Patent Application
20070116553
This Non-provisional application claims priority under 35 U.S.C. §119(a) on Patent Application No(s). 094141110 filed in Taiwan, Republic of China on Nov. 23, 2005, the entire contents of which are hereby incorporated by reference.
1. Field of Invention
The present invention relates to a fan system and a temperature-sensing protecting device thereof and, in particular, to a fan module with a temperature-sensing element and a temperature-sensing protecting device thereof.
2. Related Art
In general, most electronic systems have a fan system to ensure that the electronic systems can be kept at the normal working temperature such that the electronic system can operate normally. The fan system has predetermined operating specifications, such as the operating temperature and the likes.
As shown in
However, the analog starting control chip 13 has a high price, so that the overall manufacturing cost of the fan system 1 is too high. Besides, the analog starting control chip 13 cannot provide the function of soft-start.
Therefore, it is an important subject of the invention to provide a fan system and a temperature-sensing protecting device thereof to solve the above mentioned problem.
In view of the foregoing, the invention is to provide a fan system, which disables the fan system when the operating temperature detected by a temperature-sensing element is too high or too low, and a temperature-sensing protecting device thereof.
To achieve the above, a fan system of the invention includes a fan module, a starting module, a temperature-sensing element and a controlling module. In the invention, the starting module is electrically connected with the fan module for starting it. The temperature-sensing element generates a sensing signal in accordance with an ambient temperature. The controlling module receives the sensing signal for controlling the starting module. When the ambient temperature is higher than a first temperature or is lower than a second temperature, the controlling module controls the starting module to disable the fan module.
To achieve the above, the invention also discloses a temperature-sensing protecting device, which cooperates with a fan module. The temperature-sensing protecting device includes a starting module, a temperature-sensing element and a controlling module. The starting module is electrically connected with the fan module for starting it. The temperature-sensing element generates a sensing signal in accordance with an ambient temperature. The controlling module receives the sensing signal for controlling the starting module. When the ambient temperature is higher than a first temperature or is lower than a second temperature, the controlling module controls the starting module to disable the fan module.
As mentioned above, the fan system and temperature-sensing protecting device of the invention have a temperature-sensing element for sensing the operating temperature of a fan system. Then, when the operating temperature is too high or too low, the fan module is disabled for protecting it. Compared with the prior art, the fan system and temperature-sensing protecting device of the invention utilize the temperature-sensing element to detect the operating temperature for ensuring that the fan system can operate normally and replacing the analog starting control chip to reduce the overall manufacturing cost.
The invention will become more fully understood from the detailed description given herein below illustration only, and thus is not limitative of the present invention, and wherein:
The present invention will be apparent from the following detailed description, which proceeds with reference to the accompanying drawings, wherein the same references relate to the same elements.
The fan system 2 includes a fan module 21, a starting module 22, a controlling module 23 and a temperature-sensing element 24. The fan module 21 has a fan. Of course, the fan module 21 may have a plurality of fans according to the heat dissipating requirement so as to enhance the heat dissipating effect.
In the fan system 2, the starting module 22 is electrically connected with the fan module 21 so as to start it. The temperature-sensing element 24 produces a sensing signal Vt in accordance with an ambient temperature. The temperature-sensing element 24 may be a thermistor (thermal resistor). In this embodiment, the temperature-sensing element 24 is a negative temperature coefficient (NTC) thermistor. The ambient temperature may be the internal temperature of the electronic system, so that the temperature-sensing element 24 produces the sensing signal Vt, e.g. a voltage value, in accordance with an ambient temperature. Based on the characteristic of the NTC thermistor, the resistance of the temperature-sensing element 24 decreases and the voltage of the sensing signal Vt decreases when the internal temperature of the electronic system increases. On the contrary, the resistance of the temperature-sensing element 24 increases and the voltage of the sensing signal Vt increases when the internal temperature of the electronic system decreases.
The controlling module 23 receives and controls the starting module 22 in accordance with the sensing signal Vt. When the ambient temperature is higher than a first temperature or lower than a second temperature, the controlling module 23 controls the starting module 22 to disable the fan module 21 for preventing the fan system 21 from being damaged caused by the improper operation under abnormal operating temperature. In this embodiment, the first temperature and the second temperature are determined in accordance with the operating specifications of the fan system 2. The first temperature is the upper limit operating temperature of the fan system 2 such as 70° C., and the second temperature is the lower limit operating temperature of the fan system 2 such as −40° C.
With reference to
Each of the first switch element Q1 and the second switch element Q2 may be a transistor or any other electronic element with the switch function. In this embodiment, the first the first switch element Q1 and the second switch element Q2 are both NMOS transistors.
Regarding to the first control unit 231, a drain D of the first switch element Q1 is electrically connected with the starting module 22 for controlling the starting module 22, and a source S of the first switch element Q1 is grounded.
The first comparator element U1 includes a first input terminal input1 a second input terminal input2, and an output terminal output. In this embodiment, the first input terminal input1 is a noninverting input terminal and the second input terminal input2 is an inverting input terminal.
The first input terminal input1 receives a first reference signal Vref1, which is produced from a voltage-dividing circuit composed of at least two resistors. The specifications of the resistors can be chosen according to the requirement of user for adjusting the first reference signal Vref1. In this case, the first reference signal Vref1 is used to determine the upper limit operating temperature of the fan system 2. The second input terminal input2 receives the sensing signal Vt. The output terminal output is electrically connected with a gate G of the first switch element Q1 for controlling the first switch element Q1. To make the invention more comprehensive, the following description assumes that the voltage gain value of the first comparator element U1 is equal to 1. When the sensing signal Vt is lower than the first reference signal Vref1, the output terminal output delivers a positive voltage to start the first switch element Q1 so as to control the starting module 22 to disable the fan module 21.
In addition, the second input terminal inputs and the output terminal output of the first comparator element U1 are electrically connected with a resistor R1, so that the first comparator element U1 may have a precise temperature transition characteristic. For example, the first control unit 231 is supposed to control the starting module 22 to disable the fan module 21 when the first temperature reaches 70° C. However, the starting module 22 practically disables the fan module 21 when the first temperature is 72° C. due to the characteristic of the electronic element, which causes an error originally. For preventing the above mentioned problem, the resistor R1 is set between the second input terminal input2 and the output terminal output of the first comparator element U1 for compensating the feedback voltage value. Therefore, the first comparator element U1 can precisely control the starting module 22 to disable the fan module 21 when the temperature reaches 70° C. Accordingly, the precise temperature transition characteristic can be achieved.
Regarding to the second control unit 232, a drain D of the second switch element Q2 is electrically connected with the starting module 22 for controlling it, and a source S of the second switch element Q2 is grounded
The second comparator element U2 includes a first input terminal input1, a second input terminal input2, and an output terminal output. In this embodiment, the first input terminal input1 is a noninverting input terminal, and the second input terminal input2 is an inverting input terminal.
The first input terminal input1 receives the sensing signal Vt and the second input terminal input2 receives a second reference signal Vref2 producing from the voltage-dividing circuit composed of at least two resists. The specifications of resistors can be chosen according to the requirement of user for adjusting the second reference signal Vref2. In this case, the second reference signal Vref2 is used to determine the lower limit operating temperature of the fan system 2. The output terminal output is electrically connected with a gate G of the second switch element Q2 for controlling the second switch element Q2. To make the invention more comprehensive, the following description assumes that the voltage gain value of the second comparator element U2 is equal to 1. When the sensing signal Vt is higher than the second reference signal Vref2, the output terminal output delivers a positive voltage to start the second switch element Q2 so as to control the starting module 22 to disable the fan module 21. In addition, a resistor R2 is set between input terminal input1 and the output terminal output of the second comparator element U2, and the operation of the resistor R2 is the same as that of the above-mentioned resistor R1. Therefore, the second comparator element U2 may have precise temperature transition characteristic.
As mentioned above, when the sensing signal Vt is lower than the first reference signal Vref1, or higher than the second reference signal Vref2, both the output terminals output of the first comparator element U1 and the second comparator element U2 deliver a positive voltage signal in order to control the starting module 22 to disable the fan module 21.
In this embodiment, the starting module 22 includes a third switch element Q3, a fourth switch element Q4, at least a capacitor C, at least a resistor R3, and a plurality of diodes D1 and D2. Each of the third switch element Q3 and the fourth switch element Q4 is a transistor or any other electronic element with the switch function. In this embodiment, the third switch element Q3 is a PMOS transistor, and the fourth switch element Q4 is an NMOS transistor.
A source S of the third switch element Q3 is electrically connected with the diodes D1 and D2. A drain D of the third switch element Q3 is electrically connected with the fan system 21 for starting the fan system 21. A gate G of the third switch element Q3 is electrically connected with a drain D of the fourth switch element Q4. A terminal of the capacitor C is electrically connected with the source S of the third switch element Q3. The resistor R3 is electrically connected with another terminal of the capacitor C. In addition, each of the diodes D1 and D2 may be a Schottky diode for avoiding the reverse current. A gate G of the fourth switch element Q4 is electrically connected with the drain D of the first switch element Q1 and the drain D of the second switch element Q2.
The operation principle of the fan system 2 will be described in the following. When the internal temperature of the electronic system is between the first temperature and the second temperature (the temperature range of normal operation), the sensing signal Vt of the temperature-sensing element 24 is higher than the first reference signal Vref1 and lower than the second reference signal Vref2. In this case, the first switch element Q1 and the second switch element Q2 will be turned off and the fourth switch element Q4 will be turned on.
Then, the capacitor C starts to charge. When the voltage value of the capacitor C reaches the starting voltage of the third switch element Q3, the third switch element Q3 is turned on to enable the fan module 21 for dissipating the heat. To be noted, the charge circuit of the capacitor C and the resistor R3 enables the current flowing through the fan module 21 to increase at a slow rate such that the effect of soft starting can be achieved.
When the internal temperature of the electronic system is higher than the first temperature, the sensing signal Vt is lower than the first reference signal Vref1 to turn on the first switch element Q1. Accordingly, the fourth switch element Q4 and the third switch element Q3 are turned off to disable the fan module 21 in order to achieve the protection and efficiency.
Similarly, when the internal temperature of the electronic system is lower than the second temperature, the sensing signal Vt is higher than the second reference signal Vref2 to turn on the second switch element Q2. Accordingly, the fourth switch element Q4 and the third switch element Q3 will be turned off to disable the fan module 21 in order to achieve the protection and efficiency. As mentioned above, the temperature-sensing element 24 of the fan system 2 senses that whether the internal temperature is higher than the upper limit operating temperature or lower than the lower limit operating temperature. If so, the fan system 2 will compulsorily disable the fan module 21 for preventing it from damage.
The invention also discloses a temperature-sensing protecting device, which cooperates with a fan module. The temperature-sensing protecting device includes a starting module, a temperature-sensing element and a controlling module. In this embodiment, the starting module, temperature-sensing element and controlling module of the temperature-sensing protecting device have the same constructions and functions as those of the previously mentioned starting module 22, temperature-sensing element 24 and controlling module 23, so the detailed descriptions thereof will be omitted for concise purpose.
As mentioned above, the fan system and temperature-sensing protecting device of the invention have a temperature-sensing element for sensing the operating temperature of a fan system. Then, when the operating temperature is too high or too low, the fan module is disabled for protecting it. Compared with the prior art, the fan system and temperature-sensing protecting device of the invention utilize the temperature-sensing element to detect the operating temperature for ensuring that the fan system can operate normally and replacing the analog starting control chip to reduce the overall manufacturing cost.
Although the invention has been described with reference to specific embodiments, this description is not meant to be construed in a limiting sense. Various modifications of the disclosed embodiments, as well as alternative embodiments, will be apparent to persons skilled in the art. It is, therefore, contemplated that the appended claims will cover all modifications that fall within the true scope of the invention.
| Number | Date | Country | Kind |
|---|---|---|---|
| 094141110 | Nov 2005 | TW | national |
