This application claims priority of DE 10 2018 133 438.9 filed Dec. 21, 2018. The entire contents of this application is incorporated herein by reference.
The present invention relates to a disconnect terminal to an assembly of at least two disconnect terminals. Such disconnect terminals are used in various applications.
Thus, for instance, document DE 197 48 640 C1 describes a measurement disconnect terminal assembly for the operation of current transformers in which power rails are provided with wire connections and contacts. For the connection of current measuring devices or external voltages, a disconnect is needed. This is done by a disconnect piece that interacts with the contacts.
DE 44 44 551 A1 describes a current transformer disconnect terminal with a switch in the form of an angle-adjustable contact disk which ensures by use a contact drag or slide path that during the disconnect or closing of the passage of current through the clamp, the secondary side of a connected current transformer can never be open.
The conventional disconnect terminals as such have proven themselves to be acceptable. It is desirable, however, that this disconnect terminal be further developed such that a simple, quick, and unambiguous identification of the respective switch position of the disconnect terminal, in other words, of a connecting position and of a disconnecting position, is possible. At the same time, a compact structure and a small number of component parts is desired.
A disconnect terminal according to the invention includes an enclosure or housing, a first conductor rail and a second conductor rail, a switching device and an actuation device. The switching device can be switched by the actuation device from a connecting position, in which the first conductor rail and the second conductor rail are electrically connected by the switching device, into a disconnecting position, in which the electrical connection of the first conductor rail and the second conductor rail is separated, and back. In the connecting position, a visible portion of the actuation device aligns with a surface of a portion of an upper side of the enclosure or of a part connected with the enclosure, and in the disconnecting position, the visible portion of the actuation device protrudes from a surface of a portion of an upper side of the enclosure or of a part connected with the enclosure in a clearly visible manner.
This allows for an unambiguous and quick identification of the switch position of the disconnect terminal.
The portion of the enclosure may be an upper side of a wall of the enclosure, a surface on the upper side of a component of the enclosure or of an inserted part of the enclosure, for instance a bridge holder.
An assembly according to the invention features at least two of the aforementioned disconnect terminals.
An additional assembly according to the invention includes at least two aligned disconnect terminals, wherein each disconnect terminal features an enclosure or housing, a first conductor rail and a second conductor rail, a switching device and an actuation device. The switching device can be switched by the actuation device from a connecting position, in which the first conductor rail and the second conductor rail are electrically connected by the switching device, into a disconnecting position, in which the electrical connection of the first conductor rail and the second conductor rail is separated or disconnected and back. In the connecting position, a visible portion of the actuation device aligns with a surface of a portion of an upper side of the enclosure or of a part connected with the enclosure, and in the disconnecting position, the visible portion of the actuation device protrudes from a surface of a portion of an upper side of the enclosure or of a part connected with the enclosure in a clearly visible manner. Sliding elements, limiter sliders, and/or actuating elements are mutually connected by detachable actuating elements in order to provide synchronous actuation. This allows for simple and fast actuation.
The switching device features a contact plate made of an electrically conductive contact material contact portions, wherein a contact portion forms a drag or slide contact. The contact plate may be produced in a simple manner, for instance as a punched part.
In the connecting position, the contact plate electrically connects the conductor rails via the contact portions in a simple manner. The contact plate is, for instance, a type of blade contact that interacts with contact forks or prongs of the conductor rails.
When in the disconnecting position, the contact plate electrically connects the first conductor rail with a bridge contact via the contact portion forming the drag contact and the contact portions. Thus, when disconnect terminals are aligned, a simple connection of the respective first conductor rails can be achieved in the disconnecting position, which may be advantageous, for instance for the use as current transformer disconnect terminals.
In one embodiment, the switching device and the actuation device feature a joint sliding element which is designed to be linearly movable and which is connected with the contact plate. This results in a compact structure with a small number of component parts.
Moreover, it is advantageous that the sliding element features an actuation portion with the visible portion, since the visible portion does not form an additional component.
In an additional embodiment, the linearly movable sliding element is coupled with a limiter slider via a gear unit such that the limiter slider defines an adjustment track of the linearly movable sliding element in interaction with limit stops of a guide portion in a body of the enclosure. This provides a simple delineation of the adjustment track of the sliding element.
In an alternative embodiment, the switching device features a linearly movable sliding element including the contact plate, wherein the actuation device features a separate actuating element which is coupled with the sliding element by way of interlocking gears or of another form-fitting drive such as a rack and pinion coupling. This leads to a simple manual actuation requiring a lower exertion of force.
The actuating element of the actuation device features an actuation portion including the visible portion wherein the actuating element is arranged pivotably around an axis. This allows for a compact structure.
In another embodiment, the sliding element includes a guide portion in the form of a bar with a front face including the visible portion. This allows for an additional display option of the respective switch position of the disconnect terminal.
In a further alternative embodiment, the switching device has a linearly movable sliding element including the contact plate and the actuation device has a separate actuation lever which features the visible portion and which is coupled with the sliding element via a lever gear mechanism. The lever gear mechanism allows for transmission of power from manual actuation to the sliding element. Furthermore, preset end positions can be easily obtained.
In a further embodiment, the lever gear mechanism includes the actuation lever and a transmission lever, the transmission lever being coupled with the sliding element. This leads to a simple structure with a minimal space requirement.
In yet another alternative embodiment, the switching device has a switch lever with an actuation end including the visible portion and is formed by the contact plate which has an elongated, blade-like form. This leads to a simple and space-saving embodiment.
A further embodiment provides the switch lever of the actuation device being solidly connected with the elongated blade-like contact plate of the switching device and being pivotable together with the contact plate around a joint fixed switch lever axis. This structure is advantageous since only a small number of component parts is needed. Moreover, only a small manual exertion of force is needed. Alternatively, a tool or actuation device may be used as well.
In a further embodiment, the switch lever in the connecting position abuts an enclosure stop with its actuation end wherein the visible portion aligns with a surface of the enclosure stop. In the disconnecting position, the switch lever with the contact plate is pivoted around the fixed pivoting axis and abuts a bridge holder by way of a limit stop, wherein the visible portion of the actuation end of the switch lever protrudes from the surface of the bridge holder as a portion or a component of the enclosure. In this manner, simple identification of the switch status or position of the disconnect terminal can be achieved.
In one embodiment of an assembly, at least two disconnect terminals jointly have a bridge holder with bridge contacts that are electrically connected with each other. Thus, a range of application of the disconnect terminal is advantageously extended.
In the following specification, the invention is described in further detail based on exemplary embodiments with reference to the accompanying drawings in which:
The words “upper”, “lower”, “left”, and “right” relate to the respective assembly of the components in the figures.
The disconnect terminal 1 includes an enclosure or housing 2 with a first connection portion 2a, a second connection portion 2b, and a disconnect portion 2c centrally arranged between them.
In the first connection portion 2a, a first terminal portion 3 is arranged for connecting an electrically conductive conduit, not shown. The first terminal portion 3 is connected with a first conductor rail 4 which extends with one connecting portion 5 into the disconnect portion 2c.
Similarly, in the second connection portion 2b, in a mirror-inversion of the first connection portion 2a, a second terminal portion 6 is arranged for connecting an electrically conductive conduit, not shown. The second terminal portion 6 is connected with a second conductor 7 which extends with one connecting portion 8 into the disconnect portion 2c.
The connecting portion 5 of the first conductor rail 4 and the connecting portion 8 of the second conductor rail 7 have an operative connection with a switching device 9. The switching device 9 features two positions. In a connecting position, the switching device 9 electrically connects the two connecting portions 5 and 8, and therefore the first conductor rail 4 and the second conductor rail 7, such that the first terminal portion 3 is electrically connected with the second terminal portion 6.
In a disconnecting position of the switching device 9, the two connecting portions 5 and 8 are separate and insulated from each other, in other words, the electrical connection between the two connecting portions 5 and 8, and therefore of the conductor rails 4 and 2, is separated or disconnected.
The switching device 9 is coupled with an actuation device 10. The actuation device 10 is designed for switching the switching device 9 from the connecting position into the disconnecting position, and back. The actuation device 10 is actuated manually and/or by a suitable tool. The respective position, in other words, the connecting position and the disconnecting position of the switching device 9, is visually displayed by the actuation device 10. This is executed such that in the connecting position, a visible portion 102 of the actuation device 10 aligns with a surface 12, 12a of a portion of an upper side of the enclosure 2 or with a part connected with the enclosure 2, and that in the disconnecting position, the visible portion 102 of the actuation device 10 protrudes from the surface 12, 12a of a portion of the upper side of the enclosure 2 or of a part connected with the enclosure 2 in a clearly visible manner.
In the disconnect portion 2c, the switching device 9 and the actuation device 10 coupled with it are arranged as a disconnect unit 11 shown in
In the example illustrated in
In the first embodiment, the switching device 9 and the actuation device 10 include a joint sliding element 101. The sliding element 101 is linearly movable in the disconnect unit 11 in a manner that is not further illustrated, in other words, it is borne longitudinally, and in this case arranged perpendicularly to an imaginary longitudinal axis of the connecting portions 5, 8 of the conductor rails 4, 7. The sliding element 101 is rod-shaped, formed to have a substantially rectangular cross section.
The sliding element 101 includes an actuation portion 101a at an upper end, a switching end 101b at a lower end, interlocking gears 101c in the form of a toothed rack portion on a longitudinal side, and a guide portion 101d on a longitudinal side facing the longitudinal side with the interlocking gears 101c.
The guide portion 101d is a type of longitudinal bar, which forms a locking system of the sliding element 101 in the bridge holder 13 for stopping the short-circuit bridge thus formed in the disconnecting position with the contact portion 91 of the contact plate 90 in the bridge contact portions 14. The guide portion 101d may also extend further upward, thus engaging the guide surface of the bridge holder 13. This is not shown, but is evident from
In the disconnecting position, the narrow front face of the guide portion 101d pointing upward to the actuation portion 101a of the sliding element 101 may form an additional position indicator of the disconnect terminal 1 with the surface 12 of the bridge contact holder 13. Thus, this front face of the guide portion 101d can align in the disconnecting position with the surface 12 of the bridge contact holder 13 and be colored, for instance, as a colored visible portion, thereby indicating the disconnecting position. In the other case in which the guide portion 101d extends further upward, the connecting position may be indicated by the alignment of the front face with the surface 12 of the bridge contact holder 13. In the disconnecting position, the upper extended portion of the guide portion 101d will then protrude from the surface 12 of the bridge contact holder 13, thus indicating the disconnecting position.
The switching device 9 features a contact plate 90 formed as a blade contact with three contact portions 91, 91a, and 92. These three contact portions 91, 91a, and 92 are electrically connected with each other and attached to the sliding element 101 in the area of the switching end 101a with two contact portions 91 and 91a being arranged on a longitudinal side of the sliding element 101 that points to the first connecting portion 5, and the contact portion 92 being arranged on the opposite longitudinal side of the sliding element 101 that points to the second connecting portion 8.
The contact portions 91 and 91a interact with a contact fork or prong 5a of the connecting portions 5 of the first conductor rail 4. An additional contact fork 8a at the end of the connecting portion 8 of the second conductor rail 8 faces the contact fork 5a and interacts with the contact portion 92 of the contact plate 90.
A bridge contact fork 14 is arranged above the contact fork 5a. The bridge contact fork 14 is attached to a bridge holder 13 by an additional, parallel, bridge contact fork 14. The bridge contact forks 14 are electrically connected with each other.
The sliding element 101 is coupled with a limiter slider 104 via a gear unit. The gear unit features the interlocking gears 101c (toothed rack) of the sliding element 101, a rotatable transmission element 103 with corresponding interlocking gears, and additional interlocking gears 104a (toothed rack) of the limiter sliders 104.
The sliding element 101 engages the transmission element 103 via its interlocking gears 101c. The transmission element 103 is formed as a spur gear wheel, rotatable around an axis 103a in lateral walls 15 of the disconnect portion 2c and borne in a body member 15b.
Furthermore, the transmission element 103 engages the limiter sliders 104 with its interlocking gears 104a. The limiter slider 104 is arranged opposite the sliding element 101 in a guide portion 15c of the disconnect portion 2c in a longitudinally slidable manner. The guide portion 15c furthermore forms limit stops for the longitudinal slidability of the limiter sliders 104.
By means of the actuation portion 101a, the sliding element 101 can be switched from the connecting position to the disconnecting position and back.
In the connecting position, the contact plate 90 is electrically connected with the contact fork 5a of the first conductor rail 4. At the same time, the contact portion 92 of the contact plate 90 is electrically connected with the contact fork 8a of the second conductor rail 7, thus forming an electrical connection between the contact forks 5a and 8a.
Moreover, the guide portion 101d is slidably guided in the bridge contact fork 14 and in the bridge contact holder 13. The guide portion 101d is not electrically conductive.
In the connecting position, a visible portion 102 of the actuation portion 101a of the sliding element 101 aligns with a surface 12 of a portion of the enclosure 2. The portion of the enclosure 2 may be the upper side of the wall 15 of the enclosure 2. Here too, a surface 12 is arranged on the upper side of the bridge holder 13. The bridge holder 13 is a component of the enclosure 2 and inserted into it.
By pressure actuation of the limiter slider 104, the sliding element 101 is longitudinally moved upward via the transmission element 103 into the disconnecting position. The longitudinal movement of the limiter slider 104 is defined in the guide portion 15c by a limit stop for the disconnecting position, and by a limit stop of the slider element 101 for the connecting position. In the disconnecting position, the contact forks 5a and 8a are separated, since the contact portion 92 of the contact plate 90 is pulled out upward from the contact fork 8a. The extended contact portion 91a, however, remains in contact with the contact fork 5a, forming a so-called drag or sliding contact.
In the disconnecting position, the upper contact portion 91 of the contact plate 90 has an electro-conductive contact with the bridge contact fork 14. The bridge contact fork 14 and the contact fork 5a of the first conductor rail 5 are now electrically connected by the extended contact portion 91a that forms a drag contact. The guide portion 101d is guided in the bridge contact holder 13 in a longitudinal groove.
In the disconnecting position, the actuation portion 101a and the visible portion 102 of the sliding element 101 visibly protrudes from the surface 12 of the disconnect portion 2c.
In the illustrated embodiment with the two disconnect portions 2c of the two disconnect terminals 1 in the disconnecting position of the two disconnect terminals 1, both first conductor rails 5 are electrically connected via the bridge contact forks 14.
In the second embodiment, the switching device 9 and the actuation device 10 are separated. The switching device 9 includes the linearly movable sliding element 101 with the switching end 101b, with the interlocking rack gears 101c, the guide portion 101d, and the contact plate 90 with the contact portions 91, 91a, and 92. Furthermore, the disconnect unit 11 features the bridge contact forks 14 with the bridge holder 13.
Contrary to the first embodiment, the sliding element 101 of the second embodiment features an end portion 101e without an actuation portion and without a visible portion.
The actuation device 10 includes a separate actuating element 105 coupled with the sliding element 101 by interlocking gears. The actuating element 105 features an actuation portion 105a with a visible portion 102 and a gear segment 105c in the form of a quarter circle. The actuating element 105 is pivotably arranged around an axis 105b. A pivot angle of the actuating element 105 is defined by limit stops in the body member 15b such as system portion 15d.
The gear segment 105c engages the rack-shaped interlocking gears 104c of the sliding element 101.
In the connecting position, the visible portion 102 of the actuation portion 105a of the actuating element 105 aligns with a surface 12 of a portion of the enclosure 2. The portion of the enclosure 2 may be the upper side of the wall 15 of the enclosure 2. Furthermore, the portion of the enclosure 2 is also the upper side of the bridge holder 13 on which the surface 12 is arranged. The actuation portion 105a is supported with the lower side of the visible portion 102 on the front face of the end portion 101e of the sliding element 101.
The connecting position of the sliding element 101 with the contact plate 90 is as described for the first embodiment.
It is swiveled by a pivoting actuation of the actuation portion 105a of the actuating element 105 (in a clockwise direction in the embodiment shown) around axis 105b. The sliding element 101 engaged by the gear segment 105c is linearly shifted upward into the disconnecting position, wherein the electro-conductive connection of the contact forks 5a and 8a described above with respect to the first embodiment is separated or disconnected.
In the disconnecting position, the actuation portion 105a with the visible portion 102 of the actuating element 105 as well as the upper end portion 101e of the sliding element 101 visibly protrude from the surface 12 of a portion of the enclosure 2 and also from the surface 12 of the bridge holder 13.
Also in the third embodiment, the switching device 9 and the actuation device 10 are separated. The switching device 9 includes the linearly movable sliding element 101 with the switching end 101b and the upper end portion 101e. The contact plate 90 with the contact portions 91, 91a, and 92 is provided as in the first and second embodiments. The disconnect unit 11 features the bridge contact forks 14 with the bridge holder 13 as described above
As in the second embodiment, the sliding element 101 of the third embodiment features the end portion 101e without an actuation portion and without a visible portion.
Contrary to on the second embodiment, the end portion 101e is laterally broadened by a wedge-shaped connecting portion 101f.
On the two longitudinal sides of the sliding element 101 pointing outward towards the wall 15, longitudinally extending guide portions 101g are fitted along the entire length of the sliding element 101 by which the sliding element 101 is linearly movably guided in the walls 15.
Contrary to the second embodiment, the actuation device 10 includes a lever gear mechanism with an actuation lever 106 and a transmission lever 107.
The actuation lever 106 features an actuation end 106a with the visible portion 102, and a bearing end 106b. With the bearing end 106b, the actuation lever 106 is attached in a pivotable manner to an unmarked body of the disconnect unit 11 by means of a joint axis 106c. The bearing end 106b is arranged above the end portion 101e of the sliding element 101, wherein the joint axis 106c aligns with a longitudinal axis of the sliding element 101.
The actuation end 106a of the actuation lever 106 is pivotably connected with a drive end 107a of the transmission lever 107 by a joint axis 106d. The transmission lever 107 extends from the actuation lever 106 downward to the wedge-shaped connecting portion 101f of the sliding element 101 and is pivotably coupled with this connecting portion 101f via an output end 107b around an output joint axis 107c.
In the connecting position, both the visible portion 102 of the actuation portion 105a of the actuation lever 105a and the largest part of the surface of the actuation lever 105 align with the surface(s) 12a of the walls 15 of the disconnect unit 11. The walls 15 may be part of the enclosure 2. The transmission lever 106 abuts a system portion 15d of the disconnect unit 11 with its lower side by way of a limit stop.
The connecting position of the sliding element 101 with the contact plate 90 is as described for the first embodiment.
It is pivoted around the fixed joint axis 106c (in this case in a counterclockwise direction) by a pivoting actuation of the actuation portion 106a of the actuation lever 106. The transmission lever 107 is pulled upward and it simultaneously pulls the sliding element 101 upward from the connecting position into the disconnecting position. As described above with respect to the first embodiment, the electro-conductive connection between the contact forks 5a and 8a is thereby separated.
In the disconnecting position, the actuation lever 106 is pivoted upward around the fixed joint axis 106c so that the actuation end 106a and the visible portion 102 of the surface 12 of the disconnect unit 11 or of the disconnect portion 2c or of the bridge holder 13 protrude in a clearly visible manner.
The sliding path of the sliding element 101 is realized in the disconnecting position by a limit stop of the end portion 101e at the lower side of the bearing end 106b of the actuation lever 106.
An assembly of the lever gear mechanism in the respective axes 106c, 106d, 107c with the actuation lever 106 and the transmission lever 107 is shown in
Contrary to the previous embodiments, the contact fork 8a of the second conductor rail 7 is not arranged opposite the contact fork 5a of the first conductor rail but it is bent upward, in other words, arranged upward at a distance.
Furthermore, the bridge contact forks or prongs 14 are arranged opposite the contact forks 8a and bent towards them.
In the fourth embodiment, the switching device 9 and the actuation device 10 are formed jointly as in the first embodiment.
The switching device 9 features the contact plate 90 in an elongated blade-like form. The contact plate 90 is formed entirely of an electrically conductive contact material and includes the contact portions 91, 91a, and 92 as well as an electrically conductive connecting portion 93.
At the lower end of the contact plate 90, the contact portion 91a is fitted on the side pointing to the contact fork 5a. The contact portion 91 is fitted across from it on the other side.
The contact portions 91, 91a interact with the contact fork 5a.
The contact portion 92 is fitted on the upper end of the contact plate 90 on both sides as are the portions 91 and 91a.
The contact portions 91, 91a, and 92 are electrically connected via the connecting portion 93.
The contact plate 90 is arranged in its lower part in a fixed connection in a bearing portion 15e between the walls 15 in the disconnect unit 11 and pivotable around a pivoting axis 111b.
The upper end of the contact plate 90 is solidly connected with the actuation device 10.
The actuation device 10 features a switch lever 111 with an actuation end 111a. The visible portion 102 is arranged on the actuation end 111a.
In the connecting position, the actuation end 111 of the switch lever 111 is essentially vertical and abuts the enclosure stop 15f. The visible portion 102 aligns with the surface 12 of the enclosure stop 15f. The enclosure stop 15f is a portion of the enclosure 2.
In the connecting position, the right-side area of the contact portion 92 of the contact plate 90 is in contact with the contact fork 8a. The contact portion 91 of the contact plate 90 is in contact with the contact fork 5a. In the connecting position, this creates an electrical connection between the contact fork 5a, the contact portion 91, the connecting portion 93, the contact portion 92, and the contact fork 8a.
The contact plate 90 is pivoted (here in a counterclockwise direction) around the fixed pivoting axis 111b by a pivoting actuation of the actuation portion 111a of the switch lever 111. The contact portion 92 switches from the contact fork 8a to the bridge contact fork 14. The contact portion 91 leaves the contact fork 5a, but the contact portion 91a connected with it remains in contact with the contact fork 5a by way of a drag contact.
In the disconnecting position, the switch lever 111 with the contact plate 90 is pivoted to the left around the fixed pivoting axis 111b, the actuation end 111a abutting the limit stop at the bridge holder 13. The visible portion 102 protrudes from the surface 12a of a portion of the enclosure 2. The portion of the enclosure 2 may be the upper side of the wall 15 of the enclosure 2. Furthermore, the portion of the enclosure 2 is also the upper side of the bridge holder 13 on which the surface 12 is arranged.
In the disconnecting position, this creates a disconnect between the contact forks 5a and 8a, in other words, between the first conductor rail 4 and the second conductor rail 7. At the same time, the contact fork 5a of the first conductor rail 4 and the bridge contact fork 14 are electrically connected via the contact plate 90.
The actuation end 111a of the switch lever 111 can be shifted manually, by a tool, or by an actuating element 16. This is shown by the actuating element 16 in perspective views of the disconnect unit 11 of the fourth embodiment according to
The actuating element 16 features a body 16a for manual actuation as well as an insertion portion 16b with which the actuating element 16 can be inserted into the actuation end 111a that features a recess for that purpose. The actuating element 16 may feature one, two, or multiple insertion portions 16b. The actuating element 16 allows for the synchronous actuation of two or more sectioning points.
Schematic perspective views of assemblies 100 of disconnect terminals 1 according to the invention of the fourth embodiment of the disconnect unit 11 according to
It is clearly visible which disconnect terminals 1 are in the disconnecting position and which are in the connecting position, since in the disconnecting position, the respective actuation ends of the switch levers 111 protrude with their visible portions 102 from the surface 12, 12a of the enclosure 2 and of the bridge support 13 of the disconnect units 11 wherein they no longer abut the enclosure stops 15f.
Number | Date | Country | Kind |
---|---|---|---|
10 2018 133 438.9 | Dec 2018 | DE | national |
Number | Name | Date | Kind |
---|---|---|---|
3454836 | Norden | Jul 1969 | A |
5700986 | Rurup | Dec 1997 | A |
9589755 | Singer et al. | Mar 2017 | B1 |
10388479 | Zhai | Aug 2019 | B2 |
10547126 | Riku | Jan 2020 | B2 |
20040011630 | Pedrinell | Jan 2004 | A1 |
20160056599 | Peach | Feb 2016 | A1 |
20170162955 | Berg et al. | Jun 2017 | A1 |
Number | Date | Country |
---|---|---|
4444551 | Jun 1996 | DE |
19748640 | Mar 1999 | DE |
10118919 | Oct 2002 | DE |
60131093 | Jul 2008 | DE |
102015121057 | Jun 2017 | DE |
2684231 | May 1993 | FR |
0223675 | Mar 2002 | WO |
2014020287 | Feb 2014 | WO |
Entry |
---|
WAGO, Reihenklemmensysteme, Hauptkatalog, Band 1—Ausgabe 2017/2018. Minden 2017. S. 1, 2, 272.—Firmenschrift. |
Number | Date | Country | |
---|---|---|---|
20200203878 A1 | Jun 2020 | US |