JP2000249390A - Air fin cooler and its operation control method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To lighten the burden to an operator by omitting the louver operation by hand, and besides to control the temperature of a refrigerant accurately. SOLUTION: An air fin cooler 10 is composed of a heat exchanger 20, a louver 40 free of aperture adjustment, a fan 30A which can adjust air quantity, a temperature sensor 50 which detects the temperature of a refrigerant on the side of the outflow part 22 of the heat exchanger 20, and a temperature regulator 60 which automatically controls the aperture of a louver 40 and the quantity of air, based on the detected temperature T detected with this temperature sensor 50. Accordingly, since not only the fan 30A but also the louver 40 are controlled automatically, the burden of the operator can be lightened by omitting the louver operation by hand, and besides the temperature of the refrigerant can be controlled accurately.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to an air fin cooler and an operation control method thereof.

[0002]

2. Description of the Related Art Conventionally, in an air fin cooler provided with an air fin type heat exchanger, the opening of a louver arranged on one side of the heat exchanger and the air flow of a suction fan arranged on the other side of the heat exchanger. , The temperature of the cooling medium at the outlet side of the heat exchanger was controlled within a predetermined range.

[0003]

However, in the related art, the air volume of the fan is automatically adjusted. However, since the louver opening is manually adjusted, the louver opening adjustment may be delayed. In addition, it is difficult to accurately control the temperature of the cooling medium to the target temperature, which imposes a burden on the operator.

[0004] In particular, when the louver is kept large during heavy rain or the like, the cooling medium is supercooled and heat loss increases. Blockage occurs, leading to fluctuations in cooler operation.

An object of the present invention is to provide an air fin cooler which can reduce the burden on the operator by omitting manual louver operation and can accurately control the temperature of the cooling medium, and an operation control method thereof.

When the cooling medium tends to be supercooled, it is possible to suppress the amount of air to be taken in only by reducing the opening of the louver and thereby to raise the temperature to some extent. In spite of the fact that the heat exchanger is not desired to be cooled so much, the air flow of the fan is still largely adjusted, so that the power consumption of the fan is largely maintained and the power is wasted.

On the other hand, when the cooling medium is at a high temperature, the temperature can be lowered to some extent only by increasing the air volume of the fan. However, if only the performance of the fan is used, the cooling efficiency is poor, and Power increases.

Another object of the present invention is to provide an operation control method of an air fin cooler which can reduce the power consumption of a fan.

[0009]

An air fin cooler according to the present invention comprises an air fin type heat exchanger for exchanging heat by flowing in and out a cooling medium, and an opening arranged on one side of the heat exchanger. An adjustable louver, an air volume adjustable fan disposed on the other side of the heat exchanger, temperature detecting means for detecting the temperature of the cooling medium at least at the outlet side of the heat exchanger, Control means for automatically controlling the opening of the louver and the air flow of the fan based on the temperature detected by the means.

According to the present invention, not only the fan but also the louver is automatically controlled by the control means.
The burden on the operator can be reduced by eliminating the manual louver operation, and the temperature of the cooling medium can be accurately controlled.

At this time, the louver and the fan are provided so as to be capable of adjusting the opening degree and the air volume by inputting an air signal output from the control means, and the air signal for adjusting the louver and the air for adjusting the fan are provided. It is desirable that the pressure range of each signal differs from that of the signal. In such a case, one pipe or the like from the control means can be branched in the middle and connected to the fan and the louver, so that it is not necessary to provide two pipes connected to the control means.

On the other hand, the operation control method for an air fin cooler according to the present invention is characterized in that a louver whose opening degree is freely adjustable is arranged on one side of an air fin type heat exchanger for allowing a cooling medium to flow in and out and exchanging heat. A fan whose air volume can be adjusted is arranged on the other side of the heat exchanger, the temperature of the cooling medium is detected at least on the outflow side of the heat exchanger, and the louver is detected based on the temperature detected by the temperature detecting means. The opening degree of the fan and the air volume of the fan are automatically controlled. As described above, the burden on the operator can be reduced by eliminating the manual louver operation, and the temperature of the cooling medium can be accurately controlled. it can.

In the operation control method according to the present invention, when the detected temperature is lower than a preset lower limit temperature,
It is desirable to first reduce the air volume of the fan and then reduce the opening of the louver. That is, in order to raise the temperature of the cooling medium, it is necessary to reduce the air volume by reducing the opening of the louver or to reduce the air volume by adjusting the fan itself. Since the own air volume is reduced, the power consumption of the fan can be reduced from an earlier stage as compared with the case where the louver opening is adjusted first, and the power consumption can be reduced.

On the other hand, when the detected temperature exceeds a predetermined upper limit temperature, it is desirable that the opening of the louver is first increased, and then the air volume of the fan is increased. . That is, to lower the temperature of the cooling medium, increase the air volume of the fan itself,
Alternatively, it is necessary to increase the opening of the louver to make it easier to take in air.However, in the present invention, in order to increase the opening of the louver preferentially, heat exchange can be performed without increasing the power consumption of the fan itself from a fast stage. The cooling device can be sufficiently cooled, and the power consumption of the fan can be reduced.

[0015]

DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of the present invention will be described below with reference to the drawings. FIG. 1 is an overall view showing a schematic configuration of an air fin cooler 10 according to the present embodiment.

The air fin cooler 10 includes a heat exchanger 20 having a cooling medium inlet 21 and a cooling medium outlet 22.
And two fans 30 opposed to each other inside the heat exchanger 20 (inside the air fin cooler 10) and louvers opposed to each other outside the heat exchanger 20 (outside the air fin cooler 10). 40 and the outlet 22 of the heat exchanger 20
A temperature sensor 50 as a detecting means for detecting the temperature of the cooling medium on the side, and a temperature controller 60 as a control means for performing predetermined control according to the detected temperature T of the temperature sensor 50 are provided.

The heat exchanger 20 is an air fin type in which a plate-like, laminated plate-like, or tubular flow path is formed in an arbitrary shape such as a swelling shape or a zigzag shape, and is usually used for an air fin cooler. .

One of the fans 30A 30A
Is a variable pitch fan in which each blade 31 is angle-adjusted by an air signal A having a predetermined pressure of, for example, 0.2 to 0.6 kg / cm ² , and is provided so that the air volume can be adjusted in accordance with the angle. In the present embodiment, the angle level of the blade 31 can be switched between “vertical” at which the air volume is maximized and “horizontal” at which the air volume is minimized (dashed line in the figure). However, the setting of the opening degree is arbitrary and is not limited to two types (see a modified example described later).

The louver 40 is provided with an air motor 41 operated by an air signal B of a predetermined pressure, and the opening degree can be adjusted by the air motor 41. At this time, the operating range of the operating pressure is different between the air signal B and the air signal A of the fan 30A.
It is set to ⁶ to 1.0 kg / cm ² . In the present embodiment, it is possible to switch the louver opening level between two types, “open” where the air volume is maximum, and “closed” where the air volume is minimum. However, the setting of the opening degree is also arbitrary, and is not limited to two types (see a modified example described later).

The temperature sensor 50 utilizes a thermocouple, for example, and is configured to output an electric signal corresponding to the detected temperature T to the temperature controller 60.

The temperature controller 60 has a comparison program stored in an arbitrary storage means such as a RAM, and the RAM has a control limit temperature for managing the detected temperature T within a predetermined range, that is, a control limit temperature. upper limit temperature T _U and the lower limit temperature T _L
Is stored. Then, the temperature controller 60 compares the detected temperature T with the upper limit and lower limit temperatures T _U and T _L, and outputs an air signal A to the fan 30A which is a variable pitch fan based on the comparison result. An air signal B is output to 41.

At this time, a main line 61 is connected to the temperature controller 60, and instrumentation air serving as a basis for the air signals A and B is supplied at a main pressure of, for example, 4.5 kg / cm ² . The temperature controller 60 and the fan 30A are connected by a branch line 62 for the air signal A.
Another branch line 63 branches off from the middle of 2. The branch line 63 is used for the air signal B, and is connected to a drive line 43 connecting the air motor 41 and a regulator 42 for manually driving the air motor 41. That is, in the present embodiment, only the base end side of the branch line 62 of the branch lines 62 and 63 is connected to the temperature controller 60.

Next, based on the flowchart of FIG.
An operation control method of the affine cooler 10 will be described. here
Then, suppose that the air fin cooler 10 initially
A is set to “vertical” and the louver 40 is set to “open”.
As a result, air is supplied to the heat exchanger 20 at the maximum air volume.
In this state, the detected temperature T of the cooling medium becomes a predetermined temperature.
Within range (T _L<T <T_U)
You.

In such a state, the temperature controller 60
Sampling the detected temperature T from the temperature sensor 50 every predetermined time, compared with the upper limit temperature T _U and the lower limit temperature T _L.
Then, as long as the detected temperature T is within the predetermined temperature range, this sampling is repeated as shown in step (hereinafter simply abbreviated as “S”) 1.

Next, in step S1, if the detected temperature T of the cooling medium drops for some reason and falls below the lower limit temperature T _L (T _L > T), first, as shown in S2, the temperature controller 60 turns on the air. The signal A is output.

The air signal A is input to the fan 30A through the branch line 62. In the fan 30A, the blade 31 changes from "vertical" to "horizontal", and the air volume at the fan 30A itself is adjusted to be small.

[0027] Thereafter, after a predetermined time, the temperature regulator 60 samples the detected temperature T of the cooling medium, compared with the upper limit temperature T _U and the lower limit temperature T _L (S3). As a result, when the detected temperature T returns within the predetermined temperature range, it is determined that the detected temperature T can be controlled only by adjusting the fan 30A, and the operation is continued as it is, and the sampling of the detected temperature T is also performed. Continue to continue.

However, if the detected temperature T is still lower than the lower limit temperature _TL in S3, it is determined that the adjustment of the fan 30A alone is not sufficient, and the temperature controller 60 outputs the air signal B (S4). ).

Although the air signal B is output to the branch line 62, the pressure range of the air signal B is different from that of the air signal A.
3 and finally input to the air motor 41. Accordingly, the opening of the louver 40 is adjusted to change from “open” to “closed”, and the amount of air taken in from the louver 40 is limited, so that the air volume is further reduced.

As described above, the air flow to the heat exchanger 20 is minimized, and the heat exchanger 20 is hardly cooled. And
The operation in this state is continued until the detected temperature T exceeds the lower limit temperature _TL (S5), and the process returns to S1 when _TL <T.

Next, during operation in the air volume minimum, if the detected temperature T exceeds the upper limit temperature T _U, the temperature controller 60
Outputs the air signal B, returns the louver 40 from "closed" to "open", and facilitates the intake of air from the louver 40 to increase the cooling efficiency of the heat exchanger 20 (S6).

[0032] Thereafter, after a predetermined time, the temperature regulator 60 samples the detected temperature T of the cooling medium, compared with the upper limit temperature T _U and the lower limit temperature T _L (S7). As a result, when the detected temperature T has returned within the predetermined temperature range, it is determined that the detected temperature T can be controlled only by adjusting the opening of the louver 40, and the operation is continued as it is.
The sampling of the detected temperature T is also continued.

However, if the detected temperature T still exceeds the upper limit temperature T _U in S7, it is determined that the adjustment of the louver 40 alone is not sufficient, and the temperature controller 60 outputs the air signal A (S8). ), Return the blades 31 of the fan 30A from “horizontal” to “vertical”.

As described above, the air flow to the heat exchanger 20 returns to the maximum, and the heat exchanger 20 is more easily cooled. The operation in this state is continued until the detected temperature T falls below the upper limit temperature T _U (S9), and when T _U > T, S1 is reached.
Return to

In S3, it is determined that the detected temperature T can be controlled only by adjusting the fan 30A, and the operation is performed with the blade 31 of the fan 30A at an angle of "horizontal" and the louver 40 at an open degree of "open". In such a case, there is a possibility that the detected temperature T exceeds the upper limit temperature T _U. In such a case, the processing from S3 to S8 is performed, and the temperature controller 60 outputs the air signal A and outputs the air signal A.
The blade 31 of A is returned to “vertical”. Thereby, the heat exchanger 20 is cooled with the maximum air volume, and the detected temperature T is raised to the upper limit temperature T _U.
Is controlled to be less than Hereinafter, the process returns to S1 via S9.

On the other hand, in S7, it is determined that the detected temperature T can be controlled only by adjusting the louver 40, and the fan 30 is controlled.
When the operation is performed with the angle of the blade 31 of “A” being “horizontal” and the opening of the louver 40 being “open”, there is a possibility that the detected temperature T falls below the lower limit temperature _TL .
In such a case, processing from S7 to S4 is performed,
The temperature controller 60 outputs the air signal B to return the louver 40 to “closed”. This allows the heat exchanger 20 to operate with a minimum airflow.
Is controlled so that the detected temperature T exceeds the lower limit temperature _TL . Hereinafter, the process returns to S1 via S5.

According to the present embodiment, the following effects can be obtained. 1) In the air fin cooler 10, since both the fan 30A and the louver 40 are automatically controlled by the temperature controller 60, manual operation of the louver 40 can be omitted, and the burden on the operator can be reduced, and the temperature of the cooling medium can be reduced. Can be controlled accurately. Thus, for example, there is no fear that the cooling medium will be overcooled, so that it is possible to prevent the flow path from being blocked due to a decrease in the fluidity of the cooling medium, and it is possible to reliably prevent the operation fluctuation of the cooler.

2) At this time, the fan 30A and the louver 40 apply the air signals A and B output from the temperature controller 60.
Is input so that the air volume adjustment and the opening degree can be adjusted. The air signal A for adjusting the fan 30A and the air signal B for adjusting the louver 40 have different pressure ranges of the respective signals. The branch line 62 as one signal line may be branched in the middle, the branch line 62 may be connected to the fan 30A, and the branched branch line 63 may be connected to the louver 40. It is possible to save the trouble of providing two branch lines.

3) In the air fin cooler 10, when the detected temperature T of the cooling medium falls below the preset lower limit temperature _TL , the air volume of the fan 30A is first reduced, and then the opening of the louver 40 is reduced. To make it difficult to take in air. That is, in the present embodiment, since the air volume of the fan 30A itself is preferentially reduced, the fan 30A is adjusted earlier than when the opening of the louver 40 is adjusted first.
The power consumption at A can be reduced, and the power consumption can be reduced.

4) In the air fin cooler 10,
When the detected temperature T exceeds the preset upper limit temperature T _U , first, the opening of the louver 40 is increased to facilitate the intake of air, and then the air flow of the fan 30A is increased to increase the cooling efficiency. . That is, in the present embodiment, in order to preferentially increase the opening of the louver 40, the fan 3
The heat exchanger 20 can be sufficiently cooled without increasing the power consumption of the 0A itself from the early stage, and the power consumption of the fan 30A can be reduced.

It should be noted that the present invention is not limited to the above-described embodiment, but includes other configurations that can achieve the object of the present invention, and also includes the following modifications.
In the above-described embodiment, the angle of the blade 31 of the fan 30A can be adjusted in two ways, “horizontal” and “vertical”. However, for example, “45” which is approximately half the angle of “horizontal” and “vertical” ° may be set, and the air volume at this time may be adjusted to approximately half the air volume at “horizontal” and “vertical”. Also, the opening of the louver 40 is set not only in two ways of “closed” and “open”, but also in three ways including “half open” which can be adjusted to an intermediate opening between “closed” and “open”. You may. Then, the above-mentioned “45 °” and “half-open” times are set as the normal mode, and the normal operation is performed in the normal mode. The fan 30A and the louver 40 may be adjusted accordingly.

In the above embodiment, two fans 30 are used, one of which is a variable pitch fan, but both may be constituted by variable pitch fans. Further, the number of fans 30 is not particularly limited, and may be arbitrarily determined according to the performance required of the air fin cooler. Therefore, the number of fans 30 may be four or more, or may be one. Of course, in the case of one device, this one device becomes a variable pitch fan.

Further, the fan according to the present invention only needs to be provided so that the air volume can be adjusted. In addition to a variable pitch fan, a fan capable of adjusting the air volume by changing the rotation speed may be used. Even in such a case, by preferentially adjusting the fan when the detected temperature T is low, or by preferentially adjusting the louver when the detected temperature T is high, the electric load can be reduced, and the power consumption can be reduced.

In the above-described embodiment, the fan 30 and the louver 40 are configured such that the air volume and the opening are adjusted by the air signals A and B having different pressure ranges, respectively. When connectable to the temperature controller 60, the pressure ranges of the air signals A and B may be the same.

The fan 30 and the louver 40 may be adjusted by electric signals in addition to those adjusted by air signals A and B using the pressure of air. A personal computer or the like may be used as a control unit that can output such an electric signal.

In the above embodiment, the detected temperature T is detected only at the outlet 22 of the heat exchanger 20. In addition, the temperature is also detected at the inlet 21 and more precise control is performed using both temperatures. May be performed.

[0047]

As described above, according to the present invention,
Since both the fan and the louver are automatically controlled by the control means, there is an effect that the burden on the operator can be reduced by eliminating the manual louver operation, and the temperature of the cooling medium can be accurately controlled.

[Brief description of the drawings]

FIG. 1 is an overall view showing a schematic configuration of an embodiment of the present invention.

FIG. 2 is a flowchart of the embodiment.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 10 Air fin cooler 20 Heat exchanger 22 Outflow part 30A fan 40 Louver 50 Temperature sensor which is temperature detection means 60 Temperature controller which is control means A Air signal B Air signal T Detection temperature T _L lower limit temperature T _U upper limit temperature

Claims (5)

[Claims] 1. An air fin type heat exchanger for exchanging heat by flowing in and out a cooling medium, an adjustable louver disposed on one side of the heat exchanger, and the other of the heat exchanger A fan whose air flow is adjustable, a temperature detecting means for detecting a temperature of the cooling medium at least at an outflow portion side of the heat exchanger, and the louver based on a temperature detected by the temperature detecting means. Control means for automatically controlling the opening of the fan and the flow rate of the fan. 2. The air fin cooler according to claim 1, wherein the louver and the fan are provided so as to be able to adjust an opening degree and an air flow by inputting an air signal output from the control means, and adjust the louver. An air fin cooler characterized in that a pressure range of each signal is different between an air signal for air conditioning and an air signal for fan adjustment. 3. An air fin-type heat exchanger for allowing a cooling medium to flow in and out for heat exchange, a louver having an adjustable opening degree disposed on one side of the air fin type heat exchanger, and a fan having an adjustable air flow on the other side of the heat exchanger. And the temperature of the cooling medium is detected at least on the outflow side of the heat exchanger, and the opening of the louver and the air volume of the fan are automatically controlled based on the temperature detected by the temperature detecting means. An operation control method for an air fin cooler, comprising: 4. The operation control method for an air fin cooler according to claim 3, wherein when the detected temperature falls below a preset lower limit temperature, the air volume of the fan is reduced first, and then the louver is opened. An operation control method for an air fin cooler, characterized in that the degree is reduced. 5. The operation control method for an air fin cooler according to claim 3, wherein, when the detected temperature exceeds a preset upper limit temperature, first, an opening degree of the louver is increased, Next, an operation control method of the air fin cooler, characterized by increasing the air volume of the fan.