EP2290240A2 - Pump with power supply regulator - Google Patents

Abstract

The pump (1) has a direct-current motor (6), and a power supply unit connected to a supply of the motor. The power supply unit rectifies and/or converts received alternative current voltage or direct current voltage. The power supply unit includes a closed control loop for controlling a controlled variable of the pump, and the motor includes a mechanical commutator. The controlled variable of the pump is variably selected from a group consisting of rotary speed of the motor, current drawn by the motor and pump feed power. An independent claim is also included for a method for pumping liquid.

Description

The invention relates to a pump for conveying liquids, in particular water, with a DC motor and a power supply for rectification and / or conversion of the AC voltage or DC voltage applied to the power supply.

In addition to the use of pumps which have an AC motor, especially for smaller pumps, which must have only a low flow rate, often DC motors in use.

In this case, the pumps with DC motor used in the prior art, an external power supply, which rectifies the AC voltage applied to the power supply and depending on the dimensions of the power supply voltage down-transforms, so down converts. In this case, however, the output voltage of the power supply is constant, so that a possible change in speed of the pump motor, for example, caused by a change in the viscosity of the liquid to be pumped or by the wear of the pump or other load-dependent factors, can not or only complicated and cumbersome.

The invention has for its object to provide a pump with DC motor, which avoids the above disadvantages and it allows in a simple manner to keep the speed of the pump motor or the flow rate of the pump substantially constant even with any load changes or this according to a predetermined profile to let go.

This is achieved in the pump according to the invention characterized in that the power supply has a closed loop for controlling a controlled variable of the pump.

By this regulation, it is possible to bring the controlled variable to a predetermined value by a reference variable, the reference variable is given in this case, for example, by the flow rate of the pump, and to keep the controlled variable even with disturbing influences on this value. It is also possible to form the control such that the controlled variable follows a predetermined course. In the closed loop, the variation of control values results in changes of the controlled variables, how they are caused by the so-called disturbance variables, reacts and controls the controlled variable in such a way that the corresponding desired course of the controlled variable is achieved. In contrast, there is no such feedback by taking into account the actual value of the controlled variable in a simple control of the pump without control. The reference variable itself can be generated by an external device or directly, for example, be set on the pump.

Such pumps with power supply and closed loop can be used particularly preferably in the metering, with the closed loop the controlled variable can be kept at a predetermined by the reference variable, so for example by the delivery rate. Specific applications for pumps according to the invention arise, for example, in the household where washing machines but also kitchen appliances such as dishwashers, hood machines or tape machines can be provided with such pumps. Also in sanitary technology such as swimming pools or saunas and water treatment plants pumps according to the invention can be used beneficially.

In this case, the electronic components for rectification and conversion of the voltage applied to the power supply AC voltage, i. for the transformation of the voltage applied to the power supply AC voltage to a lower value per se in the prior art already known, for example in the form of a switching power supply, which is also known as SMPS (Switching Mode Power Supply). Instead of down-converting the AC voltage applied to the power supply, it may also be contemplated, in conjunction with high voltage DC motors, to provide the power supply with electronic components capable of up-converting the AC voltage applied to the power supply, i. transform the AC voltage applied to the power supply to a higher value. A combination of down and up converters can also be used. Such converters are already known in the art, for example in the form of the so-called book boost converters.

Especially in the case that the pump according to the invention is not operated on the public power grid but on an external power source or voltage source, it can also be provided that the power supply no rectification of Performs AC voltage, but only the downward and / or upward conversion of the voltage applied to the power supply DC voltage performs.

In a closed loop provides a command variable, a target value of a variable to be controlled, the so-called controlled variable. The controlled variable should then follow the given course of the reference variable. In most cases, however, the reference variable is only a simple (constant) value at which the controlled variable should also be kept under the influence of disturbing factors.

Further advantageous embodiments of the invention are defined in the dependent claims and will be explained in more detail below.

In addition to the known for a long time DC motors with mechanical current reversers, which are also known as collectors or commutators and in which brushes made of carbon or graphite on the circumference of the commutator can slide to the supply of electricity, are brushless DC motors (Brushless DC motors) lately known. A disadvantage has been found in these motors that the commutation is electronic and therefore the speed of such a brushless motor similar to the speed of an AC motor is adjustable over the frequency, where for this purpose a frequency converter must be used. However, such a scheme is much more complex than that for a DC motor with mechanical commutator, where the speed of the motor is directly proportional to the applied voltage at the armature of the motor.

In a particularly preferred embodiment of the invention is therefore intended to use in the pump, a DC motor having a mechanical commutator. Since in this case the speed of the motor is directly proportional to the DC voltage applied to the armature of the motor, the control of speed-dependent characteristics is particularly easy to implement and complicated electronic switching structures, which are always susceptible to defects, can be avoided.

In a preferred embodiment of the invention, the delivery rate of the pump is the control variable. The delivery rate should then be kept essentially constant due to the closed control loop. The delivery rate can be be measured with a flow sensor. In another embodiment of the invention, the controlled variable is given by the speed of the motor, which can be measured for example by means of a tachogenerator or an encoder directly to the motor axis. Further possible controlled variables are the electromotive force induced in the motor, the back EMF (mutual induction voltage) or the current consumption of the motor, which can be measured via a so-called shunt resistor in the circuit of the motor. A combination of several of these parameters is conceivable as a controlled variable. The control variable itself is preferably continuously measured and compared in a controller with the reference variable. This feedback of the actual value of the controlled variable induces a negative feedback which influences the behavior of the control loop.

Namely, if the controller detects a deviation between the reference variable and the controlled variable, ie deviates, for example, due to changes in the delivery pressure, the measured flow rate of the desired flow rate, an actuating variable of the control loop is changed by means of an actuator so that the controlled variable again the value of Leading variable. This type of control is achieved by a negative feedback (negative feedback), so that the control loop is stabilized.

In the case of the present invention, it may be particularly advantageous to use the analog voltage at the output side of the power supply as a manipulated variable, since the speed of the mechanical commutator is directly proportional to this voltage, if applied as an input voltage to the motor and from the brushes is transmitted to the commutator. For example, a DC voltage of 0 volts to 5 volts may correspond to a pump delivery rate of 0 liters per hour to 8 liters per hour. In other embodiments of the invention, the manipulated variable is realized by a pulse width modulated signal, a resistance value or a digital signal. The pulse width modulated signal, for example, between a DC voltage of 0 volts and 5 volts change and thereby have a variable pulse ratio of 0% to 100%, which in turn can correspond to a flow rate of a pump from 0 liters per hour to 8 liters per hour. A combination of several of the above-mentioned manipulated variables as a manipulated variable of the control loop according to the invention is possible.

It is essential that a change in the manipulated variable causes a change in the controlled variable in the controlled system, that is, for example, the rotational speed of the motor or the delivery rate of the pump. In this case, the relationship between manipulated variable and controlled variable, given by the dimensioning and design of the controlled system, so the corresponding components of the pump, in other words, the influence of the manipulated variable on the controlled variable or the effect of negative feedback may be known or modeled. However, it can also be provided to carry out the system identification partially or exclusively via the use of measured values of the input and output behavior of the pump.

When using a pump according to the invention, there are various influencing factors that influence the operation of the pump and thereby have an interfering influence on the control variable and therefore enter into the control loop as disturbance variables. These disturbances cause a change in the controlled variable, so that it no longer coincides with the reference variable and no longer has the desired value. One or more of these influencing factors can be modeled mathematically or physically. In one embodiment of the invention, the disturbance of the closed loop is given by a load-dependent speed change. Such load-dependent speed changes may have different causes, which may result, for example, from the viscosity of the liquid to be pumped, the wear of the pump or other phenomena that affect the delivery pressure.

Various embodiments are available for the DC motor with mechanical commutator used in the pump according to the invention. It is essential that the simplest possible relationship between the controlled variable, so for example, the speed of the motor and the manipulated variable, so for example, the output voltage of the power supply is given. Possible embodiments provide a series-wound motor or shunt motor or a so-called double-cut motor (compound motor) so a hybrid form of series and shunt motor. However, it is also possible to use external excited motors where the exciting current for the electromagnet is supplied by an independent power source. Special forms, such as pancake motors, which also have mechanical commutators, are also possible.

Engines that use permanent magnets instead of electromagnets are among the externally excited motors. Special forms of DC motors with mechanical commutator, such as a pancake motor are also possible.

The power supply of the pump has the task to rectify the AC voltage supplied by the public network on the one hand and on the other hand to transform to a lower or a higher value, ie to convert down or up. When operating with DC can be dispensed with the rectification. In a preferred embodiment of the invention, this power supply comprises a choke, which is designed as a transformer and is also known as a choke transformer (storage choke). The throttle has a coil which may be formed as an air coil or as a coil with a ferrite or iron core. The ratio of the input and output voltage is determined primarily by the circuit and the drive (timing) of the throttle.

In a further embodiment of the invention, the power supply of the pump comprises an RF transformer (RS transformer), said RF transformer comprising a choke coil having primary and secondary windings coupled to a ferrite core or an iron core, wherein the ferrite or Iron core may be completely closed or may have an air gap. The ratio of the given by the core material and the respective number of windings inductors determined to a large extent the ratio of input and output voltage to the transformer, in addition, the output voltage can be adjusted yet on the timing of the primary coil.

Such transformers are known per se for the operation of low-power electronic circuits, for example in switching power supplies (SMPS). It may be particularly advantageous that the reduction of the voltage by a so-called buck converter (Buck Converter) is performed. Such electronic components for transformerless power supplies and buck converters are already known per se. Upconverters are suitable for increasing the voltage, and it may also be intended to use transducers which are a combination of buck and boost converters and are known commercially under the designations converter or special Buck Boost Converter.

Especially for use in small pumps, as used for example in aquariums, the power supply in a preferred embodiment of the invention, the control unit and additionally or alternatively, the control unit, which ultimately drives the motor of the pump. The control unit includes a controller for comparing the reference variable and the control variable and an actuator for preferably automatic setting of the manipulated variable.

It can also be provided that the control unit is arranged in the controller or in the control unit.

An above-mentioned power supply, which includes the control unit and / or the control unit, proves to be particularly advantageous for a pump according to the invention, because the power supply and thereby also the pump can be designed to save space. It is particularly preferred to accommodate such a power supply in the pump housing, whereby no external devices are more necessary except for the power supply. It may be provided that this power supply is integrated directly in the pump head. The pump type itself is irrelevant. The invention relates to all possible types of pumps, such as peristaltic pumps, diaphragm pumps, eccentric pumps, etc.

In one embodiment of the invention, the delivery rate of the pump is specified as an internal or external signal as a reference variable, which is to be kept at a constant value. By the closed loop according to the invention, this maintenance of the delivery rate is made possible, as can be compensated by the control change in the delivery pressure and the viscosity. For this purpose, it is provided in one embodiment of the invention that the pump comprises a device for setting a desired delivery rate. But it can also be provided that the pump has an interface, whereby a desired delivery rate of a separate device can be transmitted. For example, a computer or a processor unit can be connected to this interface, wherein this computer or this processor unit transmits data via the interface to the control unit.

The invention further relates to a pump system having a plurality of pumps, said pumps, as stated above, a DC motor with Have mechanical power inverters and have a power supply for rectification and / or transformation of the voltage applied to the power supply AC voltage or DC voltage and a closed loop to control a controlled variable of the pump. Such a pump system, which can be used, for example, as a dosing system in the metering technique, has the advantage that each pump has its own power supply, so that the pumps can not influence each other.

The invention further relates to a method for operating a pump, as described above, wherein a desired delivery rate of the pump is adjusted and the control of the pump takes place such that the desired delivery rate is substantially maintained by varying the manipulated variable of the control loop of the pump.

Further details and advantages of the present invention will be explained in more detail below with reference to the description of the figures with reference to the drawings. It shows:

Fig. 1

an exploded view of a pump with built-in pump head power supply, which includes a control unit,

Fig. 2

a schematic structure of a power supply according to the invention with control unit and control unit and connected pump motor and measuring devices,

Fig. 3

a diagram of the closed loop according to the invention.

FIG. 1 shows in an exploded view of the essential components of a pump according to the invention 1. The pump motor 6 is arranged in the pump head 14. Also integrated in the pump head 14 is a circuit board 16, on which the essential electronic components, ie the power supply 2 with control unit 4 and control unit 5 are arranged. The pump is closed by the pump housing 15. Further less relevant to the invention components or details of the pump 1 are not shown here for reasons of simplicity.

FIG. 2 shows a schematic representation of the power supply unit 2, which has a power range 3, in which supplied by the public network AC voltage VAC or delivered from an external voltage source DC voltage applied to the input side of the power supply 2, optionally rectified and regulated down, that is converted down. In the present case, this is a per se known transformerless electronic component with a down converter 3 used. Subsequently, a control unit 4 is arranged, which has a controller 12 and an actuator. The control unit 4 determines a manipulated variable u, which is given in this case by the output voltage of the power supply 2 and is delivered via a control unit 5 to the motor 6 of the pump 1. It can also be provided that the control unit 5 is part of the control unit 4. The output voltage supplied by the control unit 4 is applied between the supply lines 10 and 10 'on the output side of the power supply 2 and may for example be between 0 V and 24 V (DC voltage). The pump 1 itself can be disturbed by a variety of factors, such as a load-dependent speed change, these variables are incorporated as disturbance in the control loop 11. In this case, the speed of the motor 6 serves as a controlled variable y and is continuously monitored by a tachogenerator 7 or an encoder, wherein the values of the rotational speed are transmitted from the supply line 8 to the control unit 4. Another possible controlled variable y would be the current consumption of the motor 6, which is measured via a shunt resistor 9 in the circuit of the motor 6 and the supply lines 8 'and 8 is also transmitted to the control unit 4. If the controller 12 determines a difference between the reference variable w, that is to say the target value of the rotational speed and the actual measured rotational speed, the controlled variable 13, which includes an actuator, the controlled variable y, that is, for example, the rotational speed or the current consumption of the motor 6 by a Change in the manipulated variable u, so regulated in this case, the output voltage of the power supply 2. By such a control, the speed of the motor 6 can be kept at a constant value, so that the capacity of the pump 1 is also substantially constant and independent of external influences, since changes, for example, the delivery pressure and the viscosity for the or the liquid to be pumped can be compensated.

FIG. 3 shows a diagram of the closed loop 11 of the pump according to the invention 1. The reference variable w is supplied to the control unit 5, for example by being generated by an external device such as a dosing device. A manual input, which is then transmitted to the control unit 5, is conceivable. The reference variable w may be the analog voltage value of the output voltage of the power supply 2 or an external device, which corresponds to a certain speed of the motor 6 of the pump 1 and thus a certain capacity. However, it can also be provided that the reference variable w is a predetermined delivery rate itself and in the controller 12, a conversion of the reference variable w or the controlled variable y takes place, so that a comparison of these sizes is possible. A pulse width modulated value or a digital signal as a reference variable are also possible. The controller, which is arranged in this embodiment in the controller 12 calculates by comparing the reference variable w with the manipulated variable y a control difference (control error, control deviation) e. In this case, the negative feedback z, so the actual value of the controlled variable y flows with a, which is transmitted via a return line in the closed loop 11 to the control unit 4. The controller 12 processes the control difference e and, based on this result, transmits a modified manipulated variable u via the controlled system 13, in which the controlled variable y is regulated. In the closed loop 11 also the disturbances d flow.

It goes without saying that the pump according to the invention is not limited to the exemplary embodiments shown, nor should they be limited by them.

Claims (15)

Pump for conveying liquids, in particular water, with a DC motor and a power supply for rectification and / or conversion of the AC voltage or DC voltage applied to the power supply, characterized in that the power supply (2) has a closed loop (11) for controlling a controlled variable (11) y) of the pump (1). Pump according to claim 1, characterized in that the DC motor has a mechanical commutator. Pump according to claim 1 or 2, characterized in that the controlled variable (y) of the pump (1) is the speed of the DC motor (6) and / or the current consumption of the DC motor (6) and / or the delivery rate of the pump (1). Pump according to one of claims 1 to 3, characterized in that the manipulated variable (u) of the control circuit (11) of the pump (1) one or more of the elements of the group of an analog voltage, preferably the output voltage of the power supply (2), a Resistance value, a pulse width modulated signal and a digital signal. Pump according to one of claims 1 to 4, characterized in that the disturbance (d) of the control circuit (11) of the pump (1) a load-dependent speed change of the DC motor (6) and / or a non-linear motor characteristic of the DC motor (6) and / or a non-linear capacity of the pump head (14). Pump according to one of claims 1 to 5, characterized in that the DC motor (6), preferably by means of a permanent magnet, a fringe-excited DC motor or a fringe-excited shunt motor or a series motor or a compound motor or a pancake motor. Pump according to one of claims 1 to 6, characterized in that the power supply (2) is an electronic power supply. Pump according to one of claims 1 to 7, characterized in that the power supply (2) comprises a choke transformer, preferably a storage choke. Pump according to claim 7 or 8, characterized in that the power supply (2) comprises a down converter (3) and / or an up-converter. Pump according to one of claims 1 to 9, characterized in that the power supply (2) comprises a control unit (4) and / or a control unit (3). Pump according to one of claims 1 to 10, characterized in that the power supply (2) in the pump housing, preferably in the pump head, is integrated. Pump according to one of claims 1 to 11, characterized in that the pump (1) comprises a device for setting a desired delivery rate, and / or has an interface, whereby a desired delivery rate of a separate device can be transmitted. Pump according to one of claims 1 to 12, characterized in that the control takes place automatically. Pump system, preferably metering system, consisting of a plurality of pumps (1) according to one of claims 1 to 13. Method for operating a pump according to one of claims 1 to 13, characterized in that a desired delivery rate of the pump (1) is set and the control of the pump (1) is such that via variation of the manipulated variable (u) of the control loop (11 ) of the pump (1) the desired flow rate is substantially maintained.

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