DE3919407A1 - METHOD FOR CONTROLLING A COMPRESSOR AND CONTROL DEVICE - Google Patents

Abstract

When a compressor has raised the pressure of a fluid, it can be switched to either "idle" or "off". "Off" uses less power than "idle", but repeated switching "off" and "on" can cause the compressor motor 17 to overheat. The control 14, 15 therefore senses pressure 11 and temperature 10, and decides whether to switch the compressor to "off" or "idle" on the basis of the temperature of the motor (either present or predicted at the time when it will need next to be switched "on") so that "off" is selected if the motor will not overheat when next switched "on" and "idle" is selected otherwise. A cooling fan 18 may be provided to accelerate cooling of the motor 17. <IMAGE>

Description

The invention relates to a method for controlling a Compressor, in the case of changing compressed air requirements the drive motor after reaching the maximum pressure in the Compressed air network switched off (intermittent operation) or the Compressor in idle (continuous operation) is switched, and also a Compressor control device.

When a compressor delivers more than it does at the moment is consumed, the network pressure rises to Maximum point. The compressor will then open Intermittent operation switched until after the Network pressure to a minimum value a restart of the Compressor is required.

Because the switching frequency of electric motors is limited is due to an increase in engine temperature to avoid frequent engagements Compressor in idle mode (continuous operation) switched, in which he continues to run relieved, none Air conveys, but at least about 1/4 of the Takes full load power.

Compressor operation in the event of load fluctuations to make it more economical is used Controls that, depending on the expected Pressure drop and from that of the engine manufacturer predetermined switching frequency of the drive motor, decide between intermittent and continuous operation.

It is also known for one compressor each cheapest operating mode, i.e. Intermittent or Continuous operation, depending on the respective  Air consumption during the as funding period designated intermittent operating state Control devices to choose automatically. Doing so the duration of a funding period with a time relay scanned. If the maximum pressure within the the set time is reached, the compressor switches from. Is the maximum pressure only after the expiry of Timing relay reached, this corresponds to one relatively high air consumption, so that The compressor is then switched to continuous operation. The intake throttle valve is closed and the System relieved of pressure.

The choice between the two operating modes is as before mentioned, from the permissible switching frequency of the Depending on the drive motor, for example at 4 to 6 Circuits per hour.

The controls according to the prior art have the Disadvantage that the actual current Engine temperatures are not recorded and evaluated, so that the compressor inevitably more often Idle running as due to the actual Conditions would actually be necessary. In particular for machines with high performance this means of State of the art compressor controls prescribed frequent idle operation after all considerable energy costs.

The object of the invention is therefore to provide a method for Control a compressor and a corresponding one To create control device that allow regardless of the one approved by the engine manufacturer Engine switching frequency the current Compressor drive motor temperature as a criterion for the Choice between intermittent and continuous operation of the To determine the compressor.  

The solution to this problem is through a Control process achieved and a Control device as in the claims are laid down.

Accordingly, there is the essential feature of the invention in that actually in the compressor drive motor prevailing temperature, from which the conclusion is pulled whether the compressor at low Compressed air requirement can be switched off without danger to run that at a short term Switch on again due to increased compressed air demand the permissible motor temperature is exceeded.

The inventive method according to the independent claims 1 to 3 enables one optimal adjustment of the compressor operation to the Compressed air consumption, a reduction in Use of the installed capacity at reduced air flow, a reduction in Coolant costs and safe overload protection for the electric drive motor in that due to the use of the criterion Motor temperature in the method according to the invention permissible specified by the motor manufacturer Switch-on frequency even with very fluctuating Compressed air consumption never exceeded and that Idle times of the compressor can be minimized.

When measuring the engine temperature is preferred an indirect current measurement method applied, for example using an electronic Motor protection relay. The principle lies with this method based on the fact that the heating from an engine in the Motor follows as loss of converted energy. It is  the heating depends on the copper and iron masses, copper and iron losses, various Thermal capacities and thermal resistances, of the Cooling conditions in different operating modes and from the fed currents.

Since the design-related in a motor of known design Sizes are known, can be by calculation or experiment the heating of the motor as a function of the current be derived. The current measurement is simple Funding possible in the supply line. For the typical engine Corresponding measuring devices are known for evaluation.

The indirect current measurement method is currently the available devices are technically easy to display. in the In the course of the further development of the relevant measuring technology but also the application of the direct measurement method, which has already been tried out as a trial reliable alternative can be realized.

Since in the control method of the measurement of the current drive motor internal temperature in this context it can be assumed also be advantageous, the engine cooling from To make compressor motor drive independent and For example, engine cooling only when needed switch on. This results in a performance saving. On the other hand, one can proceed in such a way that the Engine cooling after switching off the compressor drive continues for a while to get the temperature level lower and in this way additional To enable switching on the compressor drive. Since the idle operation of the compressor is approx. Requires 25% of full load power during the Cooling air fan alone, however, only a few percent of the compressor output is this Procedure energetically advantageous.  

If this separation with a known one Compressor control procedure possible in principle the effect would not have been used can be because in the known method as Switch-off criterion for the compressor only given size "allowable Drive motor switching frequency "is used.

The control method according to the invention and the Control device are based on the Drawings explained in more detail.

Show it:

Fig. 1 shows a temperature-time graph of the claims 1 and 2,

Fig. 2 is a pressure-time diagram to claim 3,

Fig. 3 shows a temperature-time diagram to claim 3,

Fig. 4 is a block diagram of the control device.

The diagram in FIG. 1 relates to claims 1 and 2. The drive motor temperature is plotted on the ordinate and the time T on the abscissa.

Starting from the steady-state temperature t _N during load operation, P _{max is} reached at ( 1 ) in the compressed air network. If one starts from the current temperature value t _{u 1} , the motor temperature would increase by the amount t _h if the compressor drive were restarted for a short time, but t _max has not yet been reached. The drive motor can therefore be switched off.

( 2 ) shows the state in which P _{max is} reached in the network, but the motor temperature would increase by an amount t _h from the increased value t _{u 2} due to previous motor start-ups and would thus exceed the maximum permissible motor temperature t _max .

In this case, the compressor drive is not switched off, but continues to run at idle until t _u + t _{h is} less than t _max .

In FIG. 2, the supply pressure is plotted on the ordinate and on the abscissa the time. This figure and FIG. 3 illustrate the control method according to claim 3.

At ( 3 ) the maximum network pressure P _{max is} reached and the subsequent pressure drop trend from ( 3 ) to ( 4 ) is used to calculate the time T _min ( 5 ) and thus the lower switching point P _min .

In Fig. 3, the engine temperature is plotted on the ordinate and the time on the abscissa.

The temperature t _u ( 8 ) at time T _{min is} calculated from the temperature level of ( 8 ) and ( 7 ) and the temperature drop tendency. From ( 9 ), t _u + t _h ( t _h = temperature rise during motor start-up) less than t _{max it} follows that the drive motor can be switched off because the maximum temperature is not reached.

However, if t _u + t _{h were} greater than t _max , the compressor would continue to run in idle mode (continuous operation).

Fig. 4 shows with reference to a block diagram in simplified form the structure of the control device according to claims 6 and 7.

For the simplest case of control (claim 6), the two middle blocks of the upper row ( 10 , 11 ) symbolize the devices for the constant detection of the motor temperature ( 10 ) and the network pressure ( 11 ). The signals emanating from these devices are fed into the microprocessor ( 14 ), into which the limit values of temperature and pressure to be observed and the decision logic (computer program) are entered by an input terminal ( 13 ), ie for example a programming device.

The microprocessor ( 14 ) processes the measured values of ( 10 ) and ( 11 ) according to the specifications of the input terminal ( 13 ) and gives the resulting commands to the compressor controller ( 15 ). The compressor control switches the load / idle control ( 16 ), the compressor drive motor ( 17 ) and / or the cooling air fan motor ( 18 ) via switching devices (not shown).

In the more complex control device (claim 7), in addition to the signals of the engine temperature ( 10 ) and the network pressure ( 11 ), signals ( 12 ) about the operating state of the compressor, in particular about idling or standstill of the compressor system, are fed into the microprocessor ( 14 ). The relevant program is entered via the input terminal ( 13 ). The microprocessor observes the relationships between the compressor operating states and the drive motor temperature profiles, in particular the time behavior of the motor temperature increase. The microprocessor ( 14 ) stores this compressor behavior, which runs under target conditions, as a reference value and derives the corresponding decisions for the compressor control ( 15 ), namely decisions for switching to load, idling, standstill and / or cooling air fan drive.

Claims (7)

1. A method for controlling a compressor in which, when the compressed air requirement changes, the drive motor is switched off after the maximum pressure p _{max has been reached} in the compressed air network (intermittent operation) or the compressor is switched to idling (continuous operation), characterized in that the pressure in the compressed air network and the temperature of the drive motor, preferably by indirect measuring method, in particular in the temperature-critical motor part, measured and subjected to an evaluation and that when the maximum network pressure p _{max is reached,} the compressor drive motor is switched off if the evaluation shows that the temperature increase t occurring when the compressor drive motor is switched off or on again briefly _h + t _u less than t _max . 2. A method for controlling a compressor in which the drive motor is switched off (intermittent operation) or the compressor is switched to idling (continuous operation) after the maximum pressure p _{max has been} reached when the compressed air requirement changes, characterized in that the pressure in the compressed air network and the temperature of the drive motor, preferably by indirect measurement method, in particular in the temperature-critical motor part, are measured and subjected to an evaluation and that when the maximum network pressure p _{max is reached,} the compressor is switched to idle, if the evaluation shows that the compressor drive motor is switched off or on again for a short time temperature increase t _h + t _u greater than t _{max occurs} and that the compressor drive motor is only switched off when the temperature of the motor has dropped to such an extent that, after a brief restart, the maximum permissible motor temperature t _{max is} not reached becomes. 3. A method for controlling a compressor in which, when the compressed air requirement changes, the drive motor is switched off after the maximum pressure p _{max has been reached} in the compressed air network (intermittent operation) or the compressor is switched to idling (continuous operation), characterized in that the pressure in the compressed air network and the temperature of the drive motor, preferably by indirect measurement method, in particular in the temperature-critical motor part, measured and subjected to an evaluation and that when the maximum network pressure is reached, the compressor is first switched to idle, at the same time the tendency of the pressure drop is recorded and from this the time T _min at which lower pressure switching point p _{min is} reached, it is calculated that the tendency of the engine temperature drop is also detected at the same time and the engine temperature t _u to be expected at the time T _{min is} calculated and from the results of the evaluation the decision regarding continuous operation ( t _h + t _u greater than t _max ) or intermittent operation ( t _h + t _u less than t _max ) is derived. 4. Method of controlling a compressor according to the Claims 1 to 3, characterized, that the cooling of the compressor drive motor after Switch off the drive motor for as long as Operation remains until the temperature of the Drive motor to a value to be determined has sunk. 5. Method of controlling a compressor according to the Claims 1 to 3, characterized, that the cooling of the compressor drive motor independent of the operation of the drive motor, however depending on the measured engine temperature or is switched off. 6. Compressor control device for performing the method according to claims 1 to 6, characterized in that devices ( 10 , 11 ) are provided for detecting the compressor drive motor temperature and the network pressure, the signals for processing in a microprocessor ( 14 ) taking into account that of an input terminal ( 13 ) programmed limit values and decision logics are fed in, the microprocessor ( 14 ) giving the processed values as commands to the compressor controller ( 15 ), which switches the load / idle control ( 16 ), the compressor drive motor ( 17 ) and, if appropriate, the fan motor ( 18 ) switches. 7. Compressor control device according to claim 6, characterized in that the microprocessor ( 14 ) at the same time via the input terminal ( 13 ) additional information ( 12 ) regarding the operating state of the compressor, in particular about load / idle or standstill, the microprocessor ( 14th ) saves the relationships between the operating states and the temperature behavior of the motor temperature increase under target conditions as a reference value and issues corresponding commands for switching ( 16 , 17 , 18 ) via the compressor control ( 15 ).