WO1996018140A1

WO1996018140A1 - Temperature monitoring device for microprocessors

Info

Publication number: WO1996018140A1
Application number: PCT/EP1995/004758
Authority: WO
Inventors: Jens Stemmler
Original assignee: Jens Stemmler
Priority date: 1994-12-04
Filing date: 1995-12-04
Publication date: 1996-06-13
Also published as: DE9419293U1

Abstract

The aim of the invention is to enhance the operational reliability of a temperature monitoring device for microprocessors (5) in a personal computer (PC) which is provided in its housing (2) (provided with a front screen (3)) with at least one cooling device (6), in particular a ventilation fan, said cooling device being controlled by a temperature sensor (7). To do this, it is proposed that the temperature monitoring device (1) should take the form of a slot-in module (8) mounted on the front panel (3) of the PC housing (2) and provided with a temperature display (9) actuated by the temperature sensor (7).

Description

Description Temperature monitoring device for microprocessors

The invention relates to a temperature monitoring device for microprocessors according to the preamble features of patent claim 1.

The cooling of microprocessors (CPU) is generally carried out by means of metal heat sinks which are placed on the integrated circuits or semiconductors in order to ensure appropriate heat dissipation. Recently, however, progress in semiconductor technology has significantly increased the integration densities of such integrated circuits, so that considerably more electronic components have been able to be integrated with the same base area of the semiconductor. Although the power consumption was reduced at the same time, for example by the transition from the 5 V to the 3.3 V construction, the power consumption also increased because the clock frequency was continuously increased. This also applies in particular to co-processors in personal computers, so that the heat sinks alone are no longer sufficient to dissipate the heat generated.

In the case of more powerful microprocessors, it has therefore become customary to support the heat dissipation of the heat sink by means of a fan which is placed on the heat sink in the form of a small cooling fan and thus increases the air circulation. This small-sized ventilation blower acts as an axial fan, which is controlled by a temperature sensor which is arranged on the area of the microprocessor which is subjected to the greatest stress. However, for safety reasons, such a fan is often operated for an excessively long time, which in turn leads to increased power consumption. The user of the PC has no means of action to design the CPU fan according to his particular requirements. In particular, the user of the PC has none Control options to monitor the correct functioning of the CPU fan.

This also applies to the control system for the power supply to a computer CPU described in DE-U-94 10 314. Here, a fan wheel is also used on a heat sink, the operation of which is controlled by a heat sensor that detects the temperature of the heat sink, as is the case, for. B. is also described in IBM Technical Disclosure Bulletin, Vol. 36, Aug. 1993, pp. 489-491. If the permissible temperature is exceeded, e.g. B. in the event of failure of the fan wheel, however, the operating voltage of the control system is interrupted, ie the power supply to the microprocessor is completely switched off. This shutdown of the system can also be done by one

Remote control switch off, so that the computer is no longer in operation. This shutdown condition is then indicated by a lamp on the front panel or keyboard of the computer. Due to this automatic switch-off, the PC user no longer has any influence on reacting in the event of signs of overheating in order to avoid data loss or to place his computer programs on it.

Accordingly, the object of the invention is to create a temperature monitoring device with which monitoring of the correct functioning of the cooling device of the microprocessor is possible, in particular a timely warning if the cooling device fails.

This problem is solved by a

Temperature monitoring device according to the features of claim 1.

By arranging a temperature display in the form of a plug-in module arranged on the front panel of the PC housing, the temperature state of the microprocessor is visible to the user at all times and can thus be monitored. If, in the case of particularly extensive calculation processes such as a spreadsheet or a graphic representation, the Microprocessor is highly loaded, is for the user to approach a critical temperature value of z. B. 70 * C can be seen. Likewise, the correct functioning of the microprocessor or CPU fan can be seen by the user if, after the temperature has initially increased, the temperature then drops or at least remains constant as a result of the cooling device being switched on. However, if the temperature should rise further, the user could possibly interrupt the computing operation in order to avoid destruction of the valuable microprocessor.

In a preferred embodiment, however, in addition to the numerical temperature display, a graduated temperature display device can be provided, for example in the form of a plurality of light-emitting diodes, a green light-emitting diode being able to be selected for normal operation, while a red signal color or an increasing luminous or color intensity is selected for the critical temperature range can be. This warning function can optionally be supported by an acoustic alarm tone, so that overheating of the microprocessor can practically no longer occur.

In addition, other additional measures such as switching on the main fan blower are also possible in order to avoid overheating of the microprocessor and other components. Such a fan blower is generally provided in any case in the PC housing for cooling the plug-in boards and the PC power supply.

In addition, the direct temperature display also allows a certain assessment of the software used, so that the user can infer from the temperature state of the microprocessor displayed to him that the microprocessor is under load when executing computer programs. The service life of the electronic components, in particular of the microprocessor, can thus be increased by selecting the software in a targeted manner or avoiding software that is particularly stressful to the temperature. It can also the temperature display can be used for demonstration purposes of temperature conditions in schools and technical training.

Of particular advantage is the simple assembly of the temperature monitoring device in the form of a plug-in module, preferably as a plug-in module which can be plugged into the drive shaft of the PC housing, which is already present. These slots in the drive bay are generally provided and standardized for the installation of floppy drives or CD-ROM drives, so that the plug-in module can be installed in a simple manner by occupying such a space in the drive bay.

Further advantageous refinements are the subject of the dependent claims.

An exemplary embodiment is explained and described in more detail below with reference to the drawing. In the (only) Fig. 1 of the drawing, an exploded perspective view of a personal computer (PC) is shown with a built-in, schematically drawn temperature monitoring device 1, which is arranged in a conventional PC housing 2 with an associated front panel 3. A main circuit board 4 is arranged in the PC housing 2, the further associated components such as the power supply unit, drives and the like not being shown in more detail for reasons of clarity. A microprocessor 5 (generally also called a CPU) is arranged on the main circuit board 4, above which a cooling device 6 is provided in the form of a heat sink known per se with an integrated miniature fan. However, a tube structure through which fluid flows (so-called cooling box) could also be provided as the cooling device 6 in order to dissipate the heat generated at the microprocessor 5. A temperature sensor 7 is provided in the area of the microprocessor 5 and is connected to a plug-in module 8 by means of a sensor input 7a. This plug-in module 8 points towards the PC user Front a temperature display 9, which is arranged flush with the front panel 3, preferably in a slot of a drive bay 10. The temperature display 9 is preferably designed as an LCD display 9a and is controlled by electronic components (not shown in more detail) on the plug-in module 8 designed as a plug-in card. This circuit located on the plug-in card is connected on the input side to the sensor input 7a and on the output side to a switching output 8a for the cooling device 6, in particular the miniature blower above the microprocessor 5.

In addition or as an alternative to the LCD display 9a, light-emitting diodes 11, 12, 13 can also be provided as the temperature display 9, which are preferably embodied in the signal colors green for normal operation, orange for increased temperature and red for alarm temperature. These light-emitting diodes 11, 12, 13 are also controlled by the sensor 7 via the monitoring circuit (not shown in greater detail) on the circuit board of the plug-in module 8 via the sensor input 7a and thus result in an exact

Temperature monitoring of the microprocessor 5. The light-emitting diodes 11, 12, 13 can also be provided in greater numbers in the horizontal or vertical direction in order to indicate to the user a corresponding increase in temperature in stages.

Furthermore, a second sensor 17 is connected to the plug-in module 8 via the sensor input 7a, which monitors the temperature in the area of plug-in boards 14 in a manner similar to the sensor 7, since temperature-sensitive microprocessors are also used in graphics cards and similar expansion cards for the PC. These plug-in boards 14 are cooled by a larger ventilation fan 16 which, like the cooling device 6, is also connected to the switching output 8a of the plug-in module 8. A switch 15 can be provided on the front panel 3 adjacent to the light-emitting diode 13, by means of which the temperature detected by the second sensor 17 in the region of the plug-in boards 14 can be displayed on the LCD display 9a. However, it can be between the two Sensors 7 and 17 may also be provided a priority circuit, which indicates the respective higher temperature on the microprocessor 5 or on one of the plug-in boards 14.

On the plug-in module 8, a threshold value circuit is also provided for the temperature parameters, in which a certain temperature limit of z. B. 70 ° C is entered. If this temperature limit is exceeded, z. B. the red LED 13 actuated as an alarm signal. To increase the alarm effect, an acoustic warning tone can also be emitted by a loudspeaker 20 integrated here in the front panel 3. However, this loudspeaker 20 can also be integrated as a separate component in the plug-in module 8. In a preferred embodiment, the plug-in module 8 is designed as a 5.25 ″ plug-in module for the drive shaft 10 and is connected to the PC power supply unit by means of a connection 19. The above-mentioned threshold circuit for determining a temperature limit can be permanently programmed by the manufacturer for the common microprocessors or can be changed within certain limits by the user. For example, if the limit temperatures for the individual light-emitting diodes 11, 12 and 13 are determined in stages, a normal temperature of 40 ° C., a prewarning temperature of 60 ° C. and an alarm temperature of 80 ° C. could be entered. A monitoring circuit for the Functionality of the cooling device 6 is provided, in which, for example, the circuit for the miniature fan on the microprocessor 5 can be periodically switched on or queried, and thus its functionality is monitored.

In contrast to the abrupt switch-off of the power supply in the control system mentioned at the outset, in the temperature monitoring device proposed here, the PC user can display the respective temperature load by displaying the current temperature value to the exact degree with a Sampling rate of approx. Detect 1 second and influence computer operation accordingly to avoid data loss.

Claims

claims

1. Temperature monitoring device for microprocessors (5) of a personal computer, which in its housing (2) with a front panel (3) has at least one cooling device (6), in particular a ventilation fan, the cooling device being controlled by a temperature sensor (7) that the temperature monitoring device (1) is designed as a plug-in module (8) arranged on the front panel (3) of the PC housing (2) with a temperature display (9) controlled by the temperature sensor (7).

2. Temperature monitoring device according to claim 1, characterized in that the plug-in module (8) is designed as a plug-in module from the front panel (3) in a drive shaft (10) of the PC housing (2).

3. Temperature monitoring device according to claim 2, characterized in that the plug-in module (8) is designed as a 5.25 '' plug-in module.

4. Temperature monitoring device according to one of claims 1 to 3, characterized in that the temperature display (9) as an alphanumeric LCD display

(9a) is formed.

5. Temperature monitoring device according to one of claims 1 to 4, characterized in that the temperature display (9) has a plurality of light-emitting diodes (11, 12, 13 ...) which are activated in stages at different temperature limit values.

6. Temperature monitoring device according to claim 5, characterized in that the light-emitting diodes (11, 12, 13 ...) have different signal colors and / or color intensities.

7. Temperature monitoring device according to one of claims 1 to 6, characterized in that when a predetermined temperature limit is exceeded, an acoustic alarm device (20) from the plug-in module (8) is controlled.

8. Temperature monitoring device according to one of claims 1 to 7, characterized in that a second ventilation fan (16) for cooling plug-in boards (14) is provided within the PC housing (2), a second sensor (17) in the area of Plug-in boards (14) is arranged and connected to the plug-in module (8).

9. Temperature monitoring device according to claim 8, characterized in that the second ventilation fan (16) together with the cooling device (6) can be switched on.

10. Temperature monitoring device according to one of claims 1 to 9, characterized in that the temperature limit for activating the cooling device

(6) on the plug-in module (8) is adjustable.

11. Temperature monitoring device according to one of claims 1 to 10, characterized in that an optical and / or acoustic warning display for automatic signal delivery in the case of a defective cooling device (6) and / or a defective fan blower (16) is provided.