The invention relates to a climate control method.
DE 43 31 142 C2 discloses a method by means of which the internal area temperature is always regulated to the nominal internal area temperature setting irrespective of the respectively prevailing temperature of the external area from which, for example, the internal area medium is taken in the case of a motor vehicle air-conditioning system, by appropriate adjustment of the temperature of the flowing-in medium. If required, the medium is cooled-down [and/]or heated for this purpose before it flows into the vehicle.
In the case of vehicles with temperature and/or fan control, it is likewise known for the blowing-in temperature of the air-conditioning system to be calculated as a function of the outside temperature, the internal area temperature and a nominal internal area temperature setting.
However, the problem with climate control methods such as these is that, when the outside temperatures are very high, for example between 35° C. and 55° C. and/or there is additional solar radiation, a very low nominal blowing air temperature, for example −30° C. to −60° C., is calculated. For physical reasons, specifically icing up of the vaporizer, the lowest blowing-in temperature is, however, about 3° C. to 5° C. If an occupant wishes to be warmer, and changes the nominal value from 22° C. to, for example, 24° C., the calculation of the nominal blowing-air temperature is increased only to about −10° C. to −20° C. Since, however, the blowing-out temperature is physically limited to 3° C. to 5° C., and a blowing air nominal temperature of down to −60° C. is calculated, the nominal value change is not detectable for the occupant. The nominal value must be set even higher depending on the values of the control parameters, that is to say the outside temperature, the nominal value, the influence of the sun (the solar radiation) and the internal area temperature until a positive blowing air temperature is calculated by the climate control calculation.
One object of the present invention is to develop a climate control method such that the climate control responds immediately to a change in a nominal value even when the outside temperatures are very high and/or the solar radiation is strong.
According to the invention, this object is achieved by a climate control method.
The control system according to the invention makes it possible to achieve a detectable reaction to a manual action. In other words, the nominal internal area temperature is increased even though a nominal blowing-in temperature calculated for this nominal internal area temperature, in the same way as a previous nominal blowing-in temperature for a lower nominal internal area temperature, is not feasible owing to the physical limits and, Conventionally, the lower limit value of the blowing-in temperature was used as standard in both cases.
In particular, the method according to the invention can also and in particular be used for multiple zone air-conditioning systems since more comfort for the individual seat positions can now be achieved in this case, since it is possible to adapt the blowing-in temperature separately for each area.
These and further objects, features and advantages of the present invention will become clear from the following description of one preferred exemplary embodiment, in conjunction with the drawing, in which:
Conventional climate control methods are subject to the problem that the blowing-in temperature Tblowing-in-min cannot be below 1° C. to 3° C. owing to the physical limit of the vaporizer icing up, even though a calculated nominal blowing-in temperature would be considerably lower. Because of this, it is impossible, if the outside temperatures are high and/or the solar radiation is severe; to provide a nominal blowing-in temperature Tblowing-in-nom which is calculated as a function of the outside temperature TA, the actual internal area temperature TI and a nominal internal area temperature setting TInom. In a situation such as this, even in the event of a readjustment by increasing the nominal internal area temperature, it is possible for the nominal blowing-in temperature Tblowing-in-nom calculated using the new nominal internal area temperature TInom-new still to be well below the achievable value, as well. The occupant therefore cannot detect any control change, so that he requires several manual readjustment processes until he is provided with a blowing-in temperature Tblowing-in which is comfortable for him. This is where the air-conditioning method according to the invention comes into play, in order to provide a modified form of climate control in this case, with which this problem no longer occurs.
The climate control method according to the invention will now be described in the following text with reference to
In the climate control method according to the invention, the conventional method is first of all used in a first step S1 to calculate the nominal blowing-in temperature Tblowing-in-nom as a function of the outside temperature TA, the actual internal area temperature TI and the nominal internal area temperature TI nom. Then, in a step S2, the calculation result, that is to say the nominal blowing-in temperature Tblowing-in-nom is compared with the minimum physically achievable blowing-in temperature Tblowing-in-min. If it is found in the step S2 that the calculated nominal blowing-in temperature Tblowing-in-nom is higher than the minimum blowing-in temperature Tblowing-in-min, conventional climate control is carried out in step S3, as a function of the actual internal area temperature TI, the nominal internal area temperature TInom, the outside temperature TA and, if appropriate, the solar radiation q, and the speed v, etc. If, in contrast, the calculated nominal blowing-in temperature Tblowing-in-nom in step S2 is below the minimum blowing-in temperature Tblowing-in-min, a check is carried out in step S4 to determine whether there is a new nominal internal area value TInom-new. If there is no such value, an internal area temperature normal value, for example of 22° C., is used instead of this, and the process returns to step S1.
If there is a new nominal internal area value TInom-new, a nominal internal area temperature change ΔtInom is then calculated in step S5 from the difference between TInom-new and TInom-old. A check is then carried out in step S6 to determine whether the nominal internal area temperature change ΔTInom is greater than zero, that is to say whether the manual action should result in a temperature increase. If there is no temperature increase, that is to say the nominal internal temperature change ΔTInom is present, the process returns to step S1, otherwise it progresses to step S7. In step S7, a second nominal blowing-in temperature Tblowing-in-nom2 is now calculated as a function of the nominal internal area temperature change ΔTInom and the outside temperature TA. The calculation is carried out with reference to empirical values determined by measurements for optimum control. A maximum of the nominal blowing-in temperature Tblowing-in-nom and the second nominal blowing-in temperature is then determined is step S8. A check is then carried out in step S9 to determine whether the second nominal blowing-in temperature Tblowing-in-nom2 has been chosen as a maximum. If this is the case, the outlet valve, in the case of several zones, the outlet valve in the respective zone, is closed in step S10. Otherwise the process returns directly to step S1.
In one preferred development of the invention, the climate control method according to the invention is used for multiple zone air-conditioning systems in such a way that the climate control process described above with reference to
Number | Date | Country | Kind |
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10256409.4 | Dec 2002 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP03/12196 | 11/3/2003 | WO | 11/14/2005 |