PC Hardware Tuning & Acceleration

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Peltier coolers are thermoelectric refrigerators based on the Peltier effect — a phenomenon named after French watchmaker and amateur physicist Jean C. A. Peltier (1785–1845).

Peltier made his discovery almost 170 years ago, in 1834. The idea behind this phenomenon was revealed several years later, in 1838, by German physicist Heinrich F. E. Lenz (1804–1865). While experimenting with an electric current flowing through the junction of two dissimilar conductors, Lenz placed a drop of water into a small cavity at the junction of two bars made of bismuth (Bi) and antimony (Sb). When the electric current flowed in one direction, the drop of water froze. When the current flowed in the opposite direction, the frozen water melted. This experiment showed that when an electric current flows through the junction of two dissimilar conductors, that junction will either absorb or release heat, depending on the direction of the current flow. This phenomenon was named the Peltier effect.

This effect is the reverse of a discovery made in 1821 by German physicist Thomas J. Seebeck (1770–1831). This phenomenon takes place in a closed electric circuit consisting of dissimilar metals or semiconductors. If there is a temperature difference at the two junction points of dissimilar metals or semiconductors, voltage is induced in the circuit.

According to the well-known Joule's law, a conductor carrying a current generates heat proportional to the product of the resistance (R) of the conductor and the square of the current (I). Thus, Joule heat that evolves during a period of time (t) is calculated using the following formula:

(Formula 11.1) 

In contrast to Joule heat, Peltier heat is proportional to the current, and the direction of heat transfer is reversed if the current is reversed. Experiments have shown that Peltier heat can be expressed by the following formula:

(Formula 11.2) 

Here, q is the electric charge (q = I × t), and P is the so-called Peltier factor, the value of which depends both on the properties of the dissimilar materials carrying the current and on their temperatures.

Peltier heat is positive if it is released; otherwise, it is negative.

In the experiment conducted as shown in Fig. 11.1, the same Joule heat will be released in each calorimeter if both wires have the same resistance (Cu + Bi). This heat can be calculated using the following formula:

(Formula 11.3) 

Figure 11.1: Arrangement for measuring Peltier heat (Cu — copper, Bi — bismuth)

Peltier heat, on the other hand, will be positive in one calorimeter and negative in the other. This experiment measured Peltier heat and derived the Peltier factor values for different pairs of conductors.

Note that the Peltier factor strongly depends on the temperature. Several Peltier factor values for different combinations of metals and alloys at different absolute temperatures (Kelvin scale, or °K) are provided in Table 11.1.

Table 11.1: Peltier Factors for Pairs of Conductors

Fe - constantan

Cu-Ni

Pb - constantan

T(°K)

P(mV)

T(°K)

P(mV)

T(°K)

P(mV)

273

13.0

292

8.0

293

8.7

299

15.0

328

9.0

383

11.8

403

19.0

478

10.3

508

16.0

513

26.0

563

8.6

578

18.7

593

34.0

613

8.0

633

20.6

833

52.0

718

10.0

713

23.4

The Peltier factor, an important technical characteristic of materials, can be calculated using the Thomson coefficient, rather than having to be measured, as follows:

(Formula 11.4) 

Here, P is the Peltier factor, α is the Thomson coefficient, and T is the absolute temperature.

This discovery had a huge effect on subsequent developments in physics and, later, in engineering.

The idea of the effect is this: When an electric current flows through the junction of two dissimilar materials, besides Joule heat (which always is produced), additional heat known as Peltier heat is either produced or absorbed, depending the direction of the current or of the temperature gradient. The degree to which this effect is manifested largely depends on the chosen conductors and the electric modes used.

A classic theory explains the Peltier effect. Electrons, moved by the current from one conductor to another, speed up or slow because of the internal potential difference at the junction point. In the first scenario, the kinetic energy of the electrons increases and is subsequently released as heat. In the second situation, the kinetic energy of the electrons decreases, and this energy loss is compensated by heat absorption. The second material, as a result, will cool.

The Peltier effect, like other thermoelectric phenomena, most strongly manifests itself in semiconductor circuits, composed of n- and p-type semiconductors.

Consider the thermoelectric processes that take place at the contact of such semiconductors. Suppose that the electric field direction causes electrons in the n-semiconductor and holes in p-semiconductor to move toward one another. After passing through the boundary, an electron enters the p-semiconductor zone and takes the place of a hole. This recombination releases heat (Fig. 11.2).

Figure 11.2: Release of Peltier heat at the contact of n- and p-type semiconductors

If the direction of the electric field is reversed, the electrons and holes will move in opposite directions. Holes moving from the boundary will increase in number because new pairs will be generated when electrons pass from the p-semiconductor to the n-semiconductor. The generation of such pairs consumes energy, and this energy loss is compensated by heat oscillations of the atomic lattice. Electrons and holes, generated as a result of appearing pairs, will be driven in opposite directions by the electric fields. Therefore, new pairs will continue to appear as long as there is a current through the contact. This will result in heat absorption (Fig. 11.3).

Figure 11.3: Absorption of Peltier heat at the contact of n- and p-type semiconductors

Thus, depending on the direction of the electric current through the contact of different types of semiconductors (p-n- and n-p-junctions), heat will be released or absorbed as electrons (n) and holes (p) interact and as new pairs of charges are recombined or generated. The usage of p- and n-semiconductors in thermoelectric refrigerators is illustrated in Fig. 11.4.

Figure 11.4: Using p- and n-semiconductors in thermoelectric refrigerators

Joining large numbers of n- and p-semiconductor junctions creates cooling elements — Peltier modules of significant capacity. The structure of a semiconductor Peltier module is shown in Fig. 11.5.

Figure 11.5: Structure of a Peltier module

The Peltier module is a thermoelectric refrigerator that consists of coupled p- and n-type semiconductors, which constitute p-n- and n-p-junctions. Each junction has heat contact with one of two heatsinks. If an electric current of a certain polarity passes through the junction, the temperature between the heatsinks in the Peltier module will drop: One heatsink will work as a refrigerator, and the other will generate and remove the heat. When the cold side of the Peltier module is joined to the surface of the object being protected, this module acts as a heat pump. This heat pump moves the heat from this object to the hot side of the module, which is cooled by air or water. Like any heat pump, it can be described by thermodynamic formulas. Therefore, Peltier modules can be called not only thermoelectric, but also thermodynamic modules.

Fig. 11.6 shows an external view of a typical Peltier module.

Figure 11.6: External view of a typical Peltier module

In a typical module, temperature can differ tens of degrees. If the hot side is cooled adequately, the other side will reach negative Celsius temperatures. To increase the temperature difference, it is possible to cascade properly cooled Peltier modules. This method provides a simple, reliable, and inexpensive way of obtaining a temperature difference that will cool electronic components efficiently.

Fig. 11.7 shows an example of cascaded Peltier modules.

Figure 11.7: Cascaded Peltier modules

A cooling component based on Peltier modules is often called an active Peltier cooler, or simply a Peltier cooler.

Peltier modules make coolers more efficient than standard coolers based on the traditional heatsink-and-fan combination. In the process of designing and running coolers that use Peltier modules, you must keep in mind certain traits. These features are the results of the modules' construction, the principles of their operation, the architecture of the hardware of a modern computer, and the functional capabilities of the system and application software.

A key role is played by the power of the Peltier module, which generally depends on its size. A weak module will not be able to guarantee the necessary level of cooling, which may lead to overheating and failure of a cooled electronic element, such as a processor. However, using a Peltier module that is too powerful may lower the temperature of the cooling heatsink to such a level that the moisture in the air condenses — a dangerous situation for electronic circuits. Water constantly formed by condensation may cause the electronic circuits of the computer to short-circuit. This is the time to recall that the distance between lead wires in modern circuit boards is often only a fraction of a millimeter.

Nevertheless, powerful Peltier modules in high-performance coolers and additional cooling systems allowed KryoTech and AMD, in a combined research project, to overclock AMD processors created with traditional technology beyond 1 GHz. They almost doubled the operating frequency. However, the given performance level was reached under conditions that ensured the stability and reliability of the processors working in overclocked modes. The result of such experimental overclocking was a performance record among 80x86 processors.

KryoTech is famous for more than its experiments related to extreme processor overclocking. Its facilities for cryogenic freezing of computer components also have become widely known. They have been equipped with appropriate electronic components and employed as platforms for many high-performance servers and workstations. Meanwhile, AMD confirmed the high level of its products and received experimental materials for further improvement of the architecture of its processors. Similar research has been conducted with Intel Celeron, Pentium II, and Pentium III processors and has increased performance significantly.

Note that Peltier modules, in the process of operating, give off a relatively large amount of heat. For this reason, you should not only have a powerful fan for your cooler, but also a means of lowering the temperature of the inside of the computer's case to avoid overheating the rest of the components. To do this, you should use additional fans in the construction of the case.

An external view of an active cooler that uses semiconductor Peltier modules is presented in Fig. 11.8.

Figure 11.8: External view of a cooler with a Peltier module

Examples of Peltier modules manufactured in lots are Osterm products (http://www.osterm.ru). They are distinguished by their maximum consumed current (Imax, in amperes), their maximum voltage (Umax, in volts), cooling power (Qcmax, in watts), the maximum temperature drop (dTmax, in kelvins) between the hot and cold sides measured in a vacuum without a workload, and their dimensions.

Table 11.2 lists the working parameters for some Peltier modules manufactured in lots.

Table 11.2: Peltier Modules from Osterm

Serial number

Imax (A)

Umax (V)

Qcmax (W)

dTmax (°K)

L × W × H (mm)

K1-127-1/0.8

6.0

15.4

50.0

71

30 × 30 × 3.1

K1-241-1/0.8

6.0

29.2

95.0

71

40 × 40 × 3.1

K1-127-1/1.3

3.9

15.4

33.4

73

30 × 30 × 3.6

K1-241-1/1.3

3.9

29.2

63.4

73

40 × 40 × 3.6

K1-127-1/1.5

3.0

15.4

27.0

73

30 × 30 × 3.8

K1-241-1/1.5

3.0

29.2

51.2

73

40 × 40 × 3.8

K1-71-1.4/1.1

8.5

8.6

41.9

71

30 × 30 × 3.8

K1-127-1.4/1.1

8.5

15.4

75.0

71

40 × 40 × 3.8

K1-71-1.4/1.5

6.0

8.6

30.0

73

30 × 30 × 3.9

K1-127-1.4/1.5

6.0

15.4

53.0

73

40 × 40 × 3.9

K1-127-2/1.5

13.0

15.5

120.0

73

55 × 55 × 4.6

Keep in mind that cooling systems based on Peltier modules are used not only in electronic systems, but also in computers. Similar modules are used to cool various high-precision devices. This primarily applies to experiment-based research in physics, chemistry, and biology.

Examples of several Peltier modules released by Osterm are shown in Figs. 11.9–11.13.

Figure 11.9: Semiconductors of p- and n-types in a Peltier module

Figure 11.10: Tiny Peltier module

Figure 11.11: Shaped Peltier module

Figure 11.12: Peltier module with one ceramic platter removed

Figure 11.13: Cascaded Peltier module

Information on modules in Peltier coolers, including their features and the results of their usage, can be found on the Internet at Web addresses including:

Features of Operation

Peltier modules, when used to cool electronic elements, have relatively high reliability. In contrast to refrigerators created using traditional technology, they do not have moving parts. To increase the efficiency of their operation, these modules can be cascaded. Cascading allows protected electronic components to cool below 0°C (32°F), even with significant power dissipation.

Besides the obvious advantages, Peltier modules have some specific properties that must be considered when using them in cooling equipment. Some of these properties have been mentioned, but to correctly use a Peltier module, you need to take a more detailed look at these characteristics. The following operating features are among the most important:

Besides the features already mentioned, you must consider situations that use thermoelectric Peltier modules to cool high-performance CPUs in powerful computers.

The efficiency of Peltier module usage depends on the model and its operating modes. Choosing a nonoptimal model and setting incorrect operating modes can lead to dangerous situations, because such choices do not ensure the required operating conditions for the cooled components. They can even result in the failure of the components to be protected. The optimal choice of a Peltier module is not a trivial task.

Fig. 11.14 illustrates one of the calculation methods used to select a Peltier modules. (This graph is published with the permission of Osterm.) The graph shows the thermoelectric characteristics of a Peltier modules manufactured in lots. The measurements are as follows:

Figure 11.14: Thermoelectric characteristics of a Peltier module

The values of these parameters of the Peltier module depend on the temperature of its hot side. They are different from the values specified in documentation, where all characteristics are provided for a temperature of 300°K (27°C).

Performing calculations based on this graph implies the following:

  1. Using the U(I) graph, for the selected U voltage, determine the I current that flows through the Peltier module. The value of the I current must fit within the range of the ascending part of the dT(I) curve.

  2. For the value of the I current, choose characteristic using the curves that determine the dependence of dT on Qc (in the lower left part of the graph).

  3. With the known values of Th and dT, determine the temperature of the cold side of the Peltier module (Tc), calculated according to the following formula:

    (Formula 11.5) 

Here, Tc is the temperature of the cold side of the module, Th is the temperature of the hot side of the module, and dT is the temperature difference.

From the graphs of the functions illustrating the dependence of dT on Qc, it is obvious that as the thermal power (Qc) of the cooled element increases, the temperature drop between the hot (Th) and cold (Tc) sides of the Peltier module decreases. (See Formula 11.5.) At the same time, the higher the current flowing through the module (defined by the U voltage), the greater the dT difference, provided that the Qc thermal power is fixed.

The following example illustrates the calculation required to choose a Peltier module. It is based on the following initial conditions: The supplied voltage is 12 V; the thermal powers of the element to be cooled are 20 W, 40 W, and 60 W; and the temperature of the hot side of the Peltier module (equal to the temperature of the base of the heatsink installed on the Peltier module) is 50°C. The calculation produces the following:

  1. For a voltage of 12 V, the current is 5 A.

  2. For a current of 5 A and a thermal power of the cooled element equal to 20 W, the temperature difference (dT) is approximately 45°K (45°C). At 40 W, it is 25°K (25°C), and at 60 W, it is 4°K (4°C).

  3. Given the values of temperature difference (dT) and of the temperature of the hot side of the Peltier module, which is 323°K (50°C) in this example, it is possible to calculate the Tc temperature for each Qc value. When the thermal power of the cooled element is 20 W, the temperature of the cold side of the Peltier module is 278°K (5°C). At 40 W, it is 298°K (25°C), and at 60 W, it is 319°K (46°C).

If a more powerful Peltier module is used, it is possible to achieve a greater temperature difference between the hot and cold sides. For example, a module with a Qc of 131 W, an I of 8.5 A, and a U of 28.8 V will ensures a temperature difference of 308°K (35°C) to 313°K (40°C) for objects with a thermal power equal to 60 W.

When choosing an appropriate module based on cooling power, keep in mind the module's thermal power. For example, when the module under consideration operates in the chosen modes (U = 12 and I = 5), this power is 60 W. There also is the thermal power of the element being cooled. The heat flux generated by these sources is a heavy burden for a cooling system.

Correctly chosen and appropriately run Peltier modules are efficient cooling devices that ensure a temperature for the case of the cooled element below the ambient temperature.

Cooling devices normally composed of a heatsink and a fan must not only dissipate rather powerful heat flux, they also must ensure a low temperature on the hot side of the Peltier module. The module ensures the temperature difference between its hot and cold sides; therefore, the lower the temperature supported on its hot side, the lower the temperature of its cold side. (See Formula 11.5.)

If traditional cooling devices can't ensure the required parameters, one possible solution is a water cooling system. Again, the temperature of the cold side of the Peltier module, and, consequently, that of the adjoining surface of the cooled element, depends both on the temperature difference and on the value of the temperature on the hot side of the Peltier module.

When choosing a Peltier module of appropriate cooling power, it is necessary to ensure that the entire surfaces of its cold and hot sides are used. Otherwise, the parts of the module that do not have contact with the surface of the protected object (such as a processor chip) will only waste power and emit heat, decreasing overall cooling efficiency (Fig. 11.15).

Figure 11.15: Incorrect usage of a large Peltier module

If the surface of the cold side of the module exceeds the area of contact with the cooled object, it is necessary to use thermal padding of sufficient dimensions and thickness. This padding must be manufactured from material with good heat conductivity, such as copper (Fig. 11.16).

Figure 11.16: Correct usage of a large Peltier module with heat-conductive padding (Cu)

Unfortunately, problems with using Peltier modules are not limited to the previously mentioned aspects. The architecture of contemporary processors and certain system software permit modification of the energy consumed, depending on the workload of the processor. This allows you to optimize the amount of energy used. This is also the result of energy-saving standards supported by functions built into the hardware and software of modern computers. Under normal conditions, optimizing the operation and energy consumption of the processor positively affects the thermal conditions of the processor, as well as the general thermal balance. However, note that modes with periodic fluctuations in the amount of power consumed might not harmonize with cooling equipment that uses Peltier modules. This is because existing Peltier coolers are intended for constant operation. If the processor is changed to a mode in which the amount of power consumed, and, therefore, the heat flux has been lowered, the temperature of the processor chip and core also will be lowered considerably. In certain cases, if the processor core is too cool, the processor may experience a temporary cessation of operation, which will cause the computer system to hang up persistently. Corresponding documentation from Intel says the minimum temperature that guarantees proper functioning of Pentium II and Pentium III processors is 5°C (41°F).

As previously mentioned, low temperatures may result in water condensation. Water condenses on the cold parts of the cooling system, such as the cold side of the Peltier module and the cooled surface of the object being protected (such as the CPU). Furthermore, when heat-conductive padding is used, it also will also collect water. This effect can be neutralized by isolating the cold areas of the cooling system. One way to achieve this is to apply special foam rubber (Fig. 11.17).

Figure 11.17: Isolating cold areas of the cooling system by using foam rubber (Cu is the heat-conductive padding)

Certain problems may arise from the work of a series of built-in functions, such as those that control the fans in the cooler. In part, the mode that controls energy consumption of the processor provides for changes in the rotation speed of the cooling fan, using hardware built into the motherboard. Under normal conditions, this greatly improves the heating rate of the processor. However, if you are using one of the simpler Peltier coolers, lowering the rotation speed of the fan may worsen the heating rate, with fatal consequences for the processor, which will be overheated by the operating Peltier module. Remember that the Peltier module, besides performing the functions of a heat pump, is a powerful source of heat.

As in the case of central processors, Peltier coolers may be a good alternative to the traditional means of cooling video chipsets used in modern, high-performance video adapters. The work of such video chipsets is accompanied by significant heat flux and rarely is subject to sharp changes in its functional modes.

To avoid problems with modes that change power consumption, which can lead to condensation, overcooling, and possibly overheating of protected elements, you should not use such modes or built-in functions. However, as an alternative, you can use a cooling system that provides intelligent control of Peltier coolers. This will control not only the work of the fan, but also will change the work modes of the thermoelectric modules used in active coolers. In the simplest situation, this might be a miniature thermal relay based on a bimetallic plate, fastened on the Peltier module and controlling the operation of the fan cooling that module.

Information recently appeared on experiments that built miniature Peltier modules directly into the processor chips to cool their most critical structures. This solution favors better cooling that results from decreased heat resistance and allows considerable increases in the operating frequency and performance of the processor.

Many research laboratories conduct investigations to improve systems that ensure optimal temperature modes of electronic components. Cooling systems based on Peltier modules are considered rather promising.

Examples of Peltier Coolers

Recently, some simple, reliable, and relatively inexpensive ($5–$20) Peltier modules have appeared on computer market. (As a rule, the cooling fan is not supplied with the kit.) These modules show the prospects of cooling devices, and even now are used regularly to cool PC components.

A wide range of Peltier coolers is available, from miniature products with relatively low cooling power, which can operate with simple coolers that use small heatsinks, to powerful Peltier modules, which require a water cooling system for proper operation.

Numerous cooling devices are supplied by Supercool (http://www.supercool.se) (Fig. 11.18).

Figure 11.18: Thermoelectric modules from Supercool

For efficient operation of powerful thermoelectric modules, a water cooling system is required. Supercool supplies these components as well, including those shown in Figs. 11.19 and 11.20.

Figure 11.19: Components of a water cooling system

Figure 11.20: Element of a two-circuit water cooling system

Some manufacturers supply processor coolers based on Peltier modules. Examples of such products are listed in Table 11.4.

Table 11.4: Industrial Coolers Based on Peltier Modules

Product

Manufacturer/vendor

Fan description

Intel processor

PAX56B

ComputerNerd

Ball bearing

Pentium/MMX, to 200 MHz and 25 W

PA6EXB

ComputerNerd

Dual ball bearing, tachometer

Pentium MMX, to 40 W

DT-P54A

DesTech Solutions

Dual ball bearing

Pentium

AC-P2

AOC Cooler

Ball bearing

Pentium II

PAP2X3B

ComputerNerd

Triple ball bearing

Pentium II

STEP-UP-53X2

Step Thermo-dynamics

Dual ball bearing

Pentium II, Celeron

PAP2CX3B-10 BCool PC-Peltier

ComputerNerd

Triple ball bearing, tachometer

Pentium II, Celeron

PAP2CX3B-25 BCool-ER PC-Peltier

ComputerNerd

Triple ball bearing, tachometer

Pentium II, Celeron

PAP2CX3B-10S BCool-EST PC-Peltier

ComputerNerd

Triple ball bearing, tachometer

Pentium II, Celeron

The PAX56B cooler was developed to cool Intel Pentium and Pentium with MMX technology, Cyrix, and AMD processors that work at a frequency of 200 MHz. The 30 × 30 mm thermoelectric modules allow the cooler to support a processor temperature of less than 63°C (145°F), at a power dissipation of 25 W and an internal temperature of 25°C (77°F). Most processors dissipate less heat; therefore, this cooler supports a much lower processor temperature than many alternative cooling systems, consisting of just heatsinks and fans. The power supply of the Peltier module included in the PAX56B cooler is from a source of 5 W; it can support a maximum current of 1.5 A. This cooler's fan requires 12 V and a maximum current of 0.1 A. The parameters of the fan are as follows: ball bearing, 47.5 mm, 65,000 hours, and 26 dB. The dimensions of the entire cooler are 25 × 25 × 28.7 mm.

The PA6EXB cooler is intended to cool more powerful Pentium processors with MMX technology, which dissipate a power of 40 W. This cooler is compatible with all processors from Intel, Cyrix, and AMD that use Socket 5 or Socket 7. The thermoelectric Peltier modules included in PA6EXB are 40 × 40 mm. The maximum current is 8.0 A (but usually 3.0 A) at a voltage of 5 V when connected through the standard power socket of the computer. The dimensions of the entire cooler are 60 × 60 × 52.5 mm. To install the cooler correctly and ensure optimal heat exchange between the heatsink and its surroundings, make sure that there is space of at least 10 mm above it and 2.5 mm to the sides. PA6EXB guarantees a processor temperature of 62.7°C (144.9°F) at a dissipation power of 40 W and an internal temperature of 45°C (133°F). Taking into consideration the way the thermoelectric module inside PA6EXB works, you must avoid using programs that place the processor in hibernation mode for long periods of time; this will prevent condensation and possibly short-circuiting.

The DT-P54A cooler (also known as the PA5B from ComputerNerd) was developed for Pentium processors. However, some companies that sell the cooler also recommend it to users of Cyrix/IBM or AMD processors. The cooler heatsink is relatively small, 29 × 29 mm. A thermal sensor built into the cooler will inform you when there is danger of overheating. It also monitors the Peltier module. An external controlling device also is included. This device tracks the voltage, the operation of the Peltier element and the fan, and the temperature of the processor. The device will give a warning signal if the Peltier element or the fan breaks, if the fan rotates at less than 70% of its normal speed (4,500 rpm), or if the temperature of the processor has climbs higher than 63°C (145°F). When the processor temperature surpasses 38°C (100°F), the Peltier element automatically turns on. If the temperature is below this, the Peltier element is kept off. This last function eliminates problems connected with moisture condensation. Unfortunately, the Peltier element is so securely attached to the heatsink that you won't be able to remove it without destroying the construction. This means that you don't have the ability to install it on another, more powerful heatsink. The fan parameters are as follows: The voltage is 12 V, the rotating speed is 4,500 rpm, the air supply speed is 6 cfm, the power consumed is 1 W, and the noise level is 30 dB. This cooler performs fairly well and is useful for overclocking. In certain cases, however, overclocking the processor simply requires a bigger heatsink and a good fan.

The AC-P2 cooler was developed for Pentium II processors. Included are a 60 mm fan, a heatsink, and a 40 mm Peltier element. It does not work well with Pentium II processors of 400 MHz and higher, because the SRAM chips are not cooled.

The PAP2X3B cooler (Fig. 11.21) is similar to the AC-P2. It comes with two 60 mm fans. The problem of cooling the SRAM is not dealt with. Keep in mind that the cooler is not recommended for use with cooling programs such as CpuIdle, or with the Windows NT or Linux operating systems, because moisture condensation on the processor is more likely to occur.

Figure 11.21: External view of the PAP2X3B cooler

The STEP-UP-53X2 cooler has two fans that blow through the heatsink.

The BCool series from ComputerNerd (PAP2CX3B-10 BCool PC-Peltier, PAP2CX3B-25 BCool-ER PC-Peltier, and PAP2CX3B-10S BCool-EST PC-Peltier) were developed for Pentium II and Celeron processors. All have similar characteristics, which are presented in Table 11.5.

Table 11.5: Coolers of the BCool Series

Parameter

PAP2CX3B-10 BCool PC-Peltier

PAP2CX3B-25 BCool-ER PC-Peltier

PAP2CX3B-10S BCool-EST PC-Peltier

Recommended processors

Pentium II, Celeron

Pentium II, Celeron

Pentium II, Celeron

Number of fans

3

3

3

Type of central fan

Ball bearing, tachometer (12 V, 120 mA)

Ball bearing, tachometer (12 V, 120 mA)

Ball bearing, tachometer (12 V, 120 mA)

Dimensions of central fan (mm)

60 × 60 × 10

60 × 60 × 10

60 × 60 × 10

Type of external fan

Ball bearing

Ball bearing, tachometer

Ball bearing, thermistor

Dimensions of external fan (mm)

60 × 60 × 10

60 × 60 × 25

60 × 60 × 25

Voltage (V), current (mA)

12, 90

12, 130

12, 80–225

Total area covered by fans (cm2)

84.9

84.9

84.9

Power (W), total current for fans (mA)

300, 3.6

380, 4.56

280–570, 3.36–6.84

Heatsink pins at center

63 long, 72 short

63 long, 72 short

63 long, 72 short

Heatsink pins on each side

45 long, 18 short

45 long, 18 short

45 long, 18 short

Total number of heatsink pins

153 long, 108 short

153 long, 108 short

153 long, 108 short

Heatsink size at center, with thermoelectric module (mm)

57 × 59 × 27

57 × 59 × 27

57 × 59 × 27

Heatsink size on each edge (mm)

41 × 59 × 32

41 × 59 × 32

41 × 59 × 32

Total heatsink size, with thermoelectric module (mm)

145 × 59 × 38

145 × 59 × 38

145 × 59 × 38

Total cooler size (mm)

145 × 60 × 50

145 × 60 × 65

145 × 60 × 65

Cooler weight (g)

357

416

422

Warranty (years)

5

5

5

Estimated price (2000)

$74.95

$79.95

$84.95

Note that BCool coolers include devices that have similar characteristics but do not include Peltier elements. Such coolers are cheaper, but they cool computer components less effectively.

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