication, and the like. Note that the output unit 3 of the present embodiment directly outputs this when t ₂ ≦ t ₁ , but outputs t ₂ > t ₁ , and when this output is not output, it is t ₂ as a ≦ t _1, indirectly it may be as to output a t ₂ ≦ t _1. Also, t ₂ > t ₁ may be used as a normal operation display without frost.

Further, for example, t ₂ ≦≦ _{2 in} consideration of the characteristics of the refrigeration circuit such as how much the degree of superheat is designed, the use and characteristics of the apparatus in which the refrigeration circuit is used, or the detection accuracy. instead of the conditions of _{t 1, t 2 -t 1 ≦} t
It is also possible to set t to a temperature close to 0 ° C., for example, to a temperature within a range of about ± 2 ° C. In this case, by setting the above-mentioned t stepwise, it is possible to output including the degree of frost. Also, as described above, t ₂ and t ₁
Instead of dealing directly with the difference, for example, 1.1> (t
The absolute value of ₁ / t ₂ )> 0.9, so that t ₁ and t ₂
It may be configured to indirectly corresponds to the difference between t ₂ and t ₁ the ratio of the.

As described above, for example, when the set temperature of the circulating air is lowered, the evaporator outlet temperature of the refrigerant drops sharply to reduce the degree of superheat, but this phenomenon is transiently resolved by operating the expansion valve. It is something. Therefore,
Since it is possible to clearly distinguish this phenomenon from a persistent decrease in the degree of superheat or a reversal of the temperature at the entrance and exit due to frosting, frosting can be reliably detected according to the judgment method of the present invention.

As described above, in the frost determination apparatus of the present invention,
The temperature of the refrigerant at the inlet and outlet of the evaporator, which changes in relation to each other, is detected. It is possible to determine the frosting with high accuracy without being affected by the frost. Further, this device can be applied uniformly to a normal refrigeration circuit. Further, since only the output unit 3 is added to the temperature sensors 1 and 2 which are usually provided, the temperature sensor is simple and low-cost.

Next, a case where the frost determination apparatus of the present invention is used for defrost control of a refrigeration circuit will be described. The defrost control unit 16 includes an operation state determination unit 16a that temporarily cancels the output of the output unit 4 according to the operation state, a frosted output continuity determination unit 16b that determines the continuity of the output of the output unit 3, and an output unit. 3 is provided with an electromagnetic valve control section 16c that controls the opening and closing of the electromagnetic valve 15 for the defrost period in response to the output of the control unit 3. The operating state determination unit 16a receives the signal of the refrigeration circuit and the signal of the execution of the defrost together with the signal of the output unit 3, and cancels the output of the output unit 3 by a timer or the like until a certain time elapses after receiving these signals. Has a function of validating the signal of the output unit 3 after the lapse of the time.

That is, immediately after the start-up, there is a possibility that an unstable phenomenon such that t ₂ becomes slightly lower than t ₁ by, for example, about 0.1 ° C. may occur due to a detection error or the like. Cancel output for several minutes after startup to avoid. Further, immediately after or during the defrosting operation, since t ₂ in order to defrosting by the hot gas is naturally lower than t _1, the defrosting operation ends after a few minutes to cancel the output.

Further, when the defrost operation is performed, the steady operation state is interrupted and the continuity of the control is lost.
In determining whether to perform the frosting, accuracy of the determination is required rather than urgency. Therefore, in order to avoid instantaneous misjudgment due to any cause or confusion with a decrease in the degree of superheat due to a temperature drop, the frosted output is set to 1 for example.
If you do not continue for a minute, cancel this. In addition,
This cancellation may be performed when the frost output detected in each fixed control cycle is not continuous for a certain number of times or more.

FIG. 2 shows an example of defrost control using the above-described frost determination device and defrost controller.
When the defrost control routine is started, first, it is determined in an operating state determining portion 16a whether the operating state is suitable for defrosting (S-1). In this determination, as described above, it is determined whether, for example, 5 minutes have elapsed since the start of the refrigeration circuit, and whether or not, for example, 5 minutes have elapsed since the end of the defrost operation.

If these times have elapsed, the output unit 3
In comparing the detected value of the sensors 1 and 2 to determine whether t ₂ ≦ t ₁ (S-2), when t ₂ ≦ t ₁ is the frost with the output continuity determination part 16b, the counter of which is not shown The count is incremented by 1 to determine whether the count has become, for example, 10 (S-3, 4). When the frost output is detected ten times in succession and it is determined that the frost is certain, the solenoid valve control section 16c Controls the solenoid valve 15 to open (S-5), and starts the defrost operation. Although not shown, after sufficient time has passed for defrosting, or when the evaporator outlet temperature is increased to a predetermined temperature or the like, if it is determined that the defrosting has been sufficiently performed, the solenoid valve 15 is closed, Return to normal operation.

According to the above-described defrost control, a highly accurate and highly reliable frost determination device is used.
By excluding the refrigeration circuit that does not originally need defrosting and a certain period immediately after defrosting, and by adding output continuity judgment to avoid judgment that is sensitive to necessary abnormalities,
The defrost operation can be reliably performed when defrosting is required. And, in the environmental test equipment, etc., to prevent the execution of defrost and the interruption of continuous operation due to erroneous judgment,
Test efficiency can be improved.

As the defrost means, instead of the hot gas solenoid valve 15 shown in FIG. 1, an electrothermal type, a water spray type or a hot air blowing type, a refrigerant circulation direction switching type, etc. It is needless to say that a known appropriate system can be adopted.

[0025]

As described above, according to the present invention, the evaporator inlet / outlet temperature detecting means is provided to detect the refrigerant temperature at the evaporator inlet / outlet, and when the difference between these temperatures falls below a predetermined temperature near 0 ° C. Since the state is determined and outputted, it is possible to determine the frost with extremely high accuracy without being affected by disturbance by utilizing a unique phenomenon that occurs only at the time of frost.

In addition, since the temperature to be determined is not a fixed temperature such as a compressor suction pipe temperature and a constant reference temperature, but is a temperature that changes relative to each other, that is, a refrigerant temperature at an evaporator inlet / outlet. INDUSTRIAL APPLICABILITY The frost determination apparatus of the present invention can be universally and uniformly applied to various refrigeration circuits and various apparatuses equipped with the refrigeration circuits.

Furthermore, since a temperature sensor which is usually provided can be used as the temperature detecting means, only an output section is added, and the structure of the frost judging device can be simplified and the cost can be reduced.

[Brief description of the drawings]

FIG. 1 is an explanatory diagram showing an example of a frost determination device of the present invention and a refrigeration circuit provided with the device.

FIG. 2 is a flowchart illustrating an example of a defrost control method using the frost determination device and a refrigeration circuit.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Inlet temperature sensor (inlet temperature detecting means) 2 Outlet temperature sensor (outlet temperature detecting means) 3 Output part 10 Refrigeration circuit 11 Evaporator

 ──────────────────────────────────────────────────続 き Continued on the front page (72) Katsuhiko Watanabe, Inventor 3-5-6 Tenjinbashi, Kita-ku, Osaka City, Osaka, Japan

Claims (1)

[Claims] 1. A frost determination device for determining a frost state of an evaporator constituting a refrigeration circuit, wherein an inlet temperature detection means for detecting a temperature of a refrigerant entering the evaporator, and a temperature of a refrigerant exiting the evaporator. Temperature difference between the outlet temperature detected by the outlet temperature detecting means and the inlet temperature detected by the inlet temperature detecting means.
And an output unit for judging a frosted state when the temperature falls below a predetermined temperature in the vicinity thereof and outputting the frosted state, and outputting the same.