KR101602314B1 - Temperature control apparatus and temperature control method for antenna - Google Patents

Abstract

The present invention provides a temperature control method, capable of increasing the reliability of a valve by minimizing the operation of the valve while satisfying a control temperature range. The present invention includes: an antenna; a temperature controller controlling the temperature of the antenna; and a duct connected between the antenna and the temperature controller. The temperature controller includes: a sensing part measuring a temperature value of air, flowing from the temperature controller into the antenna; a heat exchanging part exchanging heat with the air to cool the flowing air; and a control part variably controlling a flow rate of cooling water of the heat exchanging part based on the measured temperature value, in order to keep the temperature of the flowing air within a preset range. Therefore, the operation of the valve to control the flow rate of the cooling water is minimized to improve the reliability of the flow rate of the cooling water.

Description

TECHNICAL FIELD [0001] The present invention relates to an antenna temperature control apparatus and a control method thereof,

The present invention relates to a method for controlling the temperature of air to prevent overheating and condensation of an antenna device.

RADAR is an abbreviation of radio detection and distance measurement (RAdio Detecting And Ranging). It emits electromagnetic waves of microwave (microwave, 10cm ~ 100cm wavelength) to an object, receives electromagnetic waves reflected from the object, , Direction, altitude and so on.

Recent development of radar is to develop an active phased array radar using a plurality of transit / receive modules (TRM), which are semiconductor type amplifiers, in accordance with the development and development of semiconductor devices.

When the TRM amplifies the magnitude of the electromagnetic wave, most of the power used in the TRM is dissipated into heat. The amount of heat generated by the recent increase in the number and power of the TRM used in the radar is increasing. Therefore, it is necessary to separately provide a temperature control device for cooling the antenna on which the TRM is mounted.

It is necessary to supply cooling air having a certain temperature range to the antenna device because there is a lower limit of the control temperature for preventing condensation inside the antenna and an upper limit value exists for cooling.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a temperature control method that improves the reliability of a valve by minimizing valve operation while satisfying a control temperature range in a system in which upper and lower limits of the control temperature exist.

Further, the present invention is to improve the reliability of fan operation by controlling the operation method of the fan that supplies the cooling air according to whether the antenna power is applied or not.

According to an aspect of the present invention, there is provided a temperature control apparatus including an antenna, including an antenna, a temperature controller for controlling a temperature of the antenna, and a duct communicating with the antenna and the temperature controller, The temperature regulator includes a sensing unit for measuring a temperature value of air flowing into the antenna from the temperature regulator, a heat exchanging unit for exchanging heat with the air to cool the introduced air, And a controller for variably controlling the flow rate of the cooling water in the heat exchanger based on the measured temperature value so as to maintain the flow rate of the cooling water within a predetermined range.

In one embodiment, the apparatus further includes a heater for heating the introduced air, wherein the controller operates the heater when the measured temperature value is equal to or lower than a predetermined temperature value.

In one embodiment, the temperature controller may further include a fan unit for supplying air from the temperature controller to the antenna, and the controller may determine the operation mode of the fan unit based on whether the antenna is powered on .

In one embodiment, the fan unit includes three centrifugal fans, and the control unit operates all of the three centrifugal fans when the power of the antenna is applied, and when the power of the antenna is not applied , And one of the three centrifugal fans is alternately operated.

In one embodiment, the temperature controller further includes a memory unit, and when the one of the three centrifugal fans is operated alternately, information related to the operation cycle and the operation order of each of the three centrifugal fans Is stored in the memory unit.

In one embodiment, the display further includes a display unit, wherein the controller controls the temperature of the air flowing into the temperature regulator from the antenna, the temperature of air supplied to the antenna from the temperature regulator, the temperature of the antenna, And outputting information related to at least one of the flow rates to the display unit.

The controller may further include a setting unit configured to set information related to a corresponding relationship between the temperature of the introduced air and the flow rate of the cooling water, And the flow rate is variably controlled.

In one embodiment, the antenna is an active phased array radar using a semiconductor-type amplifier.

The present invention also discloses a method of controlling an antenna temperature control apparatus. A method of controlling a temperature controller having an antenna includes determining whether an operation state of the antenna satisfies a maximum heating condition, measuring a temperature value of air flowing into the antenna, Varying the flow rate of the cooling water in the heat exchanger based on the measured temperature value so as to maintain the temperature of the heat exchanger within a predetermined range, operating the heater when the measured temperature value is lower than a predetermined temperature value, And determining the operation mode of the fan unit based on whether or not the fan unit is operated.

According to the present invention configured as described above, in controlling the temperature of the antenna, the valve operation for controlling the flow rate of the cooling water can be minimized, and the reliability of the flow rate of the cooling water can be improved.

In addition, the temperature of the antenna can be more accurately controlled in consideration of the temperature change rate of the cooling air supplied to the inside of the antenna.

In addition, by controlling the operation mode of the fan differently depending on whether or not the antenna is powered, the power consumption can be reduced and the fan can be prevented from being overloaded.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram showing a temperature control device provided with an antenna proposed in the present invention; FIG.
2 is a block diagram illustrating the interior of a temperature controller proposed in the present invention;
3 is a flowchart showing a temperature control method used in a domestic air conditioner.
4 is a flowchart showing a temperature control method used in an air conditioner for a vehicle;
5 is a conceptual diagram showing a temperature control method considering the upper and lower limits of the temperature of the air flowing into the antenna.
6 is a conceptual diagram showing a temperature control method in consideration of a temperature change of air flowing into an antenna;
7 is a flowchart showing a temperature control method proposed in the present invention.
8 is a flowchart showing a fan operation method proposed in the present invention.
9 is a graph showing the operation state of the flow rate valve of the temperature controller according to the method proposed by the present invention.
10 is a graph showing the temperature distribution of air supplied to the antenna by the temperature controller according to the method proposed by the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings, so that those skilled in the art can easily carry out the technical idea of the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly explain the present invention, parts not related to the description are omitted, and like parts are denoted by similar reference numerals throughout the specification.

FIG. 1 is a block diagram showing a temperature control apparatus provided with an antenna proposed in the present invention, and FIG. 2 is a conceptual diagram illustrating the inside of the temperature controller shown in FIG. 1 in detail.

As shown in FIG. 1, the temperature control apparatus of the present invention may include an antenna 110, a duct unit 120, and a temperature controller 130. The temperature control device equipped with the antenna can circulate the air 140 for temperature control of the antenna inside the device. Also, although not shown in FIG. 1, the temperature controller having the antenna may include a display unit.

In the following specification, embodiments for circulating air 140 within a temperature controller for temperature control of an antenna are described. However, the subject to be circulated for temperature control is not limited to air, and the temperature regulating device may circulate liquid (cooling water) for temperature control of the antenna.

In more detail, the antenna 110 may be a TRM (Transmit / Receive Module) 111, which is a semiconductor type amplifier. That is, the antenna 110 may be an active phased array radar using at least one TRM 111. On the other hand, the antenna 110 may use a vacuum tube type amplifier.

The duct unit 120 may be communicated between the antenna 110 and the temperature controller 130. Therefore, the duct part 120 may be formed of a heat-resistant material. In addition, the duct unit 120 may include a recovery duct 121 and a supply duct 122. 1, the recovery duct 121 and the supply duct 122 may be a circulation path of the air 140 for temperature control of the antenna.

Referring to FIG. 1, the air 140 cooled or heated in the temperature controller 130 may be supplied to the antenna 110 through the supply duct 122. The air 140 heated or cooled while passing through the TRM 111 of the antenna 110 may be recovered to the temperature regulator 130 through the recovery duct 121 and then cooled or heated again.

As described above, the temperature controller 130 may supply or recover air to control the temperature of the antenna 110. [ In addition, the temperature controller 130 may cool or heat the supplied or recovered air.

2, the internal configuration of the temperature controller 130 will be described in more detail.

2, the temperature controller 130 includes at least one of a heat exchanger 210, a flow rate valve 220, a temperature sensor 230, a controller 240, a heater 250, and a pan 260 . Although not shown in FIG. 2, the temperature controller 130 may include at least one of a memory unit, a setting unit, and a discharge unit.

More specifically, the control unit 240 determines whether the air 140 flowing into the antenna 110 passes through the supply duct 122, the heat exchanger 210, the pan unit 260, and the heater 250 sequentially And can be controlled to be supplied to the antenna 110. The introduced air 140 may be recovered to the temperature controller 130 through the recovery duct 121 after heat exchange inside the antenna 110.

The heat exchanger 210 may cool the air 140. More specifically, the heat exchanger 210 may exchange heat with the air to cool the air 140. In this regard, the control unit 240 may allow the cooling water to pass through the heat exchanger 210 together with the air 140.

The controller 240 may control the amount of cooling water passing through the heat exchanger 210 and the heat exchange between the heat exchanger 210 and the air 140 may be controlled through the adjustment.

In this case, the control unit 240 may adjust the opening degree of the flow rate valve 220 to adjust the amount of the cooling water passing through the heat exchanger 210. For example, the control unit 240 can completely open the flow valve 220 and control the amount of the cooling water passing through the heat exchanger 210 to a maximum value. In another example, the control unit 240 may open the flow valve 220 by 40% to control the amount of the cooling water to be 40% of the maximum value. Also, the control unit 240 can completely shut off the flow valve 220 and control the cooling water to be prevented from passing through the heat exchanger 210.

In this specification, a method of controlling the degree of opening of the flow valve 220 is disclosed as a method of controlling the amount of cooling water by the control unit 240, but the method of controlling the amount of cooling water is not limited thereto.

The control unit 240 may control the humidity of the air 140 circulating through the antenna 110 and the temperature controller 130 by adjusting the amount of the cooling water.

Referring to FIG. 2, the temperature sensor 230 may measure the temperature value of the air 140 flowing into the antenna 110 through the supply duct 122. 2, an embodiment in which the temperature sensor 230 is disposed between the heater 250 and the supply duct 122 is shown, but the position of the temperature sensor 230 is not limited thereto. That is, the temperature sensor 230 can measure the temperature value of the air flowing into the temperature controller 130 from the antenna 110.

The control unit 240 can set a position at which the temperature sensor 230 measures the temperature of the air 140 circulating through the temperature control device provided with the antenna. In addition, the temperature sensor 230 may transmit the information related to the measured temperature value to the control unit 240.

The control unit 240 can variably adjust the flow rate of the cooling water of the heat exchanger 210 based on the temperature value measured by the temperature sensor 230 so as to keep the temperature of the air flowing into the antenna within a predetermined range have. In one embodiment, the predetermined range is not less than ° c and not more than ° c.

In one embodiment, when the measured temperature value is equal to or greater than the first temperature value close to the upper limit value of the preset range, the control unit 240 can fully (100%) open the flow rate valve and adjust the flow rate of the cooling water to the maximum value have. In addition, when the measured temperature value is less than the first temperature value and is equal to or greater than the second temperature value, the control unit 240 can open the flow rate valve by 40% and adjust the flow rate of the cooling water to 40% of the maximum value. If the measured temperature value is less than the second temperature value and is equal to or greater than the third temperature value, the control unit 240 may open the flow rate valve 30% and adjust the flow rate of the cooling water to 30% of the maximum value. If the measured temperature value is less than the third temperature value and is equal to or greater than the fourth temperature value, the control unit 240 may open the flow rate valve 20% and adjust the flow rate of the cooling water to 20% of the maximum value. If the measured temperature value is less than the fourth temperature value and is equal to or greater than the fifth temperature value, the control unit 240 may open the flow rate valve by 10% and adjust the flow rate of the cooling water to 10% of the maximum value. When the measured temperature value is less than the fifth temperature value, the control unit 240 may completely close (0% open) the flow rate valve so that the cooling water does not flow to the heat exchanger 210. [

2, the heater 250 may heat the air flowing into the antenna 110. [ In this regard, the control unit 240 can operate the heater 250 when the temperature measured by the temperature sensor 230 is lower than a preset temperature value with respect to the air flowing into the antenna 110.

Referring to FIG. 2, the fan unit 260 may supply air to the antenna 110. That is, the fan unit 260 may provide power for controlling the temperature of the antenna 110 such that the air circulates inside the temperature control unit having the antenna shown in FIG. For example, the fan unit 260 may include three centrifugal fans.

In addition, the control unit 240 may determine the operation mode of the pan unit 260 based on whether the power of the antenna 110 is applied or not. More specifically, when the power of the antenna 110 is applied, the control unit 240 can operate all of the three centrifugal fans included in the pan unit 260. In addition, when the power of the antenna 110 is not applied, the control unit 240 may alternately operate one of the three centrifugal fans included in the pan unit 260. [

When one of the three centrifugal fans is alternately operated, the control unit 240 transmits information related to the operation cycle and the operation order of each of the three centrifugal fans to a memory unit (not shown) of the temperature controller 130, Lt; / RTI > For example, when the three centrifugal fans include the first through third centrifugal fans, the controller 240 calculates time information indicating the identification information of each of the first through third centrifugal fans, Can be stored in the memory unit.

Meanwhile, the controller 240 controls the temperature of the air supplied to the antenna measured by the temperature sensor 230, the temperature of the air flowing into the temperature controller, the flow rate of the cooling water flowing in the heat exchanger 210, And output at least one to the display unit (not shown).

The setting unit (not shown) of the temperature controller 130 may set information related to the correspondence between the temperature of the air flowing into the antenna and the flow rate of the cooling water flowing in the heat exchanger 210. In this case, the control unit 240 can variably adjust the flow rate of the cooling water flowing in the heat exchanger 210 based on the information related to the corresponding relationship set by the setting unit.

Hereinafter, various control methods for temperature control of a specific object will be described.

3 is a flowchart showing a temperature control method used in a domestic air conditioner. The control unit of the domestic air conditioner can compare the preset temperature with the detected current temperature when the operation mode of the air conditioner is selected as the cooling mode. In this case, the control unit may perform the cooling operation if the detected present temperature is higher than the set temperature. The control unit may stop the cooling mode if the detected current temperature is lower than the set temperature.

Conversely, when the operation mode of the air conditioner is selected as the heating mode, the control unit can perform the heating operation if the detected current temperature is lower than the set temperature. Further, the control unit may stop the heating mode if the detected current temperature is lower than the set temperature.

4 is a flowchart showing a temperature control method used in an air conditioner for a vehicle. The control unit of the vehicle air-conditioner compares the predetermined set temperature with the detected current temperature, performs the cooling operation when the detected current temperature is higher than the set temperature, and performs the heating operation when the detected current temperature is lower than the set temperature.

5 is a conceptual diagram showing a temperature control method considering the upper and lower limits of the temperature of the air flowing into the antenna. In general, the control method shown in Fig. 5 is a method referred to as an ON / OFF control method. When the temperature of the air flowing into the antenna is a temperature (50) near the upper limit temperature, (100% open). Further, the control section can completely close (0% open) the flow valve at the temperature 51 which is near the upper limit temperature after the start of the cooling.

Then, after the cooling progresses, the controller can apply power to the heater at a temperature 52 near the lower limit temperature. Further, the temperature of the control unit is raised again, and the power of the heater can be released at the temperature 53 near the lower limit temperature. In this method, when the control unit controls the opening / closing timing of the flow rate valve and the power supply of the heater, the upper limit value and the lower limit value may be exceeded unless the temperature change rate of the air flowing into the antenna is taken into consideration. Therefore, for the method shown in FIG. 5, the optimum point must be found through many tests under various conditions. In addition, there is a problem that reliability is lowered because the valve operation operates while moving the maximum movement distance.

6 is a conceptual diagram showing a temperature control method considering a temperature change of air flowing into the antenna. The control unit 240 may adjust the opening degree of the flow rate valve according to the first to sixth temperature values 65, 64, 63, 62, 61, and 60 of the air flowing into the antenna. Thereby, the movement of the flow valve 220 can be minimized.

Fig. 7 is a flowchart showing the temperature control method proposed by the present invention shown in the conceptual diagram shown in Fig.

First, the control unit 240 can determine whether the antenna satisfies the maximum heat generation condition (S710). More specifically, the control unit 240 can determine whether or not the maximum heat generation condition is satisfied based on the operation state of the antenna. For example, when the antenna transmits the transmission signal to the maximum value, the control unit 240 can determine that the maximum heat generation condition is satisfied. In addition, when the antenna receives the transmission signal at a maximum value, the controller 240 can determine that the maximum heat generation condition is satisfied. In addition, when the electronic signal processed by the antenna is greater than a predetermined value, the controller 240 can determine that the maximum heat generation condition is satisfied.

If it is determined in the determining step S710 that the maximum heat generation condition is satisfied, the control unit 240 may fully open the flow rate valve (100% open) (S711).

Next, when the maximum heat generation condition is not satisfied, the temperature sensor 230 can measure the temperature of the air flowing into the antenna (S720).

In the measuring step S720, if the measured temperature value is equal to or higher than the first temperature 65 in FIG. 6, the flow rate valve can be completely opened (100%) to adjust the flow rate of the cooling water to a maximum value S721).

When the measured temperature value is less than the first temperature 65 and is equal to or greater than the second temperature 64 in FIG. 6, the flow rate valve is opened 40%, and the flow rate of the cooling water is set to 40 % (S722).

If the measured temperature value is less than the second temperature 64 and is equal to or higher than the third temperature 63 in FIG. 6, the flow rate valve is opened by 30%, and the flow rate of the cooling water is set to 30 % (S723).

If the measured temperature value is less than the third temperature 63 and is equal to or greater than the fourth temperature 62 in FIG. 6, the flow rate valve is opened by 20%, and the flow rate of the cooling water is set to 20 % (S724).

When the measured temperature value is less than the third temperature 62 and the fourth temperature 61 or more in FIG. 6, the control unit 240 opens the flow rate valve 10% and controls the flow rate of the cooling water to 10 % (S725).

When the measured temperature value is less than the fourth temperature 61 shown in FIG. 6, the control unit 240 can completely close (0% open) the flow rate valve so that the cooling water does not flow to the heat exchanger 210 (S726).

Next, the control unit 240 can operate the heater 250 when the measured temperature value is less than the fifth temperature 60 of FIG. 6 (S730), and when the measured temperature value is not less than the fifth temperature 60 of FIG. 6 The operation of the heater 250 may be canceled (S740).

Next, the control unit 240 may determine whether to maintain the operation of the temperature regulator (S750). In this case, if it is determined that the operation is to be maintained, the control unit 240 may again perform the step S710 of determining whether the maximum heat-generating condition is satisfied or, if not, the operation of the temperature regulator may be terminated.

8 is a flowchart illustrating a fan operation method proposed in the present invention.

First, the control unit 240 can check whether the antenna is powered on (S810).

If the power of the antenna is applied, the control unit 240 can operate all of the three centrifugal fans included in the pan unit 260 based on the checking step S810 (S830). If the power of the antenna is not applied, the control unit 240 can alternatively operate one of the three centrifugal fans included in the pan unit 260 (S840).

 In addition, when one of the three centrifugal fans is operated alternately, the control unit 240 may store information related to each operation cycle and operation order of the three centrifugal fans in the memory unit of the temperature regulator 130 . For example, when the three centrifugal fans include the first through third centrifugal fans, the controller 240 calculates time information indicating the identification information of each of the first through third centrifugal fans, Can be stored in the memory unit.

9 is a graph showing an operation state of a flow rate valve of a temperature controller according to the method proposed by the present invention.

9 (a) and 9 (b), when the method proposed in the present invention is applied, the effect of drastically reducing the operation of the flow rate valve is derived. Thereby, reliability of the control unit 240 in controlling the operation of the flow rate valve can be improved, and wear of the flow rate valve can be reduced.

10 is a graph showing a temperature value distribution of air supplied to the antenna by the temperature controller according to the method proposed by the present invention.

10 (a) and 10 (b), when the method proposed in the present invention is applied, the temperature value of the air flowing into the antenna is uniformly maintained.

The temperature control device and the control method thereof provided with the antenna described herein can be applied not only to the configurations and methods of the embodiments described above but also to a configuration in which all or some of the embodiments are selectively combined .

Claims (9)

antenna;
A temperature controller for controlling the temperature of the antenna;
And a duct communicating between the antenna and the temperature regulator,
The temperature controller includes:
A sensing unit for measuring a temperature value of air flowing into the antenna from the temperature controller;
A heat exchanger for exchanging heat with the air to cool the introduced air;
Based on the measured temperature value to maintain the temperature of the incoming air within a predetermined range,
A controller for variably controlling a flow rate of the cooling water in the heat exchange unit;
And a fan unit for supplying air from the temperature controller to the antenna,
The fan unit includes three centrifugal fans,
Wherein,
When the power of the antenna is applied, all of the three centrifugal fans are operated,
Wherein one of the three centrifugal fans is operated alternately when the power of the antenna is not applied. The method according to claim 1,
Wherein the temperature regulator further comprises a heater for heating the incoming air,
Wherein,
And the heater is operated when the measured temperature value is lower than a predetermined temperature value. delete delete The method according to claim 1,
The temperature controller further includes a memory unit,
Wherein,
When one of the three centrifugal fans is operated alternately,
Wherein the information relating to the operation cycle and the operation order of each of the three centrifugal fans is stored in the memory unit. The method according to claim 1,
And a display unit,
Wherein,
The temperature of the air flowing into the temperature controller from the antenna,
The temperature of the air supplied to the antenna from the temperature controller,
The temperature and /
And outputs information related to at least one of the flow rates of the cooling water to the display unit. The method according to claim 1,
Further comprising: a setting unit configured to set information related to a corresponding relationship between the temperature of the incoming air and the flow rate of the cooling water,
Wherein,
Wherein the controller controls the flow rate of the cooling water based on the information set by the setting unit. The method according to claim 1,
Wherein the antenna is an active phased array radar using a semiconductor type amplifier. Determining whether an operation state of the antenna satisfies a maximum heat generation condition;
Measuring a temperature value of air flowing into the antenna;
Varying the flow rate of cooling water in the heat exchange unit based on the measured temperature value so as to keep the temperature of the introduced air within a predetermined range;
Operating the heater if the measured temperature value is less than or equal to a preset temperature value; And
And determining the operation mode of the fan unit based on whether or not the antenna is powered on,
The fan unit includes three centrifugal fans,
Wherein the determining of the operating mode of the fan unit comprises:
When the power of the antenna is applied, all of the three centrifugal fans are operated,
Wherein one of the three centrifugal fans is alternately operated when the power of the antenna is not applied.

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