JP6163823B2 - Cooling monitoring device, cooling monitoring method and program - Google Patents

Description

  The present invention relates to a cooling monitoring device, a cooling monitoring method, and a program in an electric device that requires cooling.

  In order to prevent dust and dirt drifting in the air from adhering to the cooling device fan and around the ventilation holes and causing the temperature inside the personal computer to rise, some personal computers display a message prompting fan maintenance or cleaning the ventilation holes. In such a personal computer, a timer in the personal computer is used to periodically display a fan to prompt maintenance of the fan and cleaning of the ventilation holes.

  In Patent Document 1, the relationship between the operating rate and temperature of the heat generating component is stored in advance, the temperature of the heat generating component during operation and the temperature of the reference point are measured, the temperature of the heat generating component is estimated, and the temperature of the heat generating component actually measured is estimated. Describes a technique for determining that the cooling capacity has decreased when the temperature is higher than the estimated temperature by a predetermined threshold value or more.

JP 2007-249719 A

  However, since the technique described in Patent Document 1 determines a decrease in the cooling capacity of the fan based on the relationship between the CPU operation rate and the CPU temperature, the relationship between the CPU operation rate and the CPU temperature cannot be obtained. However, there is a problem that it is impossible to determine a decrease in the cooling capacity of the fan. Therefore, there has been a demand for a technique that can determine a decrease in fan cooling capacity using a relationship other than the relationship between the CPU operation rate and the CPU temperature.

  Accordingly, an object of the present invention is to provide a cooling monitoring device, a cooling monitoring method, and a program that can solve the above-described problems.

  In order to achieve the above object, the present invention provides a fan rotation speed control unit that controls the rotation speed of the fan based on a relationship between a predetermined temperature of an object to be cooled and the rotation speed of the fan; A power consumption measuring unit that measures the power consumption of the cooling target, a fan rotational speed controlled by the fan rotational speed control unit, and a power consumption that generates a correspondence relationship between the power consumption measured by the power consumption measuring unit -Rotational speed relationship generator, and the power consumption-rotational speed relationship generator is generated in the state where the cooling capacity of the fan is not reduced and in the state where the cooling capacity of the fan is reduced. A cooling monitoring apparatus comprising: a similarity determination unit that compares correspondences and determines similarity.

  Further, the present invention controls the rotational speed of the fan based on the relationship between a predetermined temperature of the cooling object and the rotational speed of the fan, measures the power consumption of the cooling object cooled by the fan, A correspondence relationship between the fan rotation speed to be controlled and the power consumption to be measured is generated, and the generated power consumption and rotation speed are generated in a state where the cooling capacity of the fan is not lowered and in a state where the cooling capacity of the fan is lowered. Is a cooling monitoring method characterized in that the two correspondences are compared and the similarity is determined.

In the present invention, the computer of the cooling monitoring device is cooled by fan rotation speed control means for controlling the rotation speed of the fan based on the relationship between the predetermined temperature of the object to be cooled and the rotation speed of the fan, and the fan. The power consumption measuring means for measuring the power consumption of the object to be cooled, the rotational speed-consumption that generates the correspondence between the fan rotational speed controlled by the fan rotational speed control means and the power consumption measured by the power consumption measuring means. Comparison of two correspondences between the power consumption and the number of revolutions generated in the state where the power relationship generation unit and the rotation speed-power consumption relationship generation unit do not decrease the fan cooling capacity and the state where the fan cooling capacity decreases. And a program for making it function as similarity determination means for determining similarity.

  According to the present invention, it is possible to determine the decrease in the cooling capacity of the fan using a relationship other than the relationship between the CPU operating rate and the CPU temperature.

It is a figure which shows the minimum structure of the cooling monitoring apparatus 10 of this invention. It is a figure which shows an example of an apparatus provided with the cooling monitoring apparatus 10 of this invention. It is a figure which shows the structure of the cooling monitoring apparatus 10 by 1st embodiment of this invention. It is a figure which shows an example of the relationship between the temperature of CPU20, and the fan rotation speed of the fan. It is a figure which shows an example of the relationship between the power consumption of CPU20, and the fan rotation speed of the fan. It is a figure which shows the processing flow which acquires the reference value used for determination of the cooling capability fall of the fan 30 in the cooling monitoring apparatus 10 by 1st embodiment of this invention. It is a figure which shows the processing flow at the time of determination of the cooling capability fall of the fan 30 in the cooling monitoring apparatus 10 by 1st embodiment of this invention. It is a figure which shows an example of the relationship between CPU power consumption and fan rotation speed in the state which the cooling capacity of the fan has not fallen / it has fallen. It is a figure which shows the structure of the cooling monitoring apparatus 10 by 2nd embodiment of this invention. It is a figure which shows the processing flow which acquires the reference value used for determination of the cooling capability fall of the fan 30 in the cooling monitoring apparatus 10 by 2nd embodiment of this invention. It is a figure which shows the processing flow at the time of determination of the cooling capability fall of the fan 30 in the cooling monitoring apparatus 10 by 2nd embodiment of this invention.

FIG. 1 is a diagram showing a minimum configuration of a cooling monitoring apparatus 10 of the present invention.
As shown in FIG. 1, the cooling monitoring apparatus 10 of the present invention includes at least a fan rotation speed control unit 101, a power consumption measurement unit 102, a power consumption-rotation number relationship generation unit 103, and a similarity determination unit 104. Is provided.
Here, the fan rotation speed control unit 101 is a functional unit that controls the rotation speed of the fan based on a data table indicating the relationship between the temperature of the cooling target and the fan rotation speed.
The power consumption measuring unit 102 is a functional unit that measures the power consumption of the cooling target that is cooled by the fan.
Further, the power consumption-revolution number relationship generation unit 103 generates a data table indicating a correspondence relationship between the fan rotation number detected by the fan rotation number control unit 101 and the power consumption measured by the power consumption measurement unit 102. It is.
In addition, the similarity determination unit 104 includes a data table created by the power consumption-revolution number relationship generation unit 103 when the cooling capacity is not reduced, and data created by the power consumption-revolution number relationship generation unit 103 when the decrease determination is made. It is a functional unit that compares a table and determines the similarity.
In addition, the fan rotation speed control unit 101, the power consumption measurement unit 102, the power consumption-rotation number relationship generation unit 103, and the similarity determination unit 104 of the cooling monitoring apparatus 10 are control units (for example, CPU, Central Processing Unit). Is configured in the cooling monitoring device 10 by executing the program.

<First embodiment>
FIG. 2 is a diagram illustrating an example of an apparatus including the cooling monitoring apparatus 10 of the present invention.
In this figure, an example in which the server 100 includes the cooling monitoring device 10 is shown. In addition to the cooling monitoring device 10, the server 100 includes a CPU 20, a fan 30, and a cooling object temperature sensor 40.
Here, the CPU 20 performs various calculations in the server 100.
The fan 30 cools the CPU 20.
The cooling object temperature sensor 40 is a temperature sensor for detecting the temperature of the CPU 20.
The server 100 is connected via an environmental temperature sensor 50 for detecting the environmental temperature and a cable for transmitting a signal indicating the detected temperature of the sensor. Furthermore, the cooling monitoring device 10 included in the server 100 is connected to the output unit 110 via a cable for transmitting an output signal.

FIG. 3 is a diagram showing a configuration of the cooling monitoring apparatus 10 according to the first embodiment of the present invention.
As shown in FIG. 3, the cooling monitoring device 10 according to the first embodiment includes an environmental temperature determination unit 105, an output control unit 120, in addition to the function indicating the minimum configuration of the cooling monitoring device 10 shown in FIG. 1. An output unit 110 and a storage unit 111 are provided.
Here, the fan rotation speed control unit 101 inputs the temperature of the CPU 20 detected by the cooling object temperature sensor 40 and shows the relationship between the cooling object temperature recorded in the storage unit 111 and the fan rotation speed. This is a functional unit that controls the rotational speed of the fan 30 based on the data table.
The environmental temperature determination unit 105 is a functional unit that inputs the temperature detected by the environmental temperature sensor 50 shown in FIG.
The output control unit 120 is a functional unit that outputs, to the output unit 110, the correspondence between the rotation speed and the power consumption generated by the power consumption-rotation number relationship generation unit 103, the determination result of the similarity determination unit 104, and the like.
The output unit 110 is, for example, a liquid crystal panel or an organic EL panel, and displays various information based on output control by the output control unit 120. The output unit 110 is not limited to the display unit, and may be any device as long as information is correctly transmitted through the human senses.
The storage unit 111 is a storage unit that stores various data and programs necessary for the operation of the cooling monitoring apparatus 10.

FIG. 4 is a diagram illustrating an example of the relationship between the temperature of the CPU 20 and the fan rotation speed of the fan 30.
As shown in this figure, the relationship between the temperature of the CPU 20 and the fan rotation speed of the fan 30 is such that the constant fan rotation speed of the fan 30 is associated on a one-to-one basis for each predetermined temperature range of the CPU 20 temperature. Further, this relationship is recorded as a data table in the storage unit 111, and is a relationship used by the fan rotation speed control unit 101 of the cooling monitoring apparatus 10 to control the fan rotation speed.

FIG. 5 is a diagram illustrating an example of the relationship between the power consumption of the CPU 20 and the fan rotation speed of the fan 30.
This figure shows a correspondence relationship between the CPU power consumption measured by the power consumption measuring unit 102 and the fan rotation speed detected by the fan rotation speed control unit 101 at a certain power consumption.
In this embodiment, the heat generation capability of the CPU when the power consumption is P1 and the cooling capability according to the number of fan rotations when the power consumption is P1 are balanced, and the CPU temperature is constant (equilibrium state). And
In the present embodiment, the heat generation capability of the CPU when the power consumption is P2 and the cooling capability depending on the fan rotation speed when the power consumption is P2 are balanced, and the CPU temperature is constant (equilibrium state). And
Similarly, in the present embodiment, the heat generation capability of the CPU at the power consumption P3 and the cooling capability by the fan rotation speed at the power consumption P3 are balanced, and the CPU temperature is constant (equilibrium state). Shall be.
Further, it is assumed that the cooling capacity at the fan rotation speed R4 [rpm] is higher than the heat generation capacity at the maximum value P5 [W] of the CPU power consumption.

  Here, the CPU temperature at which the CPU power consumption P1 [W] in the equilibrium state is settled is TA [degrees] shown in FIG. 4, the CPU temperature at which P2 [W] is settled is TB [degrees], and the CPU temperature at which P3 is settled as shown in FIG. Is TC [degree] shown in FIG.

  First, consider the relationship between CPU power consumption and fan rotational speed in a state where CPU power consumption P1m [W] is slightly smaller than CPU power consumption P1 [W]. The fan rotation speed at the power consumption P1 in the equilibrium state is the fan rotation speed R1 at the CPU temperature TA [degrees] in FIG. Therefore, the fan rotation speed for the CPU power consumption P1m [W] slightly smaller than P1 [W] in the equilibrium state is the fan rotation speed R1 [rpm at a CPU temperature slightly lower than the CPU temperature TA [degree] in FIG. ]. In such a case, since the cooling capacity of the fan rotation speed R1 [rpm] is higher than the heat generation capacity of the CPU power consumption P1m [W], the CPU temperature gradually decreases. However, as shown in FIG. 4, even if the CPU temperature falls below the CPU temperature TA [degree], the fan rotation speed remains at R1 [rpm]. In addition, in the case of CPU power consumption P1m [W] slightly smaller than CPU power consumption P1 [W] in FIG. 5, the fan rotational speed is R1 [rpm]. The same conditions as the CPU power consumption P1m [W] that is slightly smaller than the CPU power consumption P1 [W] are satisfied by the power consumption O to P1 m [W]. Since the capability is higher, the fan rotation speed at power consumption O to P1 [W] is R1 [rpm].

  Next, consider the relationship between CPU power consumption and fan speed in a state where the CPU power consumption P1p [W] is slightly larger than P1 [W]. The fan rotation speed at the power consumption P1 [W] in the equilibrium state is the fan rotation speed R1 [rpm] at the CPU temperature TA [degrees] in FIG. Therefore, the fan rotation speed for CPU power consumption P1p [W] that is slightly larger than P1 [W] in the equilibrium state is the fan rotation speed R1 [rpm at CPU temperature slightly higher than CPU temperature TA [degree] in FIG. ]. In such a case, since the cooling capacity of the fan rotational speed R1 [rpm] is lower than the heat generation capacity of the CPU power consumption P1p [W], the CPU temperature gradually increases. When the CPU temperature reaches T1 [degree], the fan rotation speed increases from R1 [rpm] to R2 [rpm]. Here, since the fan rotation speed R2 [rpm] has a cooling capacity capable of cooling the electric power up to P2 [W] which is in an equilibrium state, the temperature decreases, and the fan rotation speed is changed from R2 [rpm] to R1 [rpm]. To drop. Here, since the fan rotation speed R1 [rpm] has only a cooling capacity for cooling the electric power up to P1 [W] in an equilibrium state, the temperature rises again and the fan rotation speed becomes R2 [rpm]. Then, the CPU temperature repeatedly rises and falls before and after T1, and the fan rotational speed repeats going back and forth between R1 [rpm] and R2 [rpm]. The conditions similar to the CPU power consumption P1p [W] slightly larger than the CPU power consumption P1 [W] are the power consumption P1p to PT1 (power between P1 and P2 and corresponding to the temperature T1) [W]. Therefore, when the power consumption is P1p to PT1 [W], the fan rotation speed repeats going back and forth between R1 [rpm] and R2 [rpm]. By the same operation, the fan rotation speed fluctuates from R1 [rpm] to R2 [rpm] for each CPU power consumption that is larger than the power consumption P1 in the equilibrium state and smaller than the other power consumption P2 in the equilibrium state. Then, the change from R2 [rpm] to R1 [rpm] is repeated.

Similarly, for each CPU power consumption between P2 in equilibrium and P3 in equilibrium, the fan speed fluctuates from R2 [rpm] to R3 [rpm], and from R3 [rpm] to R2 [ rpm] is repeated.
Furthermore, when the same idea is applied, the fan rotation speed fluctuates from R3 [rpm] to R4 [rpm] for each CPU power consumption between P3 and P4 in an equilibrium state, and R4 [rpm] to R3 [ rpm] is repeated.
In the present embodiment, the similarity determination unit 104 determines the correspondence between the CPU power consumption and the fan rotation speed when the cooling capacity of the fan 30 is not reduced, and the CPU power consumption when the cooling capacity reduction of the fan 30 is measured. And the correspondence of fan speed. Then, the similarity determination unit 104 increases the number of fan rotations with respect to the CPU power consumption when the correspondence relationship between them is not similar, that is, when the cooling capacity of the fan 30 is not reduced. When it is determined that the graph of the correspondence relationship between the rotational speeds has shifted to the left side, it is determined that the cooling capacity of the fan 30 has decreased.
However, as described above, when the fan rotational speed fluctuates from one rotational speed to another rotational speed and repeatedly varies from the other rotational speed to the original rotational speed, the similarity determination unit 104 determines whether the fan rotational speed varies. There is a problem that it is difficult to determine that the number of fan rotations corresponding to the CPU power consumption has increased when measuring the decrease in the cooling capacity of the fan 30 as compared to when the cooling capacity of the 30 has not decreased.
Therefore, the similarity determination unit 104 determines the relationship between the CPU power consumption and the fan rotation speed in the equilibrium state (states where the power consumption is P1, P2, and P3) when the cooling capacity of the fan 30 is not lowered and the fan 30. By comparing this with the measurement of the cooling capacity, it is determined whether the cooling capacity of the fan 30 has decreased.

FIG. 6 is a diagram showing a processing flow for acquiring a reference value used for determination of the cooling capacity reduction of the fan 30 in the cooling monitoring apparatus 10 according to the first embodiment of the present invention.
Here, in the server 100 including the cooling monitoring device 10, the CPU 20, and the fan 30 as illustrated in FIG. 2, the cooling monitoring device 10 illustrated in FIG. 3 controls the fan 30 to cool the CPU 20. The process of the cooling monitoring apparatus 10 will be described.
It is assumed that the load variation of the CPU 20 is moderate and the power consumption variation of the CPU 20 is also moderate. In addition, the storage unit 111 preliminarily records, as a data table, first data indicating the relationship between the temperature of the CPU 20 and the fan rotation speed of the fan 30 as illustrated in FIG.

  In the present invention, under the same condition, that is, when the environmental temperature with the passage of time is the same, the cooling monitoring device 10 is more suitable for measuring the cooling capacity of the fan 30 than when the cooling capacity of the fan 30 is not decreased. As a result of the decrease in fan cooling capacity and the increase in temperature, it is determined whether the fan speed is high. When the cooling monitoring device 10 determines that the fan rotation speed is high, the cooling monitoring device 10 notifies the user of a decrease in cooling capacity, and prompts maintenance of the fan 30 and cleaning of the ventilation holes.

  First, the environmental temperature determination unit 105 of the cooling monitoring device 10 is connected to the environmental temperature detected by the environmental temperature sensor 50 outside the server 100 via a cable connected in a state where the cooling capacity of the fan 30 is not reduced. Measure (Step S1). At this time, the fan rotation speed control unit 101 of the cooling monitoring apparatus 10 reads a data table indicating the relationship between the temperature of the CPU 20 and the fan rotation speed of the fan 30 from the storage unit 111. And the fan rotation speed control part 101 of the cooling monitoring apparatus 10 measures the temperature of CPU20 which the temperature sensor 40 for cooling target detected, and controls the rotation speed of the fan 30 based on the relationship of the read data table ( Step S2). Then, the fan rotation speed control unit 101 outputs the controlled rotation speed of the fan 30 to the power consumption-rotation speed relationship generation unit 103. The fan rotation speed control unit 101 controls the rotation speed of the fan 30 at the timing of the clock signal. Further, the power consumption measuring unit 102 measures the power consumption of the CPU 20 at the same timing as the clock used by the fan rotation speed control unit 101 (step S3). Then, the power consumption measuring unit 102 outputs the measured power consumption of the CPU 20 to the power consumption-rotational speed relationship generating unit 103.

When the rotation speed of the fan 30 at the same timing and the power consumption of the CPU 20 are input, the power consumption-rotation speed relationship generation unit 103 receives the rotation speed of the fan 30 at the same timing in a state where the cooling capacity of the fan 30 is not lowered. The second data including the power consumption of the CPU 20 and the environmental temperature is associated and recorded in the storage unit 111 as a data table (step S4).
As described above, the cooling monitoring apparatus 10 has acquired the second data when the cooling capacity of the fan 30 has not decreased, that is, the reference value used when determining the cooling capacity of the fan 30 is decreased. Here, the process of step S1-step S4 is repeated with respect to several environmental temperature, and the data table under each environmental temperature is produced.

FIG. 7 is a diagram showing a processing flow at the time of determining a decrease in the cooling capacity of the fan 30 in the cooling monitoring apparatus 10 according to the first embodiment of the present invention.
Next, following the process of step S100 consisting of the processes of step S1 to step S4 in the process flow for acquiring the reference value used for determining the cooling capacity decrease of the fan 30 in the cooling monitoring apparatus 10 according to the first embodiment of the present invention. When measuring the cooling capacity of the fan 30 in the server 100, the environmental temperature determination unit 105 of the cooling monitoring device 10 measures the environmental temperature detected by the environmental temperature sensor 50 installed outside the server 100 (step S5). ). And the environmental temperature determination part 105 determines whether it is the same as the environmental temperature measured when the cooling capacity of the fan 30 currently recorded on the memory | storage part 111 is not falling. It is determined that the measurement environment is the same because the environmental temperature acquired in this determination is within a predetermined threshold value based on the environmental temperature when the cooling capacity of the fan 30 is not reduced (step S6). ). Here, the environmental temperature when the environmental temperature measured by the environmental temperature determination unit 105 at the time of measuring the cooling capacity of the fan 30 in step S5 is measured as the second data as a criterion when the cooling capacity of the fan 30 has not decreased. If NO (NO), the process returns to step S5, and the cooling monitoring apparatus 10 measures the ambient temperature when measuring the cooling capacity of the fan 30 and uses it as a criterion for determining a future cooling capacity decrease. . Further, in the process of step S4, the environmental temperature measured by the environmental temperature determination unit 105 when measuring the cooling capacity of the fan 30 is measured when the second data serving as a determination criterion is measured when the cooling capacity of the fan 30 is not decreased. If it is determined that the temperature is the same as the environmental temperature (YES), the power consumption-revolution number relationship generation unit 103 responds to the determination, and the rotation number of the fan 30 at the same timing as the clock used by the fan rotation number control unit 101 is determined. And the power consumption of the CPU 20 are input from the fan rotation speed control unit 101 and the power consumption measurement unit 102, respectively. Then, the power consumption-revolution number relationship generation unit 103 generates the rotation number of the fan 30 at the same timing as the clock used by the fan rotation number control unit 101 when measuring the cooling capacity of the fan 30, the power consumption of the CPU 20, and the environmental temperature. Is recorded in the storage unit 111 as a data table in association with each other (step S7). Similarly, the power consumption / rotation speed relationship generation unit 103 also records, in the storage unit 111, third data when the CPU power consumption is different. Here, the data recorded in the storage unit 111 is a data table having a relationship as shown in FIG. And the similarity determination part 104 cools the fan 30 recorded by the data table of the 2nd data when the cooling capacity of the reference | standard fan 30 recorded by the process of step S2 is not falling, and the process of step S5. Read the data table of the third data measured at the time of measuring the capacity. Then, if the cooling capacity of the fan decreases, it is noted that P1, P2, and P3, which are the switching speeds in FIG. 5, change from the state when the cooling capacity of the fan 30 does not decrease, and the similarity determination unit 104 Are the data table of the second data when the cooling capacity of the reference fan 30 recorded by the process of step S2 is not reduced, and the third data when measuring the cooling capacity of the fan 30 recorded by the process of step S7. And a determination is made as to whether or not a predetermined threshold value for determining that the difference is not the same is exceeded (step S8). The comparison here is, for example, a predetermined number of data with power consumption slightly smaller than the power consumption P2 in the state where the cooling capacity of the fan is not reduced and the state where the cooling capacity of the fan is reduced as shown in FIG. This is a comparison between values obtained by averaging the fan rotation speeds. As can be seen from this figure, when the cooling capacity of the fan is reduced, the CPU power consumption with the fan speed of R2 [rpm] shifts to the low power consumption side compared to the state where the cooling capacity of the fan 30 is not reduced. The average value of the fan speed increases. When the similarity determination unit 104 determines that the difference between the data when the cooling capacity of the reference fan 30 is not reduced and the data when the cooling capacity of the fan 30 is measured does not exceed the threshold value, It is determined that the data is the same, that is, it is determined that there is no change in the value of P2, and the process is terminated. If the similarity determination unit 104 determines that the difference between the data when the cooling capacity of the reference fan 30 is not reduced and the data when the cooling capacity of the fan 30 is measured exceeds the threshold value, the data is It is determined that they are not the same, that is, it is determined that the value of P2 has changed and the cooling capacity of the fan 30 has decreased, and information for urging the user to maintain the fan 30 or clean the ventilation holes is output to the output control unit 120, for example. To do. The similarity determination unit 104 calculates the power consumption and the rotation speed in the state where the cooling capacity of the fan generated by the power consumption-rotation number relationship generation unit 103 has not decreased and in the state where the cooling capacity of the fan has decreased. It may be determined whether or not the two graphs indicating the correspondence relationship are the same based on the similarity of the images. Here, the determination by the image performed by the similarity determination unit 104 is performed by, for example, reversing one of the black and white graphs in black and white, and overlaying the graphs so that the ratio of white in the black region, that is, the image is not reversed. What is necessary is just to determine with two graphs differing and the cooling capacity of the fan having fallen when the ratio which does not correspond exceeds a predetermined threshold value.

  Then, the output control unit 120 outputs information for prompting the user to maintain the fan 30 or clean the ventilation holes to the output unit 110 (step S9). For example, when the output control unit 120 is a display control unit and the output unit 110 is a display unit, the output control unit 120 indicates that “the cooling capacity of the fan has decreased. Please perform maintenance.” A message may be displayed on the output unit 110 to prompt the user for maintenance. The output control unit 120 is not limited to the display control unit. Further, the output unit 110 is not limited to the display unit. The output control unit 120 and the output unit 110 may be anything as long as information can be appropriately notified to the user through the human senses.

  In the present embodiment, the cooling monitoring device 10 determines a decrease in the cooling capacity of the fan based on the relationship between the power consumption of the CPU 20 and the fan rotation speed of the fan 30, but the load on the CPU 20 instead of the power consumption of the CPU 20. Rate may be used. Further, as the load factor of the CPU 20, an application program in which the CPU 20 directly calculates the load factor may be used. In addition, the present invention can be applied to a device serving as a heat source other than the CPU 20 capable of measuring a physical quantity corresponding to a load factor.

  Further, it is assumed that a change in CPU temperature is delayed with respect to the CPU load factor and CPU power consumption. For example, when the load increases, the CPU temperature cannot follow the speed of the CPU load increase, and the timing at which the fan rotation speed increases slightly delays. Therefore, the measurement points are biased slightly to the right of the graph of FIG. When the CPU load decreases, the measurement points are biased to the left from the graph of FIG. Therefore, it is possible to increase the detection accuracy of the cooling capacity decrease by decreasing and increasing the threshold values when comparing the change points in each case of load increase and decrease.

  The processing flow of the cooling monitoring apparatus 10 according to the first embodiment of the present invention has been described above. However, due to the processing of the cooling monitoring apparatus 10 according to the first embodiment, there is a relationship other than the relationship between the CPU operating rate and the CPU temperature. In contrast, a decrease in the cooling capacity of the fan can be determined. Further, since the graph of data used for the determination of the cooling monitoring device 10 is stepped as shown in FIG. 5, the cooling monitoring device 10 can easily detect a change in the graph.

<Second Embodiment>
FIG. 9 is a diagram showing a configuration of the cooling monitoring apparatus 10 according to the second embodiment of the present invention.
As illustrated in FIG. 9, the cooling monitoring apparatus 10 according to the second embodiment replaces the power consumption-rotational speed relationship generation unit 103 of the cooling monitoring apparatus 10 illustrated in FIG. 3 with a power consumption-temperature relationship generation unit 106. It is a configuration.
Here, the similarity determination unit 104 has two correspondences generated by the power consumption-temperature relationship generation unit 106, that is, the relationship between the temperature of the CPU 20 and the power consumption of the CPU 20 when the cooling capacity of the fan 30 is not reduced. It is a functional unit that compares two of the relationship between the temperature of the CPU 20 and the power consumption of the CPU 20 when measuring the cooling capacity of the fan 30 and determines the similarity.
The power consumption-temperature relationship generation unit 106 outputs the output unit 110, the output control unit 120 outputs the correspondence between the rotation speed and power consumption generated by the power consumption-rotation number relationship generation unit 103, the determination result of the similarity determination unit 104, and the like. It is a functional part that outputs to

FIG. 10 is a diagram showing a processing flow for acquiring a reference value used for determination of cooling capacity reduction of the fan 30 in the cooling monitoring apparatus 10 according to the second embodiment of the present invention.
In the present invention, under the same condition, that is, when the environmental temperature with the passage of time is the same, the cooling monitoring device 10 is more suitable for measuring the cooling capacity of the fan 30 than when the cooling capacity of the fan 30 is not decreased. As a result of the decrease in fan cooling capacity and the increase in temperature, it is determined whether the fan speed is high. When the cooling monitoring device 10 determines that the fan rotation speed is high, the cooling monitoring device 10 notifies the user of a decrease in cooling capacity, and prompts maintenance of the fan 30 and cleaning of the ventilation holes.
It is assumed that the load variation of the CPU 20 is moderate and the power consumption variation of the CPU 20 is also moderate. Further, it is assumed that the storage unit 111 records data indicating the relationship between the temperature of the CPU 20 and the fan speed of the fan 30 as a data table as shown in FIG. In addition, the determination of the decrease in the cooling capacity of the fan 30 performed by the cooling monitoring device 10 is based on a change in the graph of the temperature of the CPU 20 with respect to the power consumption of the CPU 20. Since the relationship shown in FIG. 4 is established between the temperature of the CPU 20 and the rotational speed of the fan 30, a graph of the temperature of the CPU 20 with respect to the power consumption of the CPU 20 if the cooling capacity of the fan 30 is reduced, as in the case of the graph shown in FIG. Also changes.

  First, the environmental temperature determination unit 105 of the cooling monitoring device 10 is connected to the environmental temperature detected by the environmental temperature sensor 50 outside the server 100 via a cable connected in a state where the cooling capacity of the fan 30 is not reduced. Measure (Step S1). At this time, the fan rotation speed control unit 101 of the cooling monitoring apparatus 10 reads a data table indicating the relationship between the temperature of the CPU 20 and the fan rotation speed of the fan 30 from the storage unit 111. And the fan rotation speed control part 101 of the cooling monitoring apparatus 10 measures the temperature of CPU20 which the temperature sensor 40 for cooling target detected, and controls the rotation speed of the fan 30 based on the relationship of the read data table ( Step S2). Then, fan rotation speed control unit 101 outputs the measured temperature of CPU 20 to power consumption-temperature relationship generation unit 106. The fan rotation speed control unit 101 controls the temperature of the CPU 20 at the timing of the clock signal. Further, the power consumption measuring unit 102 measures the power consumption of the CPU 20 at the same timing as the clock used by the fan rotation speed control unit 101 (step S10). Then, the power consumption measurement unit 102 outputs the measured power consumption of the CPU 20 to the power consumption-temperature relationship generation unit 106.

When the power consumption-temperature relationship generation unit 106 inputs the temperature of the CPU 20 and the power consumption of the CPU 20 at the same timing as the clock used by the fan rotation speed control unit 101, the fan 30 in a state where the cooling capacity of the fan 30 has not deteriorated. Fourth data including the temperature of the CPU 20, the power consumption of the CPU 20, and the environmental temperature at the same timing as the clock used by the rotation speed control unit 101 is associated and recorded in the storage unit 111 as a data table (step S11).
As described above, the cooling monitoring apparatus 10 has acquired the fourth data when the cooling capacity of the fan 30 has not decreased, that is, the reference value used when determining the cooling capacity of the fan 30 is decreased. Here, the process of step S1-step S2, step S10-step S11 is repeated with respect to several environmental temperature, and the data table under each environmental temperature is produced.

FIG. 11 is a diagram illustrating a processing flow at the time of determining a decrease in the cooling capacity of the fan 30 in the cooling monitoring apparatus 10 according to the second embodiment of the present invention.
Next, following the process of step S100 consisting of the processes of step S1 to step S4 in the process flow for acquiring the reference value used for determining the cooling capacity decrease of the fan 30 in the cooling monitoring apparatus 10 according to the first embodiment of the present invention. When measuring the cooling capacity of the fan 30 in the server 100, the environmental temperature determination unit 105 of the cooling monitoring device 10 measures the environmental temperature detected by the environmental temperature sensor 50 installed outside the server 100 (step S5). ). And the environmental temperature determination part 105 determines whether it is the same as the environmental temperature measured when the cooling capacity of the fan 30 currently recorded on the memory | storage part 111 is not falling. It is determined that the measurement environment is the same because the environmental temperature acquired in this determination is within a predetermined threshold value based on the environmental temperature when the cooling capacity of the fan 30 is not reduced (step S6). ). Here, the environmental temperature when the environmental temperature measured by the environmental temperature determination unit 105 at the time of measuring the cooling capacity of the fan 30 in step S5 is measured as the second data as a criterion when the cooling capacity of the fan 30 has not decreased. If NO (NO), the process returns to step S5, and the cooling monitoring apparatus 10 measures the ambient temperature when measuring the cooling capacity of the fan 30 and uses it as a criterion for determining a future cooling capacity decrease. . Further, in the process of step S6, when the environmental temperature measured by the environmental temperature determination unit 105 when measuring the cooling capacity of the fan 30 is measured, the fourth data serving as a determination criterion is measured when the cooling capacity of the fan 30 is not decreased. If it is determined that the temperature is the same as the environmental temperature (YES), the power consumption-temperature relationship generation unit 106 determines the temperature of the CPU 20 controlled at the same timing as the clock used by the fan rotation speed control unit 101 according to the determination. The power consumption of the CPU 20 is input from each of the fan rotation speed control unit 101 and the power consumption measurement unit 102. The power consumption-temperature relationship generation unit 106 includes the temperature of the CPU 20, the power consumption of the CPU 20, and the environmental temperature at the same timing as the clock used by the fan rotation speed control unit 101 when measuring the cooling capacity of the fan 30. The fifth data is associated and recorded in the storage unit 111 as a data table (step S12). Similarly, the power consumption-temperature relationship generation unit 106 also records the fifth data when the CPU temperature is different in the storage unit 111. Here, the data recorded in the storage unit 111 is a data table having a relationship as shown in FIG. The similarity determination unit 104 then cools the fan 30 recorded by the data table of the fourth data when the cooling capacity of the reference fan 30 recorded by the process of step S2 is not reduced and the process of step S5. Read the data table of the fifth data measured at the time of measuring the ability. If the cooling capacity of the fan decreases, the relationship between the temperature of the CPU 20 and the number of rotations of the fan 30 is established as shown in FIG. 4. Therefore, as in the case of the graph shown in FIG. Note that the graph of CPU 20 temperature versus power consumption also changes. Then, the similarity determination unit 104 uses the data table of the fourth data when the cooling capacity of the reference fan 30 recorded by the process of step S2 is not reduced and the cooling capacity of the fan 30 recorded by the process of step S5. The data table of the fifth data at the time of the measurement is compared, and it is determined whether or not a predetermined threshold value for determining that the difference is not the same has been exceeded (step S13). The comparison here is, for example, a comparison between values obtained by averaging the CPU temperatures of a predetermined number of data near a predetermined power consumption at which the CPU temperature is switched. When the similarity determination unit 104 determines that the difference between the data when the cooling capacity of the reference fan 30 is not reduced and the data when the cooling capacity of the fan 30 is measured does not exceed the threshold value, It is determined that the data is the same, that is, it is determined that there is no change in the value of the predetermined power consumption at which the CPU temperature is switched, and the process is terminated. If the similarity determination unit 104 determines that the difference between the data when the cooling capacity of the reference fan 30 is not reduced and the data when the cooling capacity of the fan 30 is measured exceeds the threshold value, the data is It is determined that they are not the same, that is, the value of a predetermined power consumption at which the CPU temperature is switched is changed, and it is determined that the cooling capacity of the fan 30 has been reduced. Outputs information for prompting Note that the similarity determination unit 104 has a correspondence relationship between power consumption and temperature in a state where the cooling capacity of the fan generated by the power consumption-temperature relationship generation unit 106 is not reduced and in a state where the cooling capacity of the fan is reduced. It may be determined whether or not the two graphs indicating the same are based on the similarity of the images.

  Then, the output control unit 120 outputs information for prompting the user to maintain the fan 30 or clean the ventilation holes to the output unit 110 (step S9). For example, when the output control unit 120 is a display control unit and the output unit 110 is a display unit, the output control unit 120 indicates that “the cooling capacity of the fan has decreased. Please perform maintenance.” A message may be displayed on the output unit 110 to prompt the user for maintenance. The output control unit 120 is not limited to the display control unit. Further, the output unit 110 is not limited to the display unit. The output control unit 120 and the output unit 110 may be anything as long as information can be appropriately notified to the user through the human senses.

  The processing flow of the cooling monitoring device 10 according to the second embodiment of the present invention has been described above. However, the relationship between the power consumption of the CPU 20 and the fan rotation speed of the fan 30 by the processing of the cooling monitoring device 10 according to the second embodiment. Instead, it is possible to determine a decrease in the cooling capacity of the fan 30 based on the relationship between the power consumption of the CPU 20 and the temperature of the CPU 20.

  In the embodiment of the present invention, the case where the CPU 20 included in the server 100 is cooled is shown as an example. However, it is an electric device that requires cooling, and control for increasing cooling stepwise as shown in FIG. The present invention can be applied to any electrical device that performs.

  In addition, although embodiment of this invention was described, the above-mentioned cooling monitoring apparatus 10 has a computer system inside. The process described above is stored in a computer-readable recording medium in the form of a program, and the above process is performed by the computer reading and executing this program. Here, the computer-readable recording medium means a magnetic disk, a magneto-optical disk, a CD-ROM, a DVD-ROM, a semiconductor memory, or the like. Alternatively, the computer program may be distributed to the computer via a communication line, and the computer that has received the distribution may execute the program.

  The program may be for realizing a part of the functions described above. Furthermore, what can implement | achieve the function mentioned above in combination with the program already recorded on the computer system, and what is called a difference file (difference program) may be sufficient.

10 ... Cooling monitoring device 20 ... CPU
30 ... Fan 40 ... Temperature sensor for cooling object 50 ... Temperature sensor for environmental temperature 100 ... Server 101 ... Fan rotation speed control unit 102 ... Power consumption measuring unit 103 ... Power consumption-rotational speed relationship generating unit 104 ... Similarity determining unit 105 ... Environmental temperature determining unit 106 ... Power consumption-temperature relationship generating unit 110 ... Output unit 111 ... Storage unit 120 ...・ Output control unit

Claims (7)

A fan rotational speed control unit that controls the rotational speed of the fan based on a relationship between a predetermined temperature of the cooling object and the rotational speed of the fan;
A power consumption measuring unit that measures the power consumption of the cooling object cooled by the fan;
A power consumption-rotational speed relationship generating unit that generates a correspondence relationship between the fan rotational speed controlled by the fan rotational speed control unit and the power consumption measured by the power consumption measuring unit;
The power consumption-rotational speed relationship generation unit compares two correspondence relationships of power consumption and rotational speed generated in a state where the cooling capacity of the fan is not reduced and a state where the cooling capacity of the fan is reduced. A similarity determination unit for determining
A cooling monitoring device comprising: The relationship between the predetermined temperature of the object to be cooled and the rotational speed of the fan is such that the constant fan rotational speed of the fan has a one-to-one correspondence with each of the different predetermined temperature ranges for the object to be cooled. The cooling monitoring device according to claim 1, wherein the constant fan rotation speed of the fan increases as the temperature in the temperature range increases. The similarity determination unit is a correspondence relationship between the power consumption and the rotational speed in a state where the cooling capacity of the fan generated by the power consumption-rotational speed relationship generation unit is not decreased and in a state where the cooling capacity of the fan is decreased. The cooling monitoring device according to claim 1, wherein it is determined whether or not two graphs indicating the same are the same based on the similarity of the images. And temperature relation creation section, - the temperature of the object to be cooled, the power consumption for generating the relationship between the power consumption measuring the power consumption measuring section
With
The similarity determination unit, the power - and state in which no degradation of the cooling performance of the resulting fan temperature relation creation section, in a reduced state of the fan cooling capacity, two corresponding relationship between power and temperature The cooling monitoring device according to any one of claims 1 to 3, wherein the similarity is determined. The similarity determination unit indicates a correspondence relationship between power consumption and temperature in a state where the cooling capacity of the fan generated by the power consumption-temperature relationship generation unit is not decreased and in a state where the cooling capacity of the fan is decreased. It is determined whether two graphs are the same based on the similarity of an image. The cooling monitoring apparatus of Claim 4 characterized by the above-mentioned. Controlling the rotational speed of the fan based on the relationship between the predetermined temperature of the object to be cooled and the rotational speed of the fan;
Measure the power consumption of the object being cooled by the fan,
Generating a correspondence relationship between the fan speed to be controlled and the power consumption to be measured;
Comparing the two correspondence relationships between the generated power consumption and the rotational speed in a state where the cooling capacity of the fan is not lowered and a state where the cooling capacity of the fan is lowered, and determining the similarity,
The cooling monitoring method characterized by the above-mentioned. Cooling monitoring computer,
Fan rotational speed control means for controlling the rotational speed of the fan based on a relationship between a predetermined temperature of the cooling object and the rotational speed of the fan;
Power consumption measuring means for measuring the power consumption of the cooling object cooled by the fan;
A rotational speed-power consumption relationship generating means for generating a correspondence relationship between the fan rotational speed controlled by the fan rotational speed control means and the power consumption measured by the power consumption measuring means;
The rotation speed-power consumption relationship generating means compares two correspondence relationships between the generated power consumption and the rotation speed in a state where the cooling capacity of the fan is not reduced and a state where the cooling capacity of the fan is reduced. Similarity determination means for determining
A program characterized by functioning as

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