EP2705586A1 - Electromotive drive for furniture, comprising a power supply device - Google Patents

Abstract

The invention relates to an electromotive drive (1) for furniture, which comprises a power supply device (5), a manual control (7), and a control device (17), and which is to be simplified and improved with regard to its switching functionality. According to the invention, the power supply device (5) has an isolator unit (30) that can be controlled by means of a control line (32), the electrical control signal of said control line (32) being able to be modified by a switching contact of the manual control (7) such that, when the manual control (7) has not been actuated, the power supply device (5) can be switched into the "isolated" operating state, said isolator unit (30) being connected to a signal feedback arrangement of a control circuit of the power supply device (5) and being integrated in a path of said signal feedback arrangement, or said isolator unit (30) being set in, or placed on, an input path or an output path of the control device (17).

Description

 Electromotive furniture drive with a power supply device

The invention relates to an electromotive furniture drive with a power supply device for adjusting movable furniture components relative to each other.

Such electromotive furniture drives are known in different embodiments. They are linear actuators with a linear adjustable

Output member or designed as a rotary drive with a rotating output member and have proven themselves in practice. The linear drives have one or a number of electric motors, each motor being followed by a speed reduction gear and a further gear following the speed reduction gear, for example in the form of a threaded spindle gear, which generates a linear movement of the output member from the rotational movement of the motor. The rotary drives have at least one speed reduction gearbox connected downstream of the respective electric motor, with the last gearbox element forming the driven element. The output member of the respective electromotive furniture drive is connected to a fixed and / or with a movable furniture component, so that during an operation of the electric motor, the movable furniture components are adjusted relative to each other. The furniture can be designed as a slatted base, work table, bed, lying surface, treatment couch, hospital or nursing bed, as well as a lifting device for persons such as lifters or patient lifts. To operate the electric motor furniture drives switching power supplies have proven to be the best power supply device. The power supply device has different operating states, namely an operating state Off in the event of disconnection from the network, an operating state of commissioning after connection to the network to regular operation and an operating state of operation in regular operation. The switching power supplies have an isolation transformer connected by a control module with a high frequency, which can also be referred to as a transformer or as a high-frequency transformer, which is switched on and off by an upstream semiconductor switch on the primary side with a high switching frequency. For this purpose, the control module is assigned a separate intermediate circuit, which has a power source of the control module and supplies the control module with an electrical energy. If the energy supply device is not connected to the network or at least for a period of time, then the energy supply device is in the "off" operating state, with all energy stores, such as capacitors, being virtually without energy. If the energy supply device is connected to the network, the operating state initially changes from the operating state "off" to the operating state "startup". The power source of the control module is connected to a charging circuit and supplies the power source in the operating state of commissioning with electrical energy. Such an energy source with an associated charging circuit is known from the prior art and has proven itself best.

It should still be explained in more detail the state of the art of the disconnecting device, wherein the disconnecting device has at least one network-side controlled switch in the form of a relay switch or a semiconductor switch for disconnection from the network. In the non-energized state of the disconnecting device, the at least one controlled switch is in an open state and does not conduct mains voltage to the power supply device. When the operator presses a manual operation button, the enabling device changes from the non-energized state to the energized state, with the controlled switch or contacts of the controlled switch changing to a closed state, supplying the power supply device with the electrical energy from the network.

The isolation devices have proven themselves in practice, especially as they cause a galvanic isolation from the network and in the state "" Unlocked "" is present at its output no electrostatic alternating field. The cost of this, however, are not insignificant and the installation cost is correspondingly high, especially since the release devices are preferably arranged in a housing with attached power plug. The invention has for its object to simplify an electromotive furniture drive with a power supply device of the type described in more detail circuitry with improved functionality.

In the case of an electromotive furniture drive with a power supply device, the solution is achieved in that the power supply device has a disconnect unit controllable via a control line, wherein the electrical control Ersignal the control line by a switching contact of the manual control is changeable such that the power supply device in the non-actuated state of the manual operation has the operating state "Enabled".

The controllable disconnection unit is controlled by the respective push-button switch of the manual control, wherein a control signal is triggered by the manual pressing of a button and fed via the control line into the disconnection unit connected thereto.

The enable unit is also operatively connected to a signal feedback of a control circuit of the power supply device. In this case, a first embodiment provides that the enabling unit is integrated in a path of the signal feedback. Another embodiment provides an unlock unit which is inserted in or attached to an input path or an output path of the control device or attached thereto.

The controllable disconnection unit has the function that it changes the signal feedback of the power supply device such that via the control output of the control device of the power supply device between a high frequency switching signal in the operating state of regular operation and no high frequency signal in the operating state "Enabled "can be switched.

In this way, according to the invention, all the components of a prior art disconnecting device which have been described above are omitted because the prior art energy supply device designed as a switched-mode power supply can be only slightly widened according to the invention and the electrical isolation of the transformer unit can be used, so that the power supply device in the operating state "enabled" itself according to the invention acts as a disconnecting device, or represents such.

In principle, in the operating state "Enabled" on the primary side of the input circuit and parts of the intermediate circuit, which will be explained in more detail below, although under mains voltage, since the entire control circuit of the power supply device by the controllable disconnecting unit in the operating state "enabled" is practically disabled , no high-frequency control of the transmitter unit takes place, so that in the "released" operating state neither electrostatic see alternating fields arise, nor is an energy consumption by the transmitter unit. Thus, in a further inventive manner, a power supply device is provided, which assumes the operating state "Enabled" in the unused state of the electromotive furniture drive and thereby has a quiescent output of significantly less than 0.5 watts.

Depending on the design of the switched-mode power supply, the potential of the signal feedback of the switched-mode power supply units known in the prior art and designed as a power supply device may increase with the switching frequency at the transmitter unit with increasing frequency or fall with increasing frequency. For this reason, several embodiments of enabling units come into consideration, which however all cause that in the operating state "Enabled" no high-frequency signal is applied to the transmitter unit.

A first embodiment of a disconnection unit is formed by a node or by a feed point, wherein in the signal feedback a relatively high

Voltage, for example, a supply voltage of 5 volts, is fed, the supply voltage means the maximum of the potential on the signal feedback and as a result, the controller does not transmit a Hochfrequenzschaltsignal to the switching module, so that no high-frequency signal at the

Transformer is applied. Further, a non-powered auxiliary power source is provided in the form of a high-capacity battery or capacitor, wherein in the non-actuated state of the hand-held operation, a transistor switch or a handset contact is switched and electrical energy is supplied from the auxiliary power source to the feed point.

A second embodiment of a disconnection unit is formed by another node in the path of the signal feedback, wherein the signal feedback is formed as hohohmiger control path and at the node, a switching transistor or a contact of the manual switch button is attached.

In the non-actuated state of the manual control, the switching transistor is conductive or the contact of the manual switch button is closed, wherein the electrical potential of the node or the electrical potential of the signal feedback is switched to ground. In this embodiment, the result of a potential-free state of the signal feedback means that the control device has no Radio frequency signal transmits to the switching module, so that no high-frequency signal is applied to the transmitter.

A third embodiment of a disconnection unit provides a galvanic release agent in the form of a transmitting coupler. When a voltage is applied to the input of this enable unit, the state changes at its output, the state at the output having a switching signal, a voltage signal or a frequency signal. In a preferred embodiment of the disconnection unit, this is designed as an optocoupler or as a photovoltaic coupler, in which case the output of the disconnection unit has a switching signal and / or a voltage signal. In the following, the disconnection unit will be explained in more detail by the example of an unlock unit designed as an optocoupler.

The switching output of the optocoupler is preferably in operative connection with the signal feedback. In one embodiment, the switching output of the

Optocoupler used in an electrical series circuit in the path of signal feedback. Since such release units have a galvanic isolation between their input and their output, such an enable unit can also be attached to or in the control device or inserted therein in another embodiment. Thus, it is grateful that the output of the

Optocoupler is in electrical series connection with the input of the control device or with a frequency output of the control device or with a power supply terminal of the control device in electrically conductive connection. In one embodiment, a high-impedance power supply of the control device is provided. Advantageously, according to this embodiment, the switching outputs of the optocoupler or the switching outputs of a controlled by the switching output of the optocoupler transistor switch to the power supply terminals of the control device connected such that in the non-actuated state of the manual control and / or in the operating state "Unlocked" the power supply terminals of the control device with each other are connected. Thus, the control device is switched on the input side energy-free and since the power supply of the control device is formed high impedance, only a very low leakage current flows here. Furthermore, the isolating unit designed as a galvanic isolating means has a signal input which is connected to the control line. The switching of the potential of the control line is carried out effectively by the manual key operation of the manual control. Depending on the design of the power supply device designed as a switched-mode power supply, the potential connected to the control line must be adapted. In a first embodiment of a switching power supply-forming power supply device is provided in a non-actuated button of the manual operation, that the potential of the control line is 0 volts or approximately 0 volts. As a result, the transmitter unit is not supplied with a high-frequency switching signal. However, a preferred embodiment provides that in the case of an unactuated button of the manual control, the potential of the control line on the disconnecting unit is a voltage of several volts, for example 5 volts or 24 volts. As a result, in this embodiment, the output of the enable unit switches such that the high-frequency switching signal can not be supplied to the transmitter unit. In this embodiment, an auxiliary voltage source is provided in the form of a battery or a capacitor with a high capacitance, wherein the capacitor may be formed as a gold cap. Advantageously, the auxiliary voltage source is arranged on the secondary unit of the power supply device and is charged in the operating state of the regular operation or supplied with energy to maintain the charge.

Advantageously, the auxiliary voltage source is additionally designed as a voltage source for the operation of transceivers such as radio receivers or infrared receivers or for the operation of processor units. After the auxiliary voltage source has been sufficiently charged by the power supply device in the operating state of the regular operation and, moreover, no push-button of the manual control is actuated, a circuit is closed, which conducts the energy from the auxiliary voltage source to the input of the activation unit. As a result, the enabling unit switches free, which means that no high-frequency switching signal is supplied to the transmitter unit and the energy supply unit has the operating status "enabled". With increasing time, the energy potential of the auxiliary voltage source is reduced in such a way that it is foreseeable that the input of the enabling unit does not have enough energy to maintain the switching state of its output. If the energy potential of the auxiliary voltage source continues to decrease, the output of the enabling unit undergoes a changeover, as a result of which the high-frequency switching signal is activated at the transmitter unit and the energy supply unit sets the operating state of regular operation. takes. In this way, an automatic recharging of the auxiliary power source by the secondary unit takes place.

However, if the power supply device is in the operating state "Enabled" and a push-button of the manual control is actuated, the circuit between the auxiliary voltage source and the input of the enable unit is opened according to the previously described embodiment. This is done in a simple manner by the button of the manual control is assigned a normally closed contact. However, a preferred embodiment of an NC contact in the circuit between the auxiliary voltage source and the input of the enable unit provides a transistor switch, which is turned on in the de-energized state and the control terminal is electrically connected to a trained as a contact contact terminal of a button of the hand control.

Other characteristics and features will be apparent from the following description of a preferred embodiment and are the subject of further subclaims.

Reference to the accompanying drawings, the invention will be explained in more detail. Show it:

Figure 1 is an exemplary and schematic representation of a trained as a linear drive furniture drive according to the invention with a power supply device;

Figure 2 is a schematic block diagram of an embodiment of the

 Energy supply device according to Fig. 1; and

FIG. 3 shows a schematic block diagram of a further exemplary embodiment of the energy supply device according to FIG. 1.

FIG. 1 shows an electromotive furniture drive 1 with a power supply device 5.

The electromotive furniture drive 1 is a so-called linear drive 2, and the power supply device 5 is designed as a switching power supply. The linear drive 2, depending on the direction of rotation of an electric motor, not shown, a retractable and extendable lifting tube 3, at its free end a connection part in the form of a clevis 4 is mounted. Another connection part in the form of a further fork head 4 is fastened to the housing of the linear drive 2. The respective connection part is in a manner not shown in each case with a furniture component in connection, so that move the connected to the linear drive 2 furniture components relative to each other during operation of the electric motor.

The power supply device 5 is connected according to the illustration of Figure 1 via a power cord 200 with a power plug 8, wherein in another and not shown embodiment of the power plug 8 may be disposed on the power supply device 5. It should be noted that the power supply device 5 is provided according to the illustration of Figure 1 with an enclosing housing, so that the power plug 8 can be attached to the housing or molded. The power plug 8 leads via power cord 200, the input-side mains voltage to the power supply device 5 designed as a switching power supply, which outputs a low voltage in the form of a DC voltage on the secondary side and forwards them to a motor controller 6.

On the motor control 6, a hand control 7 is connected in wired form, wherein, according to the representation of FIG. 1, the hand control 7 has two pushbuttons. According to another embodiment not shown in detail, the handset 7 is coupled to the motor controller 6 via a wireless link and transmits radio waves or infrared light waves to control the at least one electric motor, i. Linear drive 2 to the engine control 6.

According to the illustration of Figure 1 is in a first embodiment, the manual control 7 with a motor controller 6 in conjunction, the motor controller 6 is designed as a relay control with relay switches and / or as a semiconductor circuit with semiconductor switches. The manually operable push-button switch of the manual control 7 switch the control current of the relay switch or the semiconductor switch, wherein the circuit breaker of the relay switch or the semiconductor switch switch the high motor current of the linear actuator 2. According to the illustration of Figure 1 is in a second embodiment, the

Hand control 7 with the motor control 6 in connection, which is a supply cable 9 of the power supply device 5 and a motor cable 210 of the electric motor of the linear drive 2 and the electrical lines of the manually operable push-button of the hand control 7 connects to each other. According to this embodiment, the contacts of the manually operable push-button of the manual control 7 are designed as a circuit breaker and switch at actual pressure the high motor current.

In a further, but not shown embodiment, the power supply device 5 is inserted into the housing of the linear drive 2 or attached thereto, wherein the linear drive 2 can be constructed in a manner not shown in the manner of a double drive, which at least one motor, but preferably two Engines motors in a common housing.

FIG. 2 shows a schematic block diagram of a first exemplary embodiment of the power supply device 5 according to FIG. 1.

The power supply device 5 has an input circuit 10, an intermediate circuit 11, a transformer unit 14, a secondary unit 15, an optocoupler 16, a control device 17 and a control supply 18. The input circuit 10 is the input side (indicated by arrows) coupled to the network via power plug 8 and power cord 200. In the input circuit 10 are conventional network interference suppressors, such as capacitors and chokes, as well as fuses included, which are not shown here. The input circuit 10 is connected to the intermediate circuit 1 1, which has a rectification 12 and a switching component 13, for example a switching transistor. The intermediate circuit 1 1 is coupled to the switching module 13 to the transmitter unit 14. The transmitter unit 14 has a transformer with electrical isolation 19, which extends through the power supply device 5 therethrough. On the secondary side of the transmitter unit 14, the secondary unit 15 is connected, which provides a supply voltage Uv for supplying the linear drive 2 via the supply cable 9 to the motor controller 6. A reaction of the secondary unit 15 is arranged via an optocoupler 16 with galvanic isolation 19 to the control device ^. The control device 17 controls the switching module 13 for regulating the supply voltage Uv of the secondary unit 15. The control unit 17 is supplied with electrical energy by a control supply 18. In one embodiment of the power supply device 5, the control device 17 and the switching module 13 are coupled to the control circuit and interconnected such that the height of the signal arriving at the control device 17

Optocoupler 16, wherein the input voltage of the optocoupler 16 is coupled to the output-side supply voltage Uv, the control device 17 controls such that the 17 controlled by the control device switching frequency of the switching module 13 is guided. Thus, a feedback device is provided for the control loop, which can be acted on the input side with the supply voltage Uv and the output side, the switching frequency of the switching module 13 has. The switching component 13 switches the input coil of the transmitter unit 14 in a high-frequency range and together with the transmitter unit 14 forms a transmission characteristic which is constructed in such a constructive manner that the transmissible electrical power of the transmitter unit 14 changes as a function of the controllable switching frequency of the switching component 13. With increasing current flow at the output side of the power supply device 5, the signal at the optocoupler 16 is variable, which changes a change in the switching frequency of the switching module 13. If the current flow at the output side of the energy supply device 5 continues to increase, the switching frequency of the switching component 13 changes such that the transmission characteristic of the transmitter unit assumes a less ideal state, which is in operative connection with a reduction in the output of the energy supply device 5 , In the event of a short circuit or a high overload on the output side of the power supply device 5 Schaltfrequenzbegrenzungs- means are provided which form an intermediate control loop with the input member of the switching block 13 and the controller 17 and limit the switching frequency of the switching component so regulating that it results in the holding voltage Uh , Thus, at least the optocoupler 16, the control device 17, the switching module 13, the transmitter unit 14 and possibly also the secondary unit 15 are coupled to the control circuit described in more detail below or arranged therein. Fixed or variably adjustable setting means, which determine the height of the holding voltage Uh, are connected in or on the control loop.

According to the exemplary embodiment according to FIG. 2, the secondary unit 15 has an auxiliary voltage source 41, which is designed as a voltage-connected auxiliary voltage source and as a capacitor of high capacity. In a manner not shown, the auxiliary voltage source 41 can be used as a network-connected auxiliary voltage source. be formed source and having an autotransformer with very low quiescent current consumption.

In a further, but preferred, and also not shown, the auxiliary voltage source 41 may be formed as a network-connected auxiliary voltage source. In this case, this grid-connected auxiliary voltage source can have an economical transformer, which is, for example, an isolation transformer with a low power. In this case, the economical transformer is designed such that its quiescent current consumption is reduced compared to conventional (isolating) transformers with low power and is very small.

Furthermore, FIG. 2 illustrates a disconnection unit 30, which is integrated here in three exemplary embodiments in the signal feedback 40 between the secondary unit 15 and the optocoupler 16 or in the signal feedback 40 between the optocoupler 16 and the control device 17 or in or on the control device 17 or on it is scheduled. Furthermore, a control line 32 is provided, which electrically connects the input of the activation unit 30 with the manual control 7 or electrically connects the input of the release unit with the auxiliary voltage source 41. FIG. 3 shows a schematic block diagram of a further exemplary embodiment of the energy supply device 5 according to FIG. 1.

The power supply device 5 of this further exemplary embodiment differs from that of the exemplary embodiment according to FIG. 2 in that a coupling unit 16 'is provided which is coupled on the secondary side to the control line 32 and on the primary side to the disconnection unit 30 which is either in the control device 17 or in the signal feedback 40 is arranged, is connected. The coupling unit 16 'also has the galvanic isolation 19. The disconnection unit 30 (either in the control device 17 or in the signal feedback 40) in this embodiment can therefore be designed particularly simply without galvanic release means, e.g. as a switching transistor.

The coupling unit 16 'can be realized in different ways. It is thus possible, for example, for the coupling unit 16 'to be a further optocoupler, also in photovoltaic design. Furthermore, it is also conceivable that the coupling unit 16 'as electromechanical switch, for example as a miniature relay, is designed with appropriate galvanic isolation.

It may also be possible that a combination of more than one enabling device 30 is provided at different locations or in series.

In yet another combination, it is possible that the coupling unit 16 'is arranged parallel to the control line 32 according to the embodiment of Figure 2 as a redundant control of the enabling device 30. The invention is not limited to the illustrated embodiments. It is essential, however, that the power supply device 5 has an operating state "Enabled" and a switchover into or out of the operating state "Enabled" by a controllable by the manual control unit 7 disconnection unit 30, which is arranged in the signal feedback 40 of the control circuit of the power supply device 5 designed as a switching power supply is or which is arranged on the control device 17, such that in the operating state "Enabled" at one of the terminals of the transmitter unit 14 is not applied to a high frequency switching signal.

LIST OF REFERENCE NUMBERS

1 Electromotive furniture drive

2 linear drive

 3 lifting tube

 4 clevis

 5 power supply device

6 engine control

 7 manual operation

 8 power plug

 9 supply cable

 10 input circuit

 1 1 DC link

 12 rectification

 13 switching module

 14 transformer unit

 15 secondary unit

 16 optocouplers

 16 'coupling unit

 17 control device

 18 Control supply

 19 Galvanic separation

 30 unlock unit

 32 control line

 40 signal feedback

 41 auxiliary voltage source

 200 power cable

 210 motor cables

Claims

Electromotive furniture drive (1) with a power supply device (5) and with a manual control (7) for adjusting movable furniture components relative to each other,

wherein the electromotive furniture drive (1) has at least one rotationally reversible electric motor, wherein each electric motor is followed by a speed reduction gear and wherein each speed reduction gear is followed by a further gear,

and wherein the energy supply device (5) has a network connection which is connectable to the network, wherein the energy supply device (5) transforms the line-side input voltage into a low-side output voltage, and an isolation transformer or a galvanic isolation transmission unit (19) between the the power supply device (5) is designed in the manner of a switching power supply and an intermediate circuit (1 1), a control device (17) for controlling the switching power supply, and the control device (17) a control supply (18) is assigned, wherein the power supply device (5) has an operating state "enabled" and an operating state "operation" in regular operation,

characterized,

in that the electrical control signal of the control line (32) can be changed by a switching contact of the manual control (7) such that the energy supply device (5) is not actuated State of the manual operation (7) has the operating state "Enabled".

Electromotive furniture drive (1) according to claim 1, characterized in that the enable unit (30) is connected to a signal feedback of a control circuit of the power supply device, wherein the enable unit (30) is integrated in a path of signal feedback, or that in or on an input path or an unlocking unit of the control device is used or attached to a disconnection unit. Electromotive furniture drive (1) according to claim 1 or 2, characterized in that the controllable disconnection unit (30) at a signal change of the control line connected to it (32) the signal feedback of the power supply device (5) changed such that via the control output of the control device (17 ) of the power supply device (5) between a Hochfrequenzschaltsignal in the operating state of the regular operation and a non-acting as a high-frequency signal, in the operating state "Enabled" can be switched.

4. Electromotive furniture drive (1) according to one of the preceding claims, characterized in that the control circuit of the power supply device (5) by the controllable disconnection unit (30) in the operating state "Enabled" is disabled, so that in the unused state of the electromotive furniture drive of Operating state "Enabled" sets itself automatically.

5. Electromotive furniture drive (1) according to any one of the preceding claims, characterized in that the disconnecting unit (30) is formed by a node or by a feed point, and that a netztebundene auxiliary power source in the form of a battery or a capacitor (41) with such Capacity is provided that in the non-actuated state of the manual control (7), a transistor switch or a contact of the manual control is switchable.

Electromotive furniture drive (1) according to one of the preceding claims, characterized in that the enable content (30) is formed by a node in the path of signal feedback, wherein the signal return (40) is designed as a relatively high-impedance control path and at the node a switching transistor or a contact of the manual switch button is attached.

Electromotive furniture drive (1) according to one of the preceding claims, characterized in that the disconnection unit (30) comprises a galvanic release agent in the form of a transmitting coupler and that the unlocking content (30) is designed as an optocoupler (16) or as a photovoltaic coupler.

8. Electromotive furniture drive (1) according to any one of the preceding claims, characterized in that the switching output of the optocoupler (16) is in operative connection with the signal feedback, and that the switching output of the optocoupler (16) used in an electrical series circuit in the path of signal feedback is, and that the unlock unit (30) is attached to or in the control device (17) or inserted therein.

9. Electromotive furniture drive (1) according to any one of the preceding claims, characterized in that the switching outputs of the optocoupler (16) or the switching outputs one of the switching output of

 Optocoupler (16) controlled transistor switch with power supply terminals of the control device is connected such that in the non-actuated state of the manual control (7) and / or in the operating state "Enabled" the power supply terminals of the control device (17) are interconnected.

10. Electromotive furniture drive (1) according to any one of the preceding claims, characterized in that the activation unit (30) is designed as a galvanic release agent and having a signal input which is connected to the control line (32).

1 1. Electromotive furniture drive (1) according to one of the preceding claims, characterized in that an auxiliary voltage source (41) in the form of a battery or a capacitor is provided with a relatively high capacity, wherein the auxiliary voltage source (41) to the secondary unit of the power supply device (5) and arranged charged in the operating state of the regular operation or is supplied with energy to maintain the charge.

12. Electromotive furniture drive (1) according to one of the preceding claims, characterized in that at least one button of the manual control (7) is associated with a normally closed contact, which lies in the circuit between the auxiliary voltage source (41) and the input of the enable unit (30).