DE102006060011A1 - Voltage converter for operating light arrangement, has level that has capacitor recharged by input voltage in capacitor voltage, and formed in way that capacitor voltage is tapped at output of level as voltage - Google Patents

Abstract

The voltage converter (1) has a level (10) that has a capacitor (11) recharged by an input voltage (VIN) in a capacitor voltage (VK1), and formed in a way that a capacitor voltage is tapped at an output (3) of a level as a voltage (V1). Another level (20) has another capacitor (21) recharged by a voltage in a latter capacitor voltage (VK2) and formed in a way that the sum of former capacitor voltage and latter capacitor voltage is tapped as another voltage (V2) at an output (23) of the latter level. An independent claim is also included for a method for voltage conversion.

Description

The The present invention relates to a voltage converter and a Method for voltage conversion.

Voltage converter in English as Direct Current / Direct Current Converter, abbreviated DC / DC Converters, called, often serve a low to convert it into a higher voltage.

document DE 10 2005 012 662 A1 shows an arrangement with voltage converter for supplying power to a load with multiple capacitors.

task The present invention is a voltage converter and to provide a method of voltage conversion, comprising a enable the highest possible duplication of an input voltage.

These The object is with the subject of claim 1 and the method solved according to claim 13. further developments and embodiments are each subject of the dependent Claims.

According to the invention a voltage converter has a first and a second stage. The first. step has a first capacitor and an output. The second Stage includes a second capacitor and also an output.

Of the first capacitor is charged by means of an input voltage, such that a first capacitor voltage is applied to the first capacitor can be tapped. The output of the first stage is so with the First capacitor connected to at least the first capacitor voltage as a first voltage at the output of the first stage becomes. The second capacitor is charged by means of the first voltage, such that at the second capacitor a second capacitor voltage can be tapped. The second capacitor is connected to the output of the second Stage connected such that at least the sum of the first capacitor voltage and the second capacitor voltage as a second voltage the output of the second stage can be tapped.

With Advantage, the second voltage by means of the addition of the first and the second capacitor voltage having a high voltage value to be provided. When adding, the amounts of the the first and the second capacitor voltage added.

In In one embodiment, the first voltage is replaced by a Addition of the first capacitor voltage and the input voltage provided. Therefore, advantageously, the first voltage is approximately twice the input voltage. The second voltage can thus approximately according to this embodiment be three times the input voltage.

In In a further development, the second voltage is an addition of the first Capacitor voltage, the second capacitor voltage and the input voltage. Thus, the second voltage can reach at most four times the input voltage.

In In a further development, the voltage converter has a further stage on, which includes another capacitor and another output. Of the another capacitor is charged to another capacitor voltage. The charging is done by means of the voltage at the output of the previous one Stage is provided. Another tension at the further output of the further stage is at least the sum the capacitor voltage of the further stage and the capacitor voltages the upstream stages. In one embodiment the further output voltage of the further stage the addition of Capacitor voltages of the previous stages, the other capacitor voltage and the input voltage. Advantageously, thus, the further tension twice that at the output of the previous stage Be tension.

In In a further development, the voltage converter comprises a number L from further stages, where L is greater than or equal to 1 is.

In In one embodiment, the voltage converter has one Output connected to the output of the second stage. If the voltage converter includes another stage, the output can be the voltage converter with the further output of the further stage be connected.

Of the Voltage converter can be used to operate a lighting arrangement be used. The lighting arrangement has at least one light source which is connected to the output of the voltage converter. The lighting means may comprise a light emitting diode. This preferably has Bulb several LEDs on. The multiple light emitting diodes may preferably be connected in series.

In An embodiment comprises a semiconductor body the voltage converter. In one embodiment, at the semiconductor body of the first, the second and optionally the other capacitors can be coupled.

According to the invention a method of voltage conversion, the following steps: A first capacitor is converted to a first capacitor voltage using an input voltage charged. A second capacitor is used using the first Capacitor voltage charged to a second capacitor voltage. In this case, a first stage comprises the first capacitor and a second Stage the second capacitor. A second voltage is given due to an addition of at least the first capacitor voltage and the second capacitor voltage is generated.

With Advantage is the second voltage by a summation of the first and the second capacitor voltage recovered. This is the summation carried out such that the amounts of the first and be added to the second capacitor voltage.

In a continuation to charge the second capacitor adds the input voltage and the first capacitor voltage. Again, the voltage amounts are added.

In a further development is to summon the second voltage the input voltage and the first and the second capacitor voltage by adding the amounts of the three voltages.

The The invention will be described in more detail below explained in more detail with reference to FIGS. functional or equivalent components and circuit parts bear the same reference numerals. As far as circuit parts or Components in their function correspond to their description not repeated in each of the following figures.

1A and 1B show exemplary embodiments of a voltage converter according to the proposed principle,

2 B and 2 B show exemplary embodiments of a switch,

3A to 3D show exemplary embodiments of a method for voltage conversion according to the proposed principle,

4A and 4B show an alternative exemplary embodiment of a method according to the proposed principle and

5 to 7 show three further exemplary alternative embodiments of a method according to the proposed principle.

1A shows an exemplary embodiment of a voltage converter according to the proposed principle. The voltage converter comprises a first, a second, a third and a fourth stage 10 . 20 . 30 . 40 , Each of the four levels 10 . 20 . 30 . 40 each has a capacitor 11 . 21 . 31 . 41 on. The first stage 10 includes a first capacitor 11 , a first, a second and a third switch 14 . 15 . 16 as well as an entrance 12 and an exit 13 , The entrance 12 the first stage 10 is with an entrance 2 of the voltage converter 1 connected. The first switch 14 couples the entrance 12 the first stage 10 with a first electrode of the capacitor 11 , The second switch 15 couples the entrance 12 the first stage 10 with a second electrode of the first capacitor 11 , The third switch 16 couples the second electrode of the first capacitor 11 with a reference potential connection 8th , The exit 13 the first stage 10 is with the first electrode of the first capacitor 11 connected. The second stage 20 includes a second capacitor 21 , a fourth, a fifth and a sixth switch 24 . 25 . 26 as well as an entrance 22 and an exit 23 , The entrance 22 the second stage 20 is with the exit 13 the first stage 10 connected. The entrance 22 the second stage 20 is about the fourth switch 24 with a first electrode of the second capacitor 21 and the fifth switch 25 with a second electrode of the second capacitor 21 coupled. The second electrode of the second switch 21 is over the sixth switch 26 with the reference potential connection 8th coupled. The first electrode of the second capacitor 21 is with the exit 23 the second stage 20 connected.

The third stage 30 is according to the first and the second stage 10 . 20 constructed and includes a third capacitor 31 , a seventh, an eighth and a ninth switch 34 . 35 . 36 as well as an entrance 32 and an exit 33 , The entrance 32 the third stage 30 is with the exit 23 the second stage 20 connected. A first electrode of the third capacitor 31 is about the seventh switch 34 with the entrance 32 the third stage 30 coupled. The first electrode of the third capacitor 31 is with the exit 33 the third stage 30 connected. A second electrode of the third capacitor 31 is over the eighth switch 35 with the entrance 32 the third stage 30 coupled and via the ninth switch 36 with the reference potential connection 8th gekop pelt. The fourth stage 40 includes a fourth capacitor 41 and a tenth switch 44 as well as an entrance 42 and an exit 43 , The entrance 44 the fourth stage 40 is with the exit 33 the third stage 30 connected. The entrance 42 the fourth stage 40 is about the tenth switch 44 with a first electrode of the fourth capacitor 41 connected. A second electrode of the fourth capacitor 41 is with the Reference potential terminal 8th connected. The first electrode of the fourth capacitor 41 is with the exit 43 the fourth stage 40 connected. The exit 43 the fourth stage 40 is with the exit 3 of the voltage converter 1 connected to the one electrical load 4 connected.

The voltage converter 1 also includes a comparator 80 and a control circuit 85 , A first entrance 81 of the comparator 80 is with the exit 3 of the voltage converter 1 coupled. A second entrance 82 of the comparator 80 is via a voltage source 84 with the reference potential connection 8th connected. An exit 83 of the comparator 80 is to an input of the control circuit 85 connected. The control circuit 85 has ten outputs connected to the control inputs of the first to tenth switches 14 . 15 . 16 . 24 . 25 . 26 . 34 . 35 . 36 . 44 are connected.

The entrance 2 of the voltage converter 1 an input voltage VIN is supplied. At the exit 3 of the voltage converter 1 is an output voltage VOUT tapped. The method for generating the output voltage VOUT using the input voltage VIN is determined by means of the 3 to 7 described. The output voltage VOUT becomes the first input 81 of the comparator 80 fed. The voltage source 84 serves to provide a predefinable threshold voltage VTH, the second input 82 of the comparator 80 is forwarded. At the exit 83 of the comparator 80 is a voltage VCO tapped, the control circuit 85 is supplied. The threshold voltage VTH is a lower threshold voltage. Thus, the output voltage VOUT drops below the threshold voltage VTH, so the output voltage VCO of the comparator 80 the logical value zero. If, however, the output voltage VOUT is higher than the threshold voltage VTH, then the comparator 80 the output voltage VCO of the comparator with the logical value one ready. At a logic zero value of the output voltage VCO, the control circuit controls 85 the ten switches so that the output voltage VOUT increases. This can be done, for example, by increasing a clock frequency f at which the ten switches are switched. Alternatively, the output voltage VOUT may be increased by decreasing on-resistance of the ten switches. Alternatively, the method of operating the ten switches may be changed such that a multiplication factor M, which is the ratio of the output voltage VOUT to the input voltage VIN, is increased.

In an alternative embodiment, the voltage converter comprises 1 another comparator 90 which is at a first entrance 91 with the exit 3 of the voltage converter 1 is coupled. The second entrance 92 further comparator 90 a second threshold voltage VTH2 is provided which is an upper threshold voltage. An exit 93 further comparator 90 is with another input of the control circuit 85 connected. At a logical value 1 of the output voltage VCO2 of the other comparator 90 controls the control circuit 85 the ten switches of the voltage converter 1 such that the output voltage VOUT is reduced. This can be achieved either by a reduction of the clock frequency f, with which the ten switches are switched, or by a change of the method and thus a reduction of the multiplication factor M.

In an alternative embodiment, the voltage converter has an eleventh and a twelfth switch 37 . 38 on. The eleventh switch 37 couples the entrance 12 the first stage 10 with the second electrode of the third capacitor 31 , The twelfth switch 38 couples the entrance 22 the second stage with the second electrode of the third capacitor 31 ,

In an alternative embodiment, the voltage converter 1 at least a fifth stage for increasing the multiplication factor M on. The fifth level is according to the first level 10 built and between the third and the fourth stage 30 . 40 arranged. Further stages can be arranged in the same way.

1B shows an exemplary embodiment of a voltage converter according to the proposed principle, which is a development of the voltage converter according to 1A is. At the exit 3 of the voltage converter 1 is an electrical load 4 connected, which four LEDs 100 to 103 includes. The four light-emitting diodes 100 to 103 are connected in series with each other. The four light-emitting diodes 100 to 103 are between the exit 3 of the voltage converter 1 and a power source 5 connected. A node between the power source 5 and the four LEDs 100 to 103 is with the first entrance 81 of the comparator 80 connected. Another connection of the power source 5 is connected to the reference potential connection 8th connected.

With the power source 5 becomes one through the four light emitting diodes 100 to 103 flying load current IL limited. Indicates the output voltage VOUT of the voltage converter 1 a high value, so falls a part of the output voltage VOUT across the four LEDs 100 to 103 and another part, namely the sag voltage VSINK, across the power source 5 from. The comparator 80 will be at his second entrance 82 a lower threshold voltage VTH supplied. Falls the sinking voltage VSINK below the threshold voltage VTH, so controls the control circuit 85 the switches of the voltage converter 1 such that the output voltage VOUT of the voltage converter 1 is increased.

2A shows an exemplary embodiment of a switch, as it embodiment of one or more of the ten switches in the voltage converter 1 according to the 1A and 1B can be used. The switch according to 2A includes the switching element 110 and a resistance 111 , which are connected in series with each other. The resistance 111 is designed as a controllable resistor. For controlling the resistance 111 includes the voltage converter 1 an amplifier 112 which connects to a first input to the output 3 of the voltage converter 1 and to a second input with a voltage source 113 is coupled to specify a threshold voltage VTH. The amplifier is realized as an operational amplifier. Advantageously, by means of a switch, which has an adjustable resistance, the multiplication factor M of the voltage converter 1 set to a value between two integers. The advantage is therefore a finer adjustment of the output voltage VOUT and a reduction of noise at the input 2 of the voltage converter 1 possible.

2 B shows another exemplary embodiment of a switch, which in the voltage converter 1 according to the 1A and 1B can be used and a development of the switch according to 2A represents. The switch according to 2 B includes a metal oxide semiconductor field effect transistor 115 , abbreviated MOSFET 115 , A control terminal of the MOSFET 115 is with an output of the control circuit 85 coupled. The control circuit 85 can be a gate voltage VGS for the MOSFET 115 provide the MOSFET 115 either placed in a very good conductive state or in a blocking state. In a preferred embodiment, the control circuit 85 deliver a gate voltage VGS, which is the mosfet 115 in an operating state, which is between the very good conductive operating state and the blocking operating state. Thus, the control circuit 85 a resistance of the MOSFET 115 and thus finely adjust the output voltage VOUT. Due to the finite resistance of the MOSFET 115 is achieved with advantage that the switching pulses of the voltage converter 1 are reduced, because in the voltage converter 1 occurring currents are reduced during a switching operation. Advantageously, thereby the output voltage VOUT and the input voltage VIN less switching noise.

3A to 3D show an exemplary embodiment of a method for voltage conversion, which with the voltage converter 1 according to 1A and 1B can be realized. For clarity, the switches of the voltage converter 1 omitted. 3A shows a phase A of the voltage conversion. The second electrodes of the four capacitors 11 . 21 . 31 . 41 are connected to the reference potential connection 8th connected. The first capacitor 11 the first stage 10 is charged to the input voltage VIN.

The first capacitor voltage VK1 is thus equal to the input voltage VIN. The first electrode of the fourth capacitor is connected to the output 3 of the voltage converter 1 connected to provide the output voltage VOUT. 3B shows a phase B of the process which follows phase A. According to phase B, the second electrode of the first capacitor 11 with the entrance 2 of the voltage converter 1 connected. Since the first capacitor voltage VK1 has the value of the input voltage VIN, is thus at the output 13 the first stage 10 as the first voltage V1 to twice the input voltage VIN. With the help of the first voltage V1, the second capacitor 21 charged. The second capacitor voltage VK2 can thus be up to twice the input voltage VIN. 3C shows a phase C of the process which follows phase B. After charging the second capacitor 21 to the second capacitor voltage VK2 is the second electrode of the second capacitor 21 with the first electrode of the first capacitor 11 connected. This is at the exit 23 the second stage 20 the sum of the first capacitor voltage VK1, the second capacitor voltage VK2 and the input voltage VIN as a second voltage V2. The value of the second voltage V2 can thus reach at most four times the input voltage VIN. With the second voltage V2 becomes the third capacitor 31 charged. 3D shows a phase D of the process which follows phase C. Phase D is again followed by phase A, so that the sequence repeats periodically. After charging the third capacitor 31 to the third capacitor voltage VK3, which may be up to four times the input voltage VIN, becomes the second electrode of the third capacitor 31 from the reference potential connection 8th separated and with the first electrode of the second capacitor 21 connected. At the exit 33 the third stage 30 is thus as a third voltage V3, the addition of the third capacitor voltage VK3, the second capacitor voltage VK2, the first capacitor voltage VK1 and the input voltage VIN. With the third voltage V3 becomes the fourth capacitor 41 the fourth stage 40 charged. The maximum value of the output voltage VOUT, namely eight times the input voltage VIN, can be repeated after repeating phases A through D several times in accordance with FIG 3A to 3D can be achieved with a frequency f. The multiplication factor thus has the value 8. Advantageously, therefore, a doubling of the voltage which can be tapped off at the output of the previous stage can be achieved with each stage. The maximum value of the multiplication factor M can be determined from the number N of stages with the following equation: M = 2 N . where M is the multiplication factor and N is the number of stages having a capacitor that is switched at both electrodes. The number N of stages is 3 in the voltage converter 1 according to 1A and 1B ,

4A and 4B show an alternative embodiment of the method for voltage conversion. In the method according to 4A and 4B become the phases A and B as in the 3A and 3B carried out. 4A thus shows an alternative embodiment C 'of the phase C. According to the alternative phase C' is for charging the third capacitor 31 to the third capacitor voltage VK3, the first electrode of the third capacitor 31 with the exit 23 the second stage 20 and thus with the first electrode of the second capacitor 21 and the second electrode of the third capacitor 31 with the entrance 2 connected. The third capacitor voltage VK3 is thus the sum of the first and second capacitor voltage VK1, VK2 and can be up to three times the input voltage VIN. 4B shows an alternative phase D '. In the alternative phase D 'is the output 33 the third stage 30 with the first electrode of the fourth capacitor 41 connected. The second electrode of the third capacitor 31 is with the exit 23 the second stage 20 connected. The fourth capacitor 41 is thus charged to the addition of the three capacitor voltages VK1, VK2, VK3 plus the input voltage VIN. The output voltage VOUT can thus amount to a maximum of seven times the input voltage VIN, so that the multiplication factor M is equal to 7.

5 shows an alternative embodiment of the phase D, namely a phase D '' The phases A, B, C are according to the method, which in the 3A to 3C is shown performed. According to the alternative phase D ", the third voltage V3 is generated by adding the input voltage VIN, the first capacitor voltage VK1 and the third capacitor voltage VK3. Since the third capacitor voltage VK3 according to the 3A to 3C can be four times the input voltage VIN, is at the output 33 the third stage 30 six times the input voltage VIN can be tapped off. Thus, the fourth capacitor becomes 41 charged to six times the input voltage VIN. The multiplication factor M thus has the value six.

6 shows an alternative embodiment of the method for voltage conversion. According to the alternative method, the phases A, B and C are as in 3A to 3C shown performed. 6 shows an alternative embodiment of the phase D, namely a phase D '''. According to the method according to 6 the third voltage V3 is formed from the addition of the input voltage VIN and the third capacitor voltage VK3. Since the third capacitor voltage VK3 can be up to four times the input voltage VIN, after the addition with the input voltage VIN, it is five times the input voltage VIN at the output 33 the third stage 30 can be tapped, so that the multiplication factor M has the value 5.

In an alternative, not shown embodiment used as the third voltage V3, the third capacitor voltage VK3. Thus, the input voltage VIN does not become the third capacitor voltage VK3 in the generation of the third voltage V3 added thereto. Of the Multiplication factor M is thus four.

7 shows an alternative embodiment of the method for voltage conversion. Phase A and Phase B are performed according to 3A and 3B carried out. In an alternative phase C '''are the third and the fourth capacitor 31 . 41 connected in parallel. As the second voltage V2, the addition of the second capacitor voltage VK2 and the input voltage VIN is provided. The second voltage V2 is thus up to three times the input voltage VIN. With this second voltage V2 becomes the third and the fourth capacitor 31 . 41 charged. The multiplication factor M is thus three.

In an alternative embodiment, not shown, the multiplication factor M is generated equal to two. For this purpose, the phase A and phase B as in the 3A and 3B shown performed. The second capacitor voltage VK2 is thus up to twice the input voltage VIN. The second capacitor voltage VK2 is applied as a second voltage V2 at the output 23 the second stage 20 provided and serves to charge the third and the fourth capacitor 31 . 41 , The multiplication factor M thus has the value 2.

In all methods, after completion of the last phase shown, the phase A is again in accordance with 3A started, followed by the phase B according to 3B follows. The phases are traversed periodically at the frequency f. Through the different Procedures can be with a voltage converter 1 different multiplication factors M are set.

The 1 to 7 show a voltage converter with four stages. The methods shown can also be used in a corresponding manner in voltage converters with two, three, five or more stages.

1

voltage converter

2

entrance

3

output

4

electrical load

5

power source

8th

Reference potential terminal

10

first step

11

first capacitor

12

entrance

13

output

14

first switch

15

second switch

16

third switch

20

second step

21

second capacitor

22

entrance

23

output

24

fourth switch

25

fifth switch

26

sixth switch

30

third step

31

third capacitor

32

entrance

33

output

34

seventh switch

35

eight switch

36

ninth switch

37

eleventh switch

38

twelfth switch

40

fourth step

41

fourth capacitor

42

entrance

43

output

44

tenth switch

80

comparator

81

first entrance

82

second entrance

83

output

84

voltage source

85

control circuit

90

Another comparator

91

first entrance

92

second entrance

93

output

94

voltage source

100-103

led

110

switching element

111

resistance

112

amplifier

113

voltage source

115

MOSFET

f

frequency

IL

load current

M

multiplication factor

V1

first tension

V2

second tension

V3

third tension

V4

fourth tension

CC1

first capacitor voltage

CC2

second capacitor voltage

CC3

third capacitor voltage

VK4

fourth capacitor voltage

VGS

gate voltage

VIN

input voltage

VOUT

output voltage

VSINK

reduce tension

VTH

threshold voltage

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - DE 102005012662 A1 [0003]

Claims (15)

Voltage converter, comprising - a first stage ( 10 ), which has a first capacitor ( 11 ), which can be charged by means of an input voltage (VIN) to a first capacitor voltage (VK1), and is designed such that at an output ( 13 ) of the first stage ( 10 ) at least the first capacitor voltage (VK1) as a first voltage (V1) can be tapped, and - a second stage ( 20 ), which has a second capacitor ( 21 ), which is chargeable by means of the first voltage (V1) to a second capacitor voltage (VK2), and is designed such that at an output ( 23 ) of the second stage ( 20 ) at least the sum of the first capacitor voltage (VK1) and the second capacitor voltage (VK2) as a second voltage (V2) can be tapped. Voltage converter according to claim 1, wherein at the output ( 13 ) of the first stage ( 10 ) the sum of the first capacitor voltage (VK1) and the input voltage (VIN) can be tapped off as the first voltage (V1) and at the output ( 23 ) of the second stage ( 20 ) the sum of the first capacitor voltage (VK1), the second capacitor voltage (VK2) and the input voltage (VIN) can be tapped off as the second voltage (V2). Voltage converter according to claim 1 or 2, comprising at least one further stage ( 30 ), the at least one further capacitor ( 31 ), by means of the voltage (V2), which at the output ( 23 ) of the upstream stage ( 20 ) can be tapped off, at least one further capacitor voltage (VK3) is chargeable, comprises and is designed such that at an output ( 33 ) of the at least one further stage ( 30 ) at least the sum of the capacitor voltages (VK1, VK2) of the upstream stages ( 10 . 20 ) and the at least one further capacitor voltage (VK3) can be tapped off as at least one further voltage (V3). Voltage converter according to claim 3, wherein at the output ( 33 ) of the at least one further stage ( 30 ) the sum of the input voltage (VIN) and the capacitor voltages (VK1, VK2) of the preceding stages ( 10 . 20 ) and the at least one further capacitor voltage (VK3) can be tapped off as the further voltage (V3). Voltage converter according to one of claims 1 to 4, wherein the first stage ( 10 ) - an entrance ( 12 ), with an entrance ( 2 ) of the voltage converter ( 1 ), to which the input voltage (VIN) is fed, - the first capacitor ( 11 ), - a first switch ( 14 ), the entrance ( 12 ) of the first stage ( 10 ) with a first electrode of the first capacitor ( 11 ). couples, - a second switch ( 15 ), the entrance ( 12 ) of the first stage ( 10 ) with a second electrode of the first capacitor ( 11 ), - a third switch ( 16 ), the second electrode of the first capacitor ( 11 ) with a reference potential connection ( 8th ), and - the output ( 13 ) connected to the first electrode of the first capacitor ( 11 ). Voltage converter according to one of claims 1 to 5, wherein the second stage ( 20 ) - an entrance ( 22 ) connected to the output ( 13 ) of the first stage ( 10 ), - the second capacitor ( 21 ), - a fourth switch ( 24 ), the entrance ( 21 ) of the second stage ( 20 ) with a first electrode of the second capacitor ( 21 ), - a fifth switch ( 25 ), the entrance ( 21 ) of the second stage ( 20 ) with a second electrode of the second capacitor ( 21 ), - a sixth switch ( 26 ), the second electrode of the second capacitor ( 21 ) with a reference potential connection ( 8th ), and - the output ( 23 ) connected to the first electrode of the second capacitor ( 21 ) and with an output ( 3 ) of the voltage converter ( 1 ) is coupled. Voltage converter according to claim 6, when appended to claim 3, wherein the at least one further stage ( 30 ) - an entrance ( 32 ) connected to the output ( 23 ) of the upstream stage ( 20 ), - the at least one further capacitor ( 31 ), - a first further switch ( 34 ), the entrance ( 31 ) of the at least one further stage ( 30 ) with a first electrode of the at least one further capacitor ( 31 ), - a second further switch ( 35 ), the entrance ( 31 ) of the at least one further stage ( 30 ) with a second electrode of the at least one further capacitor ( 31 ), - a third further switch ( 36 ), the second electrode of the at least one further capacitor ( 31 ) with a reference potential connection ( 8th ), and - the output ( 33 ) connected to the first electrode of the at least one further capacitor ( 31 ) and with an output ( 3 ) of the voltage converter ( 1 ) is coupled. Voltage converter according to one of claims 1 to 7, comprising - a comparator ( 80 ) located at a first entrance ( 81 ) with an output ( 3 ) of the voltage converters ( 1 ) and at a second input ( 82 ) a predefinable threshold voltage (VTH) can be supplied, and - a control circuit ( 85 ), the input side with an output ( 83 ) of the comparator ( 80 ) and the output side with the control terminals of the switches of the stages ( 10 . 20 . 30 ) of the voltage converter ( 1 ) is coupled. Voltage converter according to claim 8, comprising a current source ( 5 ) between the first entrance ( 81 ) of the comparator ( 80 ) and the output ( 3 ) of the voltage converter ( 1 ) or between the first entrance ( 81 ) of the comparator ( 80 ) and a reference potential terminal ( 8th ) is switched. Voltage converter according to one of claims 5 to 9, wherein the switches of the stages ( 10 . 20 . 30 ) of the voltage converter ( 1 ) are realized as field effect transistors. Voltage converter according to one of claims 5 to 10, wherein a resistance value of at least one of the switches of the stages ( 10 . 20 . 30 ) of the voltage converter ( 1 ) is adjustable. Use of a voltage converter according to one of Claims 1 to 11 for operating a lighting arrangement, comprising at least one light-emitting means connected to the output ( 3 ) of the voltage converter ( 1 ) connected is. Method for voltage conversion, comprising - charging a first capacitor ( 11 ), which from a first stage ( 10 ) by means of an input voltage (VIN) to a first capacitor voltage (VK1), - charging a second capacitor ( 21 ), which from a second stage ( 20 ), to a second capacitor voltage (VK2) by means of at least the first capacitor voltage (VK1) and - providing a second voltage (V2) by adding at least the first capacitor voltage (VK1) and the second capacitor voltage (VK2). The method of claim 13, wherein the charging of the second capacitor ( 21 ) to the second capacitor voltage (VK2) comprises an addition of the input voltage (VIN) and the first capacitor voltage (VK1). The method of claim 13 or 14, wherein providing the second voltage (V2) is an addition of the input voltage (VIN), the first capacitor voltage (VK1) and the second capacitor voltage (VK2).