DE102007011815B4 - Electronic switching system - Google Patents

Abstract

Electronic switching system for carrying out automated test series with at least one electrically switched switch (101, 102, 103, 104, 105, 106), wherein the switching position of the at least one switch is determined by at least one display device (111, 121, 131, 141, 151, 161) is shown, and wherein the display device is designed so that the switching positions of different types of switches can be displayed differently.

Description

The invention relates to a switching system for carrying out automated metrological test series with one or more electrically switched switches and display devices.

The state of the art is here for example on the utility model DE 90 12 480 U1 directed. In this an electrical circuit arrangement is described, which serves to control large numbers of electrical loads in buildings. The switching position of the individual on / off switches is indicated at a central point by means of LEDs.

The DE 197 14 315 A1 deals with an electronic switching system for performing automated test series with at least one electrically switched switch (relay), wherein the switching position of the at least one switch (relay) by means of at least one display device (screen, PC) is shown.

The DE 31 04 384 A1 shows a mechanical or electronic switching position indicator on rotary switches.

The US 2003/0019733 A1 describes a switching position indication with the help of LEDs.

So far it has been common in automated test equipment to electrically energize the switches and not receive any form of feedback regarding the current switch position. In this arrangement, the switch position is determined with great effort in the event of an error for diagnosis or test program creation on the basis of the current via the switch terminals signals.

The invention has for its object to provide an electronic switching system for performing automated metrological test series with electrically switchable switches that allows direct readability of the switch positions without great technical effort.

The object is solved by the features of claim 1. The subclaims relate to advantageous developments of the invention.

The invention is based on the concept to visually represent the switching position of each switch in switching systems for carrying out automated test series with electrically switched switches. The arrangement of display devices, the switching position of the respective switch is shown. Depending on the type of switch used, the representation takes place in different ways.

If an intuitively detectable graphic representation of the switch connections and the switching state is available for the switch type, then such a representation is preferably used. If such a representation is not possible due to the complicated geometry of the switch terminals or other reasons, the switching position is preferably expressed numerically. For example, a graphic representation of the switch connections and switch positions is easily available for changeover switches and transfer switches. The switching position of rotary switches can not be represented by a graphic symbol on a spatially limited display, in particular with rotary switches with many poles. Thus, a numerical symbol for coding the respective switching state is preferably selected instead. The display preferably takes place on a universal pixel matrix, which is e.g. can be designed as an LCD or LED display. The display is driven by a controller which is in communication with a nonvolatile memory.

In addition to the switching states, status information such as the remaining life of the switches and potential fault conditions can be displayed on the display devices. These data are detected by the control device and stored as necessary in the memory or read from this.

The control of the switch is preferably carried out via an accessing to a bus system interface. A signal sent via the bus system is interpreted by the interface and converted into a switch position. The interface controls the switches by direct loading of the switches with control signals. The control device is also connected to the interface and thus to the bus system. Each switching change is detected by the control device and stored in the memory. Upon reaching various thresholds of duty cycles relative to the total life of the switches, a specific icon is output on the display devices. In addition, a representation of transmitted directly over the bus symbols on the display devices is possible. In this way error states of different components can be displayed. This design allows easy reading of the switching position of the switches and also provides status information such as the remaining life and error messages. This avoids costly outages and simplifies repairs. The requirements for the knowledge of the operating personnel are reduced by the inventive switching system.

• 1 ein Ausführungsbeispiel eines erfindungsgemässen Schaltsystems mit einer Anordnung mehrer Schalter in einem Gerät;
• 2 einen beispielhaften Aufbau einer Steckkarte des Ausführungsbeispiels des erfindungsgemässen Schaltsystems;
• 3 eine beispielhafte, nicht angesteuerte Anzeigeeinrichtung in LED Bauweise;
• 4 eine beispielhafte, zur Darstellung eines numerischen Symbols angesteuerte Anzeigeeinrichtung in LED Bauweise;
• 5 eine beispielhafte, zur Darstellung eines ersten grafischen Symbols angesteuerte Anzeigeeinrichtung in LED Bauweise;
• 6 eine beispielhafte, zur Darstellung eines zweiten grafischen Symbols angesteuerte Anzeigeeinrichtung in LED Bauweise;
• 7 eine beispielhafte, zur Darstellung eines dritten grafischen Symbols angesteuerte Anzeigeeinrichtung in LED Bauweise;
• 8 eine beispielhafte, zur Darstellung eines vierten grafischen Symbols angesteuerte Anzeigeeinrichtung in LED Bauweise;
• 9 eine beispielhafte, zur Darstellung eines numerischen Symbols angesteuerte Anzeigeeinrichtung in LED Bauweise;
• 10 eine beispielhafte, zur Darstellung mehrerer numerischer Symbole angesteuerte Anzeigeeinrichtung in LED Bauweise und
• 11 eine beispielhafte, zur Darstellung eines numerischen Symbols angesteuerte Anzeigeeinrichtung in LCD Bauweise.

Embodiments of the invention are described below with reference to the drawings. In the drawing show:

• 1 an embodiment of a novel switching system with a plurality of switches in a device;
• 2 an exemplary construction of a plug-in card of the embodiment of the inventive switching system;
• 3 an exemplary, non-driven display device in LED construction;
• 4 an exemplary, driven to display a numerical symbol LED display device;
• 5 an exemplary, driven to display a first graphical symbol display device in LED construction;
• 6 an exemplary, driven to display a second graphical symbol LED display device;
• 7 an exemplary, driven to display a third graphical symbol display device in LED construction;
• 8th an exemplary, driven to display a fourth graphical symbol LED display device;
• 9 an exemplary, driven to display a numerical symbol LED display device;
• 10 an exemplary, driven to display a plurality of numerical symbols display device in LED construction and
• 11 an exemplary, driven to display a numeric symbol display device in LCD design.

First, the structure and operation of the inventive switching system based on the 1 and 2 described before using the 3 to 11 possible symbol representations are explained. Identical elements have not been repeatedly shown and described in similar figures.

1 shows the front view of an inventive switching system for the automated execution of test series. Various types of switches are shown, with each switch associated with a display. A 7-pin rotary switch 101 is by a display device 111 represents. A 6-pole rotary switch 102 is by a display device 121 represents. A 5-pole rotary switch 103 is by a display device 131 represents. A 4-pole rotary switch 104 is by a display device 141 represents. Six changeover switches 105 be through a display device 151 represents. Two 4-pin transfer switches 106 be through a display device 161 represents.

For high frequency applications, the switches have a defined characteristic impedance of e.g. 50 ohms and are e.g. designed as a coaxial switch.

The different switches 101 . 102 . 103 . 104 . 105 . 106 and display devices 111 . 121 . 131 . 141 . 151 . 161 are each on a front panel 108 assembled. These front panels 108 be through fasteners 107 fixed. The six switching positions of the 7-pole rotary switch 101 be through the numerical symbols 1 to 6 displayed on the display device. A graphical representation of this switch with 6 switching states by a radial display with spoke as in 7 would be difficult to read here, as would be given to a large spatial proximity of the individual switching positions on the display device. The five switching positions of the 6-pole rotary switch 102 are therefore represented by the numerical symbols 1 to 5 displayed on the display device. The four switching positions of the 5-pole rotary switch 103 be through the numerical symbols 1 to 4 displayed on the display device. The three switching positions of the 4-pole rotary switch 104 be through the numerical symbols 1 to 3 displayed on the display device.

Although for the rotary switches with 4 to 6 poles also have a graphic representation, as in 7 and 8th would be possible, a numerical display was selected in this embodiment because of the uniformity of the display of the various rotary switches. The two switching positions of the six changeover switches 105 are represented by a graphic symbol like in 6 shown. The two switching states of each of the two 4-pole transfer switches 106 are represented by a graphic symbol like in 5 shown.

The switching positions of all switches can be read intuitively without training time by qualified personnel. No elaborate check of the switching state is required for troubleshooting the test setup.

2 shows the exemplary structure of a single inventive plug-in card. An electrically switched switch 201 is on a driver card 204 mounted, which by the fastening devices 107 on a front panel 209 is held attached. On the front panel are also the display device 208 and the switch terminals 210 appropriate. On the drive plug-in card 204 are still the control device 202 and, via connection line 214 associated with it, the non-volatile memory 216 assembled. In addition, the control device 202 via connection line 212 with the display device 208 connected. The drive plug-in card 204 is connected to an interface card 205 , which with a bus connector 206 over a connecting line 215 Tied to the bus. On the interface card 205 is the bus interface 203 mounted, which via connecting line 213 with the control device 202 communicates and via connection line 211 the electrically switched switch 201 controls.

Drive signals are sent from the bus via the bus connector 206 , Connecting line 215 through the bus interface 203 received and converted into control signals. These are over the connecting line 211 to the electrically switched switch 201 transferred, whereupon this reacts with a switching operation. At the same time, the information about the switching process via the connecting line 213 and the controller 202 transfer. This reads over the connection line 214 from the non-volatile memory 216 the current number of shifts, adjusts them according to the new shift, and writes the updated value back to the nonvolatile memory 216 , This ensures that the exact number of switching operations made at each switch is recorded for each switch.

If a predetermined value of the switching operations for the individual switch is reached, the control device controls 202 the display device 208 such that a special symbol as in 10 is displayed as a life indicator. Is from the bus via the bus connector 206 and the bus interface 203 a fault to the controller 202 reported, this controls the display device 208 such that a symbol specifying the error, for example, "E" as in 9 , is pictured. If there is no fault and no life indicator, the control device controls 202 the display device 208 such that the respective current switching state is displayed.

The switching operations of the electrically connected switches are preferably carried out by relays which are installed in the switches.

3 shows an exemplary display device which does not represent a symbol. The display device is made of pixels 301 composed. The column counter 302 shows the number of pixel columns. The line counter 303 shows the number of pixel lines.

4 shows an exemplary display device, which represents a numerical symbol. The activated LED pixels result in switching position "3" 401.

5 shows an exemplary display device, which represents a first graphical symbol. The controlled LED pixels result in the switch position "horizontal transfer" 501 and the switch position "vertical transfer" 502 for a transfer switch. The horizontal bars of the upper symbol represent a horizontal interconnection of the contacts of the upper switch. The vertical bars of the lower, clearly separated icon represent the vertical interconnection of the contacts of the lower switch.

6 shows an exemplary display device, which represents a second graphical symbol. The controlled LED pixels result in the switching position "left" 601 and the switching position "right" 602 for six switches integrated into one switch. Each individual line of the display indicates the switching position of a single switch. If the bar is moved from the center position to the left, the switch is in the "left" position. If from the middle position the bar continues to the right, then the switch is in the position "right".

7 shows an exemplary display device, which represents a third graphical symbol. The driven LED pixels result in the switch position "left-up" 701 for a three-pole rotary switch. The center contact is represented by the central pixel. The direction of the illustrated spoke indicates the second currently active contact of the switch.

8th shows an exemplary display device, which represents a fourth graphical symbol. The controlled LED pixels result in the switch position "right-down" 801 for a three-pole rotary switch. The center contact is represented by the central pixel. The direction of the illustrated spoke indicates the second currently active contact of the switch.

9 shows an exemplary display device which represents another numeric symbol. The driven LED pixels give an error indication "E" 901.

10 shows an exemplary display device, which represents another numeric symbol. The controlled LED pixels indicate the remaining life with a two-part symbol. A lifetime symbol "L" 1001 and a remaining lifetime indication "2" 1002 are combined to "L2".

11 shows an exemplary display device, which represents a numerical symbol. The driven LCD pixels yield switching position "3" 1101.

The invention is not limited to the illustrated embodiments. Thus, other display devices such as e.g. an electroluminescent display, or other switching elements, e.g. a stripline switch, are used. All described and / or drawn elements can be combined with one another in the context of the invention as desired.

Claims (12)

Electronic switching system for carrying out automated test series with at least one electrically switched switch (101, 102, 103, 104, 105, 106), wherein the switching position of the at least one switch is determined by at least one display device (111, 121, 131, 141, 151, 161) is shown, and wherein the display device is designed so that the switching positions of different types of switches can be displayed differently. Electronic switching system according to Claim 1 , characterized in that the displayable switch types include rotary switches (101, 102, 103, 104), transfer switches (106) and / or changeover switches (105). Electronic switching system according to Claim 1 or 2 , characterized in that the display of the switching position by means of graphic (501, 502, 601, 602, 701, 801) and / or numeric (401, 901, 1001, 1101) symbols is that the representation of the graphic symbols of the position of the switch terminals and the switching position of the respective switch corresponds, and that the numerical symbols directly represent the switching position of the respective switch. Electronic switching system according to one of Claims 1 to 3 , characterized in that the display devices are designed as universal pixel arrays. Electronic switching system according to Claim 4 , characterized in that the universal pixel matrices as LED displays (301, 401, 501, 601, 701, 801, 901, 1001) and / or as liquid crystal displays (1101) are formed. Electronic switching system according to one of Claims 1 to 5 , characterized in that the control of the switch is effected by means of a bus system, and that the conversion of the bus signals into the signals acting on the switch is effected by an interface (203). Electronic switching system according to Claim 6 Characterized in that the switches and indicators on a plug-in card (204) are mounted, and that the interface on a plug-in card is mounted (205), wherein the switch and Display device plug-in card (204) to the interface plug-in card (205) connected a combined plug-in card results. Electronic switching system according to claim 7, characterized in that the position of a plurality of switches mounted on one or more plug-in cards is represented by a number of indicators (502, 502, 601) which is less than the number of switches, the indicator or indicators on one or more of which the switch-carrying plug-in cards is or are mounted. Electronic switching system according to one of Claims 1 to 8th , characterized in that the switching position of the switch or switches (201) is detected by a control device (202), wherein the control device controls the display device or the display devices (208). Electronic switching system according to Claim 9 characterized in that the controller (202) is connected to a nonvolatile memory (216) such that the controller (202) can read, write and overwrite the contents of the memory (216) that the controller (202) estimates the number of switching operations of the switch (201) or the switch (201) and stored in the non-volatile memory (216), and that the controller (202) upon presentation of a predetermined number of switching operations for the particular representation, the remaining expected life of Indicator (1001, 1002) on the display (s) (208). Electronic switching system according to claims 7 and 9, characterized in that the control device (202) registers error states of the control device (202), the switch (201) and / or the plug-in card (204, 205), wherein the error condition specifying symbols (901) one or more display devices (208) are shown. Electronic switching system according to Claim 11 , characterized in that the control device (202) communicates bidirectionally with the bus, that the number of switching operations of the individual switches (201) is transmitted, that the current switching position of the individual switches (201) is transmitted, that the content of the non-volatile memory (216) is transmitted, that the content of the non-volatile memory (216) can be overwritten by data transmitted by the bus, and that error conditions of the control device ( 202), the switch (201) and the plug-in card (204, 205) are transmitted.

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