DE102006023533B4 - Electric potentiometer - Google Patents

Abstract

Electrical potentiometer (1) with a support plate (6) carrying a resistance track (3), the free ends (9, 12) of the resistance track (3) being connected to the first and second potentiometer connections (15, 18), and with one Tapping contact (24) carrying, around an axis of rotation rotatable tap (27), which is connected to the third potentiometer connection (21), the resistor track (3) consisting of a resistor arrangement (4) of electrically connected, discrete resistor elements (30) with predetermined resistance values is formed, a device (36) being provided, with which the sliding contact (24) can be electrically connected along its movement path (B) to predeterminable parts (42) of the resistor arrangement (4) in the adjustment region of the tap, and the predeterminable parts (42 ) of the resistance arrangement (4) are the electrical connection points between the individual resistance elements (30), and wherein the device for electrical connection (36) of the sliding contact (24) with the predeterminable parts (42) of the resistance arrangement (4) between the electrical connection points of the resistance elements (30) and the path of movement (B) of the sliding contact (24) comprises contact fields (45), characterized in that the third Potentiometer connection (21) to the axis of rotation of the tap (27) is expanded to a conductor circuit which is concentrically surrounded by the contact fields (45).

Description

The invention relates to an electrical potentiometer according to the preamble of claim 1. A generic electrical potentiometer has three potentiometer connections and a carrier plate which carries a resistance track. The free ends of the resistance track are connected to the first and second potentiometer connections. Furthermore, a generic potentiometer has a tap which carries a sliding contact and is connected to the third potentiometer connection.

Generic electrical potentiometers are known in principle as adjustable resistors in the prior art. Their basic structure and use is described, for example, in the textbook "Ekbert Hering, Klaus Bressler, Electronics for Engineers, VDI Verlag Düsseldorf, 1992, Chapter 2.2.4".

For the production of generic electrical potentiometers, one or more resistance masses are applied to a carrier element according to the previously known methods. These resistance masses form a continuous resistance layer. For example, there are layers of carbon or layers of CERMET, layers of metal particles embedded in a ceramic or glass mass.

However, simple layer potentiometers are not very accurate. In the case of known potentiometers, the resistance layers are compared with a laser to increase the accuracy. The resistance layer serves. at the same time as a contact surface for the sliding contact, which forms the resistance tap.

Because of the required laser alignment, the previously known method is quite complex and inflexible. Known generic electrical potentiometers with high accuracy are therefore expensive.
The DE 26 49 251 shows a command transmitter for electrical positioning drives, which has a generic potentiometer according to the preamble of claim 1. The potentiometer comprises a resistance track and further contact elements, an extension of the third potentiometer connection and the further contact elements being contacted by a common wiper, which requires a complicated mechanical structure.
It is therefore the object of the present invention to provide a generic electrical potentiometer with high accuracy, which can be manufactured in a simple and inexpensive manner.
The object is achieved by a generic electrical potentiometer with the characterizing features of claim 1.
According to the invention, the resistance track is thus formed from an arrangement of electrically connected, discrete resistance elements with predetermined resistance values, and a device is provided with which the sliding contact can be electrically connected along the movement path with predeterminable parts of the resistance arrangement in the adjustment range of the tap.
The advantage of the new electrical potentiometer according to the invention lies in the fact that the discrete, that is to say isolated, resistance elements can be selected with predetermined resistance values of such accuracy classes that their electrically connected arrangement results overall in a potentiometer of the desired accuracy class. By selecting suitable tolerance classes for the individual resistance elements, the accuracy of the potentiometer can be determined and determined from the outset.
The resistance tapping via the sliding contact takes place similarly to the potentiometers known in the prior art. However, the change in the resistance value that occurs between the first or second and the third potentiometer connection when the sliding contact is moved along its path of movement is no longer continuous, as in the prior art. The resistance values change rather gradually. The amount of change from one stage to the next is predetermined by the resistance value between two contact points between two resistance elements.

Another advantage is that by varying the resistance values, different characteristics of the potentiometer, for example linear or non-linear or continuous or discontinuous, can be realized. The type of characteristic of the potentiometer can also be preselected by the type of connection of the individual resistance elements, for example by the type of network in which the individual resistance elements are connected, whether in series, or in parallel or a mixed series and parallel connection .

In a particularly advantageous embodiment, the arrangement is a series connection of resistance elements, and the predeterminable parts of the resistance arrangement, with which the sliding contact can be connected in the adjustment range of the tap along its path of movement, are the electrical connection points between the individual resistance elements. An electrical series connection is the simplest network and is therefore one of the preferred ways to build up an electrically connected arrangement of resistance elements according to the invention.

It is also very advantageous if the device for electrically connecting the sliding contact to the predeterminable parts of the resistance arrangement comprises contact fields which run between the electrical connection points of the resistance elements and the path of movement of the sliding contact. In this way, it is then possible to adapt the geometrical arrangement of the resistance elements connected in series on the carrier plate to the respective space conditions. The arrangement on the carrier plate is then not limited by the fact that the connection point between two resistors must lie in the region of the path of movement of the sliding contact.

The arrangement of electrically connected resistance elements can be attached on the side of the carrier plate opposite the sliding contact, so that the arrangement of electrically connected resistance elements and the sliding contact lie on different sides of the carrier plate. The advantage of such an arrangement is that a smaller and more compact design can be achieved.

According to another advantageous embodiment, the arrangement of electrically connected resistance elements can also be arranged on the same side of the carrier plate as the sliding contact. The advantage of such an arrangement is that the resistor arrangement is protected by the free back of the carrier plate.

The tap is advantageously rotatably mounted about an axis of rotation, so that the movement path of the sliding contact roughly describes an arc. This ensures a sufficiently long movement path of the tap with a small absolute space requirement.

An embodiment in which the carrier plate is a printed circuit board is particularly advantageous. The methods known from printed circuit board technology and from the technology of populating printed circuit boards and also machines for producing a potentiometer according to the invention can then be used

An embodiment in which the resistance elements SMD components and SMD technology are applied to the printed circuit board is particularly advantageous. SMD stands for "Surface Mount Device". As is well known, SMD technology has proven itself as an inexpensive method in printed circuit board manufacture for many years. The resistance components are designed in a special way, namely without connection wires, but instead with connection points containing solder material, directly at the ends of the resistance elements, for example cuboid or cylindrical.

When assembling in the circuit board, the SMD components are placed in their specified place and held there. In a subsequent automated soldering process, for example after the so-called wave soldering, liquid solder is then rinsed over the components. The solder connection is made at the connection points, and the liquid solder rolls off at all other points. Fitting and soldering can take place on fully automated machines.

Resistor components in an SMD-compatible embodiment are available in a wide range of variations and in many accuracy classes. Any resistor arrangements with a given accuracy can thus be implemented inexpensively in this way.

Another advantage of such an embodiment is that the contact fields, which form the connection points between each two resistance elements and the path of movement of the sliding contact, are designed as conductor tracks on the carrier plate. The production of such conductor tracks on a printed circuit board is one of the basic techniques in printed circuit board manufacture and is therefore also simple and inexpensive to implement.

To reduce the contact resistance and to minimize environmental influences, the contact surface of the sliding contact or the contact fields can be gold-plated in a further advantageous embodiment. This is particularly advantageous if it cannot be ruled out that moisture or dirt particles can reach the contact surface.

In a particularly simple and therefore advantageous embodiment of a potentiometer according to the invention, this comprises a potentiometer housing comprising a housing base and an upper housing part. The carrier plate can simultaneously form the housing base of the potentiometer housing with its functions as a carrier of the resistor arrangement and the movement path of the tap. This is particularly advantageous if the resistor arrangement and the tap are arranged on the same side of the carrier plate. Because then the back of the carrier plate is free of electrical components and can be fitted into the upper part of the housing so that it acts as a protective housing base.

The tap is advantageously attached to a contact carrier part which is rotatably mounted in the upper housing part about its axis of rotation. It is then accessible from the side of the upper housing part for an operator, with or without tools, to set the desired resistance.

The contact carrier part is advantageously sealed with a sealant, for example an O-ring, against the upper housing part. In this way, especially in combination with a sealing housing base, a dirt and moisture-proof housing of the potentiometer according to the invention can be achieved.

The sliding contact can advantageously comprise a metallic contact piece which is held in the contact carrier part and acts resiliently on the carrier plate. The resilient loading ensures a sufficient and constant contact pressure.

To further minimize the effects of dirt particles, the sliding contact can consist of several partial contacts connected in parallel. It can therefore be designed, for example, as a comb or brush.

The production of an electrical potentiometer according to the invention is very cost-effective, in particular if, according to a further preferred embodiment, the contact carrier part and the upper housing part are prefabricated injection molded parts. These can be manufactured consistently in large quantities and for different types of potentiometers. The distinction between the individual types of potentiometers is then determined solely by the dimensioning of the resistor arrangement.

In a particularly simple and therefore preferred embodiment, an electrical potentiometer according to the invention is composed of only five individual components. These are the components: upper housing part, contact carrier part, contact piece, sealant and carrier plate.

During assembly, the sealant is inserted into the contact carrier part in a first step. According to an advantageous embodiment described above, an O-ring is used as the sealing means in an annular groove of the contact carrier part which is adapted to this. In a second step, the contact carrier part is then inserted into a suitable recess in the upper housing part, so that the O-ring effects a seal between the inside of the upper housing part and the upper width of the contact carrier part. In a third step, the contact piece is then inserted into a corresponding recess on the underside of the contact carrier part. In a fourth step, the printed circuit board is then placed and fastened on the underside of the housing, which is still open known way.

The invention and further advantageous refinements and improvements of the invention are to be explained and described in more detail with reference to the drawings, in which two exemplary embodiments of the invention are shown.

• 1: einen Querschnitt (schematisch) durch ein erfindungsgemäßes Potentiometer,
• 2: eine Aufsicht (schematisch) auf ein erfindungsgemäßes Potentiometer, bei dem die Widerstandsanordnung und der Abgriff auf derselben Seite der Trägerplatte angeordnet sind,
• 3: einen Querschnitt (schematisch) durch ein erfindungsgemäßes Potentiometer, wobei die Trägerplatte gleichzeitig als Gehäuseboden dient,
• 4: einen Querschnitt (schematisch) durch ein erfindungsgemäßes Potentiometer, wobei zusätzlich zur Trägerplatte ein Gehäuseboden vorgesehen ist,
• 5: schematisch den Widerstandsverlauf eines erfindungsgemäßen Potentiometers gemäß 2 bis 4 in Abhängigkeit des Drehwinkels, sowie
• 6: einen Querschnitt (schematisch) durch ein erfindungsgemäßes Potentiometer, wobei die Trägerplatte mit einer Dicht- und Füllmasse mit dem Gehäuse verbunden ist

Show it:

• 1 a cross section (schematically) through a potentiometer according to the invention,
• 2nd FIG. 1 shows a top view (schematic) of a potentiometer according to the invention, in which the resistor arrangement and the tap are arranged on the same side of the carrier plate,
• 3rd a cross section (schematically) through a potentiometer according to the invention, the carrier plate also serving as the housing base,
• 4th a cross-section (schematically) through a potentiometer according to the invention, a housing base being provided in addition to the carrier plate,
• 5 : schematically the resistance curve of a potentiometer according to the invention 2nd to 4th depending on the angle of rotation, as well
• 6 a cross section (schematically) through a potentiometer according to the invention, the carrier plate being connected to the housing with a sealing and filling compound

The 1 shows an electrical potentiometer 1 with a first potentiometer connection 15 , a second potentiometer connection 18th and a third potentiometer connection 21 . On the underside of a carrier plate 6 is a resistor arrangement 4th of resistance elements 30th attached in the form of an electrical series connection. The resistance elements 30th are designed as SMD components. They each carry connection pieces at the ends of the cuboid resistance body 31 made of solder material.

From the connectors 31 each resistance element 30th lead electrically conductive bushings to the opposite side of the carrier plate 6 . There, the conductive bushings are each two adjacent resistance elements in an electrical connection point 42 electric connected. Thus, the electrical feedthroughs provide a device for electrically connecting parts of the resistor arrangement 3rd with the sliding contact within the adjustment range of the tap 27 This creates an electrical series connection of the resistance track 3rd between their first free end 9 and the second free end 12th .

The first free end 9 is also with a conductive bushing on the opposite side of the carrier plate with the first potentiometer connection 15 electrically connected, as is the second free end 12th through an electrical feedthrough with the second potentiometer connection 18th electrically connected.

With the third potentiometer connection 21 is a tap 27 connected, in a sliding contact 24th ends. The sliding contact 24th resiliently presses against the resistance track 3rd opposite side of the carrier plate 6 . The tap 27 and thus the sliding contact 24th can in the direction of the arrow P along its trajectory B parallel to the surface of the carrier plate 6 be moved. The resistance between a free end of the resistance track 3rd and the third potentiometer connection 21 is then set as the value resulting from the series connection of those resistance elements 30th results between the respective free end of the resistance track 3rd and that electrical connection point 42 lying through the sliding contact 24th is contacted.

The 2nd shows a plan view of a further embodiment of an electrical potentiometer according to the invention. The same or equivalent elements or functional groups have the same reference numerals as in the 1 . In the following, we should therefore only focus on the differences 1 To be received.

The resistance elements 30th that the resistor arrangement 4th in the form of an electrical series connection of the resistance elements 30th form, are in the embodiment of the 2nd on the same side of the carrier plate 6 attached like the tap 27 . They are circular in shape around the axis of rotation 62 of the contact carrier part 60 around on the top of the circuit board 6 upset. The contact carrier part 60 has a cylindrical shape, the tap 27 is approximately parallel to the surface of the circuit board 6 extending in the radial direction from this. It is about the axis of rotation 62 of the contact carrier part together with this by an angle of about 270 ° between the start and the end position. The third potentiometer connection 21 is as a trace on the side of the edges of the circuit board 6 led out. The third potentiometer connection extends towards the center 21 to the contact carrier part 60 ring-shaped surrounding circuit.

The start and end points of two adjacent resistance elements 30th are each in an electrical connection point by electrical conductor tracks 42 connected. The electrical connection point 42 are also circular around the axis of rotation 62 arranged around. From every electrical connection point 42 runs radially on the axis of rotation 62 indicative of a contact field 40 , formed as a longitudinally extending piece of rectangular conductor track.

At the bottom of the tap 27 , in the view 2nd covered by this is the sliding contact. This creates the electrical connection between the contact field 45 and the circular conductor track in extensions of the third potentiometer connection 21 .

The 5 shows schematically the course of the potentiometer resistance between the first or second and the third potentiometer connection, plotted on the ordinate in units of ohms, as a function of the angle of rotation of the contact carrier part 60 . One can clearly see the step-like course of the resistance, which arises when the sliding contact is moved from one contact field to the next. The resistance values of the individual resistance elements 30th are predefined in such a way that a logarithmic course of the resistance characteristic is established.

The 3rd shows a cross section through a further embodiment of an electrical potentiometer according to the invention. The same or equivalent elements or functional groups have the same reference numerals as in the 1 and 2nd . In the following, we should therefore only focus on the differences to the 1 and 2nd To be received.

The carrier plate 6 serves in the embodiment 3rd at the same time as the case back 51 from the upper part of the housing 54 and the case back 51 formed potentiometer housing 57 . The resistance elements 30th are as SMD components on the underside of the carrier plate 6 attached, according to the in 1 shown arrangement. The tap 27 on the opposite side of the carrier plate 6 is part of the contact carrier part 60 . The contact carrier part 60 has the shape of a cylindrical body 64 with an also cylindrical attachment placed in the middle 65 . The essay 65 is through a recess 61 in the upper part of the housing 54 performed and protrudes outwards from this. In the axis of rotation 62 of the contact carrier part 60 there is a notch, suitable for engaging a tool, for example a screwdriver.

At the top of the cylindrical body 64 is an O-ring inserted in an annular groove around the cylindrical body against the inside of the housing top 54 less know. On the opposite underside of the cylindrical body 64 there is a contact recess 28 , slightly eccentrically arranged. This serves to take up the sliding contact 24th . The sliding contact 24th has approximately the shape of a metallic V-shaped spreading spring which is spring-loaded in the opening direction.

At the free end of the sliding contact 24th this runs into a flattened contact piece 66 out. To improve the electrical contact is the contact piece 66 gold-plated. In addition, the contact field can also be used 45 be gilded.

Due to the resilient action on the sliding contact 24th in the opening direction on the one hand the contact carrier part 60 with the O-ring 63 against the inside of the upper housing part 54 pressed, on the other hand this creates the necessary contact pressure on the contact piece 66 . In this way, the contact carrier part 60 without additional aids in the potentiometer housing 57 held in the correct position. This makes the assembly of the potentiometer according to the invention in accordance with the embodiment 3rd very simple and inexpensive.

The 4th shows a variant of the embodiment according to 3rd . The same or equivalent elements or functional groups have the same reference numerals as in the 3rd . In the following, we should therefore only focus on the differences to the 3rd To be received.

In the embodiment according to 4th is in the potentiometer housing 57 through an additional case back 51 locked. The circuit board six is thus completely inside the potentiometer housing 57 introduced and optimally protected from dirt and moisture. The potentiometer connections are through the potentiometer housing 57 carried out and sealed in a suitable manner.

The 6 shows a cross section through a further embodiment of an electrical potentiometer according to the invention in which the protection against dirt, moisture and other environmental influences is realized in a different way. The same or equivalent elements or functional groups have the same reference numerals as in the previous ones 1 to 4th . In the following, therefore, essentially only the differences from the previous figures will be discussed.

The carrier plate 6 is in the embodiment of 6 a little bit into the upper part of the housing 54 introduced from its open side, so that between the one with the resistance elements 30th equipped side of the carrier plate 6 and the free edge of the upper housing part 54 a free volume remains. This free volume is with a potting compound 67 filled out. The potting compound fixes the carrier plate on the one hand 6 in the upper part of the housing 54 . On the other hand, it seals the interior of the potentiometer from the outside and serves to protect the resistance elements 30th and the rest of the inner space of the potentiometer against environmental influences, such as. B. dirt, moisture or mechanical impact.

Reference list

1

Potentiometer

3rd

Resistance track

4th

Resistor arrangement

6

Carrier plate

9

first free end of the resistance track

12th

second free end of the resistance track

15

first potentiometer connection

18th

second potentiometer connection

21

third potentiometer connection

24th

Sliding contact

27

Tap

28

Contact recess

31

Fittings

30th

Resistance element

36

Device for electrical connection

42

electrical connection point

45

Contact field

51

Case back

54

Upper part of the housing

57

Potentiometer housing

60

Contact carrier part

61

Recess

62

Axis of rotation

63

sealant

64

cylindrical body

65

Essay

66

Contact piece

67

Sealing compound

Claims (21)

Electrical potentiometer (1) with a support plate (6) carrying a resistance track (3), the free ends (9, 12) of the resistance track (3) being connected to the first and second potentiometer connections (15, 18), and with one Tapping contact (24) carrying, around an axis of rotation rotatable tap (27), which is connected to the third potentiometer connection (21), the resistor track (3) consisting of a resistor arrangement (4) of electrically connected, discrete resistor elements (30) with predetermined resistance values is formed, a device (36) being provided, with which the sliding contact (24) can be electrically connected along its movement path (B) to predeterminable parts (42) of the resistor arrangement (4) in the adjustment region of the tap, and the predeterminable parts (42 ) of the resistance arrangement (4) are the electrical connection points between the individual resistance elements (30), and wherein the device for electrical connection (36) of the sliding contact (24) with the predeterminable parts (42) of the resistance arrangement (4) between the electrical connection points of the resistance elements (30) and the path of movement (B) of the sliding contact (24) comprises contact fields (45), characterized in that the third Potentiometer connection (21) to the axis of rotation of the tap (27) is expanded to a conductor circuit which is concentrically surrounded by the contact fields (45). Electrical potentiometer (1) after Claim 1 , characterized in that the resistor arrangement (4) is a series connection of resistor elements (30). Electrical potentiometer (1) according to one of the preceding claims, characterized in that the resistance arrangement (4) of electrically connected resistance elements (30) and the sliding contact (24) lie on different sides of the carrier plate (6). Electric potentiometer (1) according to one of the Claims 1 to 2nd , characterized in that the resistance arrangement (4) of electrically connected resistance elements (30) and the sliding contact (24) lie on the same side of the carrier plate (6). Electrical potentiometer (1) according to one of the preceding claims, characterized in that the tap (27) is rotatably mounted about an axis of rotation, so that the movement path (B) of the sliding contact (24) describes approximately an arc. Electrical potentiometer (1) in according to one of the preceding claims, characterized in that the carrier plate (6) is a printed circuit board. Electrical potentiometer (1) after Claim 6 , characterized in that the resistance elements (30) SMD components and in SMD technology on the circuit board (6) are applied. Electrical potentiometer (1) according to one of the preceding claims, characterized in that the contact fields (45) are designed as conductor tracks on the carrier plate (6). Electrical potentiometer (1) according to one of the preceding claims, characterized in that the contact surface of the sliding contact (24) and / or the contact field (45) are gold-plated. Electrical potentiometer (1) according to one of the preceding claims, characterized in that different characteristics of the potentiometer (1) can be realized by varying the resistance values. Electrical potentiometer (1) according to one of the preceding claims, characterized in that the accuracy of the potentiometer (1) can be determined by selecting suitable tolerance classes for the resistance elements (30). Electrical potentiometer (1) according to one of the preceding claims, characterized in that the carrier plate (6) forms the housing base of the potentiometer housing (57) comprising a housing base (51) and an upper housing part (54). Electrical potentiometer (1) according to one of the preceding claims, characterized in that the carrier plate (6) on the open side of an upper housing part (54) is inserted into the upper housing part (54) and is potted on the outside with a potting compound (67). Electrical potentiometer (1) according to one of the preceding claims, characterized in that the tap (27) is attached to a contact carrier part (60) rotatably mounted in the upper housing part (54). Electrical potentiometer (1) according to one of the preceding claims, characterized in that the contact carrier part (60) is sealed with a sealing means (63) against the upper housing part (54). Electrical potentiometer (1) according to one of the preceding claims, characterized in that the sliding contact (24) comprises a metallic contact piece (66) held in the contact carrier part (60) and resiliently acting on the carrier plate (6). Electrical potentiometer (1) according to one of the preceding claims, characterized in that the contact carrier part (60) and the upper housing part (54) are prefabricated injection molded parts. Electrical potentiometer (1) according to one of the preceding claims, wherein the potentiometer (1) is composed of the five individual components housing upper part (54), contact carrier part (60), contact piece (66), sealant (63) and carrier plate (6). Electrical potentiometer (1) according to one of the preceding claims, characterized in that the distance between the individual segments of the contact field (45) is smaller than the width of the sliding contact (24). Electrical potentiometer (1) according to one of the preceding claims, characterized in that the sliding contact (24) consists of a plurality of partial contacts connected in parallel. Electrical potentiometer (1) after Claim 20 , characterized in that the sliding contact is designed as a comb or brush.

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