EP2322809A1 - Control device for a fluid actuator and electric voltage supply unit - Google Patents

Abstract

The device has an air-pressure transducer (24) provided with an electrical generator for generating electrical energy and an energy storage, where the device is arranged in a common housing. The transducer is connected with a pressure line (16) by a load control valve (23). A valve driver stage arrangement (29) is connected with the valve for opening the valve during undershooting of a given charge state of the energy storage. An inlet valve (17), working valve (18) and the control valve are controlled by the arrangement and guide an exhaust air of an actuator to the transducer.

Description

The invention relates to a control device for at least one fluidic actuator according to the preamble of claim 1 and an electrical supply module for power supply according to the preamble of claim 13.

Such, from the WO 01/18405 A1 known control device includes for generating energy, for example, an air pressure transducer with electric generator. This is constantly connected to the pressure line, which has a constant air consumption, even if the energy storage has sufficient memory content. Due to the continuous operation, it is even proposed to completely dispense with the energy storage. Its state of charge thus depends on the operation of the other components and is more or less random.

An object of the present invention is to improve the known control device and a corresponding electrical supply module so that the air consumption is minimized despite sufficient power supply.

This object is achieved by a control device with the features of claim 1 or claim 2 and solved by a supply module having the features of claim 13.

The advantages of the control device according to the invention are, in particular, that the air pressure transducer for the charge control valve is only switched on when this is necessary for the energy supply. In the remaining time, so with sufficient state of charge of the energy storage, the air pressure transducer is turned off, and there is no air consumption. By the charge control device, the state of charge of the energy storage can be completely detected. The entire control device has the further particular advantage that it only has to be connected to a fluidic line. All electrical supply and control lines can be omitted. It is therefore particularly suitable for use in spatially widely distributed systems, such as process equipment, where enormous installation costs can be saved.

Advantageously, the supply module can be realized by the arrangement of both the turbine wheel and the rotor of the generator in the same housing very small, the arrangement of the rotor and the turbine on a common shaft still supports this Kleinstaubweise and contributes to a simple assembly, as both in one operation can be used in the housing. The entire supply module is quickly and easily replaceable as a compact unit.

The measures listed in the dependent claims advantageous refinements and improvements of the claim 1 control device are possible.

An even more favorable energy balance and an even lower air consumption for power generation can be achieved by providing actuator exhaust air controlled by the valve driver stage arrangement via the valve assembly carrying the air pressure transducer. Fluidic actuators must be vented again and again due to operational reasons. Advantageously, this otherwise not usable for the energy balance exhaust air is guided through the air pressure transducer and contributes positively to the energy balance, namely for charging the energy storage at. As a result, it must be switched on less often by the fluidic pressure line.

Advantageously, the charge control valve can form part of this valve arrangement and thus contribute to reducing the number of total components.

At least one sensor interface which can be connected to external sensors has proven to be favorable on the sequence controller. As a result, for example, sensors arranged on the actuators can be evaluated without the need for voltage supply lines from external devices.

A pressure sensor connected to the pressure line is expediently connected to the sequence controller in order to be able to monitor the supply pressure and to be able to take suitable measures if it moves outside a correct range.

The energy balance can additionally be improved by providing a solar cell generator and / or a wind generator in addition to the charge of the energy store.

The energy store is expediently designed as an electric battery, in particular as a rechargeable battery, or as a capacitor arrangement.

In particular, an infrared and / or radio device is suitable as a wireless transmitting and / or receiving device.

The entire control device with all the components can be advantageously designed as a compact unit, in particular be arranged in a common housing.

The housing of the supply module expediently has a cylindrical or cuboidal shape, which can be optimally adapted to the rotating parts in the interior with regard to the desired micro-construction.

An important contribution to the desired miniature construction is the arrangement of the stator winding of the generator in the rotor of the generator encompassing wall portion of the housing, so that the stator winding takes up no additional space. For this purpose, suitable as a stator winding, in particular a basket winding, wherein the rotor has a permanent magnet arrangement.

In a further embodiment, the housing interior is divided by an intermediate wall into a first chamber for receiving the turbine wheel and the rotor of the generator and in a second chamber for receiving the valve, the charge control device and the energy storage. The intermediate wall then expediently carries a first shaft bearing and one of the two housing end faces another shaft bearing.

The generator is expediently designed as an alternating voltage generator, in which case the charging control device contains the electrical components required for forming a direct voltage, for example a rectifier arrangement, a regulating device and / or a smoothing device. However, the generator can also be designed as a DC voltage generator.

• Figur 1 ein Blockschaltbild einer Steuereinrichtung als Ausführungsbeispiel der Erfindung und
• Figur 2 ein elektrisches Versorgungsmodul zur Spannungsversorgung der Steuereinrichtung oder einer sonstigen elektrischen Einrichtung.

Embodiments of the invention are illustrated in the drawings and explained in more detail in the further description. Show it:

• FIG. 1 a block diagram of a control device as an embodiment of the invention and
• FIG. 2 an electrical supply module for supplying power to the control device or other electrical device.

The control device described below for at least one fluidic actuator 10 is housed as a compact unit in a common housing 11, wherein variations may also be divided into several units. In the exemplary embodiment, a single actuator is shown, for example, a linear drive, a pneumatic gripper, a working cylinder, a process valve or the like, wherein a plurality of identical or different actuators can be controlled. For this purpose, a corresponding number and design of control valves must be provided in the control device. It is also possible to arrange the control device together with an actuator integrally in a housing or to integrate.

For electronic control of the actuator 10 is a flow controller 12, which contains at least one microprocessor or a logic logic. A radio device 13 designed as a transmitting and receiving device is used for wireless data transmission from and to an external control unit 14, which may be, for example, a central control for a plurality of such control devices. From this control unit 14 control signals are transmitted to the sequence controller 12, wherein in the reverse direction, transmission signals are sent to the external control unit 14. The flow controller 12 may itself include a flow program through which certain functions and operations in the actuator 10 may be independently controlled. It remains the respective conception reserved which and how many functions of the sequence controller 12 can run independently and which and how many functions are controlled by the external control unit 14.

As an additional wireless communication device, an infrared device 15 is also connected to the sequence controller 12, via which alternatively or additionally a communication with external devices, for example also with an external control unit, can be carried out. In a simpler embodiment, this infrared device 15 can also be omitted.

The control device is connected to a fluidic pressure line 16 to which a working pressure P of an external pressure source is constantly applied. This pressure line 16 extends via an input valve 17 and a working valve 18 in the housing 11 to the actuator 10. A connected to the pressure line 16 pressure sensor 19 is connected to the sequence controller 12 and transmits the measured pressure values to this. Furthermore, external sensors 20, 21 are connected via a sensor interface 22 to the sequence controller 12, to this sensor data, for example of the actuator 10 or other external sensor data. Such sensor data are, for example, pressure data, temperature data, position data or the like. All sensor data can be transmitted from the flow controller 12 via the radio device 13 of the external control unit 14.

In the case of the formation of the sensors 20, 21 or a part thereof as a position sensor or as a plurality of position sensors or as a continuous path or angle measuring system of the sequence controller 12 is used for position control of, for example, designed as a working cylinder or process valve actuator 10. In addition to a limit position detection and / or end position control of the corresponding actuator member of the actuator 10, so for example a piston or valve member, while also a cushioning can be realized. Depending on the number of position switches or position sensors several positions can be approached or adjusted. In the case of a continuous path or angle measuring system, any positions can be approached. For fine control, an electric or electropneumatic fine drive can be provided as an additional servopneumatic or electrical positioner, which is switched linear or parallel. Overall, a sensor-dependent position control is thereby realized, which requires no supply of electrical energy from the outside and thus forms a self-sufficient device, wherein preferably the control device is attached to the actuator or together with this forms an integrated unit.

The pressure line 16 is further connected to the input valve 17 via a charge control valve 23 and an air pressure transducer 24 with a fluid outlet 25. The air pressure converter 24 drives an electric generator 26 whose generated Voltage via a charge control device 27 for charging an electric storage battery 28 is used. The electric generator 26 may be a DC or AC generator. In the case of an AC voltage generator, the charge control device 27 also contains a controlled or uncontrolled rectifier arrangement, eg a MOSFET rectifier circuit. The charge control device 27 reports the respective state of charge of the storage battery 28 to the sequence controller 12, which then opens the charge control valve 23 via a valve driver stage arrangement 29 as required, that is to say when the charge state is too low, and thereby the air pressure converter 24 and the electric generator 26 for charging the storage battery 28 in operation. After reaching the respectively provided correct state of charge then the charge control valve 23 is closed again. The charging control device 27 supplies all the electrical and electronic components of the control device with the required supply voltage. For this purpose, the Ladesteuerungseinrichtüng 27 includes a voltage converter, which converts the voltage of the storage battery 28 in the respectively required supply voltage, which should be a stabilized voltage.

The air pressure transducer 24 may be formed, for example, as a microturbine or vane motor, with vane motors being commercially available, for example, under the name Globe vane motor. Incidentally, any known system can be used for the combination of air pressure motor-generator in the invention, can be converted by the air pressure energy into electrical energy. In addition to rotating generators, it is also possible to use non-rotating electrical generators, for example piezo-generators.

The input valve 17 and the working valve 18 are also controlled by the drain controller 12 via the valve driver stage assembly 29. The input valve 17 is open in the normal state. In a venting of the actuator 10, the outflowing fluid is used in addition to the operation of the air pressure transducer 24 and the electric generator 26 and thus to charge the storage battery 28. For this purpose, the working valve 18 and the charge control valve 23 are opened and the input valve 17 is closed. As a result, the fluid flow around the actuator 10 can be guided via the air pressure transducer 24 to the fluid outlet 25.

Alternatively, the working valve 18 may be formed as a multi-way valve and have a fluid outlet for the discharged from the actuator 10 fluid. This fluid outlet can then be connected directly to the inlet of the air pressure transducer 24. In this case, the input valve 17 can be omitted, and the charge control valve 23 is closed during the backflow of the fluid from the actuator 10. The execution of the working valve 18 depends not least on the control requirements for the actuator 10, that is, how many control paths the working valve 18 must have. Of course, instead of a working valve, it is also possible to provide a plurality of working valves, in particular also in the event that a plurality of actuators 10 are connected. Above all, impulse valves are suitable as valves.

The charge control device 27 may also be integrated in the drain controller 12. Alternatively, a separation of the charge control device 27 may be provided in a module for actual charge control or regulation and in a module for power supply.

For additional energy generation, a solar cell generator 30 and / or a wind generator 31 may also be provided. This depends on the particular local conditions, that is, whether the control device is positioned at a location that ensures sufficient light, or at a point where sufficient wind occurs, so for example in an outdoor application.

If the control device is used in a potentially explosive area, then the units used must be explosion-proof, for example, the housing would have to be designed either pressure-resistant or overpressure-encapsulated.

Instead of an electrical storage battery 28 or other electrical accumulator, for example, a capacitive element or a capacitor arrangement can be used as an energy storage, including, for example. at least one gold cap or ultracap element is particularly suitable.

This in FIG. 2 illustrated electrical supply module includes a part of the components and assemblies according to FIG. 1 Essentially, the part that is used for the power supply. These components are integrated in a separate module housing 41, which is used to power the in FIG. 1 can be used in the housing 11 shown control device. However, this electrical supply module 40 can also be used to supply power to other electrical devices that have a fluid connection, in particular a compressed air connection. Same or equivalent components and assemblies already in FIG. 1 are shown and described in wear FIG. 2 the same reference numerals.

The example cylindrical, cuboid or pot-shaped module housing 41 includes the arranged on a common shaft 42 compressed air converter 24 and the electric generator 26. This common shaft is connected to an end portion in a bearing 43 of an end wall 44 of the module housing 41 and with its other end in one Bearing 45 mounted in an intermediate wall 46.

A compressed air inlet 47 is connected to a compressed air outlet 48 via the charge control valve 23 designed as a proportional valve and via the compressed air converter 24 designed as a microturbine. If the compressed air inlet 47 is acted upon by compressed air, then a turbine wheel 49 of the compressed air converter 24 is driven and set in rotation, which in turn drives a rotor 50 of the electric generator 26 via the common shaft 42.

The electric generator 26 consists of this rotor 50 and a stator winding 51 in the form of a basket winding, which is arranged in a wall region of a housing part 52 of the module housing 41 encompassing the rotor 50. In principle, this stator coil 51 could also be arranged on the inside of the housing part 52, but this would require a larger amount of space. Furthermore, in an alternative bell armature design, the winding may also rotate while the permanent magnet substantially forms the stator.

The stator coil 51 is connected via electrical lines 53 to the charge control device 27, which is also located in the module housing 41 and which is designed to charge the electric storage battery 28 on the one hand and for the removal of energy from the same, as has already been described. In one as an alternator trained generator 26, the components required for the voltage conditioning in the charge control device 27 are included. This may be, for example, a rectifier arrangement and / or a regulating device and / or a smoothing arrangement. The rectifier arrangement can be designed as a controlled or uncontrolled rectifier circuit, for example as a MOSFET circuit. Instead of an alternator, of course, a DC generator can be used, which does not require a rectifier arrangement. The sequence controller 12 could additionally be integrated in the module housing.

The module housing described is a very small housing which is suitable for insertion into pneumatic or electrical arrangements with pneumatic components. A typical size, for example, has a length of 30 mm and a diameter of 20 mm. In this small size, the charge control valve 23 may be formed, for example, as a piezo valve.

A speed sensor 54 is used to detect the rotational speed of the turbine wheel 59 and the rotor 50 of the generator 26. It is also connected via the electrical lines 53 to the charge control device 27, wherein the illustrated two lines 53 are only a schematic representation. The number of lines, however, depends on the respective requirements. The rotational speed signal of the rotational speed sensor 54 is supplied to the charge control device 27, which contains a control device, as an actual value in order to regulate the rotational speed of the generator 26 as a function of the required charging voltage. It is a load-dependent speed control to regulate a desired voltage of 12 V, for example. This is done via the trained as a proportional valve Charge control valve 23, which controls the flow of air through the compressed air converter 24 continuously. The actuation of the charge control valve 23 via the integrated valve driver stage assembly 29, of course, according to FIG. 1 can be designed as a separate unit.

The state of charge of the storage battery 28 is continuously interrogated by the charge control device 27, and according to the speed of the electric generator 26, the charging voltage is regulated. At electrical connections 55 of the charge control device 27, the voltage of the storage battery 28 or a voltage derived therefrom can be tapped as the supply voltage. For this purpose, the charge control device 27 may also include a voltage converter and / or a voltage regulator to provide one or more supply voltages as stabilized voltages available.

The pressure sensor 19 generates a sensor value which corresponds to the supply pressure at the compressed air inlet (47) and supplies it to the charge control device (27) so that the speed control can be influenced as a function of the available supply pressure.

Claims (10)

Electric supply module with an electric generator (26) driven by an air pressure transducer (24), wherein the rotor (50) of the generator (26) and the turbine wheel (49) of the compressed air converter (24) have a common shaft (42) and in the same housing (41) are arranged, characterized in that the housing (41) in addition an electric energy storage (28), a charging process regulating charge control device (27) and the air flow through the compressed air converter (24) predeterminable, controlled by the charge control device (27) as a proportional valve formed valve (23), wherein a speed of the generator (26) detected as an actual value speed sensor (54) to the charge control device (27) for controlling the speed in dependence of the state of charge of the energy store (28) is connected. Supply module according to claim 1, characterized in that the housing (41) has a cylindrical or cuboid shape. Supply module according to claim 1 to 2, characterized in that the rotor (50) of the generator (26) encompassing wall portion of the housing (41), the stator coil (51) of the generator (26). Supply module according to one of claims 1 to 3, characterized in that the stator coil (51) of the generator (26) is designed as a basket winding and the rotor (50) has a permanent magnet arrangement. Supply module according to one of claims 1 to 3, characterized in that the housing interior through an intermediate wall (46) in a first chamber for receiving the turbine wheel (49) and the rotor (50) of the generator (26) and in a second chamber for receiving the valve (23) of the charge control device (27) and the energy store (28) is divided. Supply module according to claim 5, characterized in that the intermediate wall (46) carries a first shaft bearing (45) and one of the two housing end faces (44) carries a second shaft bearing (43). Supply module according to one of claims 1 to 6, characterized in that the generator (26) is designed as a DC voltage generator or as an AC voltage generator and the charge control device (27) in the case of training as an AC generator, the electrical components required to form a DC voltage. Supply module according to claim 7, characterized in that a rectifier arrangement and / or a smoothing device are provided as electrical components. Supply module according to one of claims 1 to 8, characterized in that the energy store (28) is designed as an electric battery, in particular as an accumulator, or as a capacitor arrangement. Supply module according to one of claims 1 to 9, characterized in that the charge control device (27) includes a voltage converter and / or a voltage regulator for specifying at least one supply voltage and / or a charge controller and / or a sequence controller (12).

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