RU2608593C2 - Terminal block arrangement - Google Patents

Abstract

FIELD: manufacturing technology.

SUBSTANCE: invention relates to terminal block arrangement (100), which has elongated mounting strip (2) with two rectangular broad long-edged front plates, equipped with parts (8, 9), formed at its opposing narrow short-edged side plates (13) with short edges for coupling them to support parts (5, 6) of support structure (7), terminal block arrangement has modules (3), that can be fitted to mounting strip (2) next to one another in a row, said modules (3) have an insulated housing, whereby each housing (3) and mounting strip (2) have mutual connection devices (20) for plugging modules (3) to mounting strip (2), transversely with respect to the longitudinal direction of mounting strip (2), each housing has mounting wall (45) and at least one receiving slot in mounting side (45), connection bars (20) project from one of its two rectangular broad long-edged front plates and oriented transversely with respect to the longitudinal direction of mounting strip (2), whereby receiving slot (21) and connection bars (20) form mutual connection devices, whereby connection bar (20) has a T-shaped cross-section, with first plate-like limb (40).

EFFECT: technical result is stable positioning and fixing of the terminal blocks.

15 cl, 11 dwg

Description

The invention relates to a terminal block device, which has an elongated mounting plate with two rectangular wide front plates with long edges provided with parts formed on its opposite narrow side plates with short edges for connecting it to the supporting parts of the supporting structure, wherein said terminal block device has blocks that can mate with the mounting plate next to each other in a row, while these blocks have an insulated housing, so that each The body and mounting plate have mating connectors for connecting the blocks to the mounting plate transverse to the longitudinal direction of the mounting plate 2 in accordance with the introductory part of p. 1.

EP 1217693B1 describes a terminal block device for a distribution block for electrical equipment, in particular for connecting protective earth wires and neutral wires, wherein said terminal block device has a mounting strip and blocks that can mate with the mounting strip next to each other in a row, however, these blocks have an insulating casing, so that each of the casing and the mounting plate have devices for connecting the blocks to the mounting plate across relative to the longitudinal th direction by means of the mounting plate, that said device contains a hook element, which is connected with the housing, having a hook limb which engages behind the mounting plate.

An object of the present invention is to provide a terminal block device of a simplified type in which a stable arrangement and fixation of terminal blocks on a mounting strip are achieved by simple handling of the devices.

In accordance with the invention, the above goal is achieved by the device terminal blocks with the characteristics specified in paragraph 1 of the claims. In accordance with the invention, each housing has a mounting wall and at least one receiving groove in the mounting wall, and the mounting plate has a series of connecting bars protruding from one of its two rectangular front plates with long edges and oriented transverse to the longitudinal direction of the mounting strips, so that the receiving groove and connecting bars form mating connecting devices, while the connecting bar has a T-shaped cross section with the first astinchatoy branch, receding from one of two rectangular plates with a front long edges, and the second branch of the plate, formed at the free end and perpendicular to the first branch. The T-shaped cross-section of the connecting bar in cooperation with the receiving groove is a possible way of stable location and fixation of the block body on the mounting plate. All connecting bars are oriented parallel and transverse to the longitudinal direction of the mounting plate, and they can advantageously be spaced equally apart from each other, forming a kind of raster. The block case, if it has a larger size, can preferably have a number of receiving grooves, while all of these receiving grooves are spaced apart from each other by the same distances as the connecting bars, so that the raster of the receiving grooves in the block body mates with a raster of connecting bars on the mounting plate. Thus, the structure in accordance with the invention allows precise positioning of the block housings with raster lattice spacing along the longitudinal extent of the mounting plate.

Preferred embodiments of the invention are described in the characterizing parts of the dependent claims.

According to a preferred object of the invention, the mounting wall of the housing has a mounting edge, and the receiving groove has a mounting hole in the mounting edge, wherein said receiving groove extends from the mounting edge upward towards the second edge of the housing located opposite the mounting edge, and the connecting bar and the receiving groove are made with the possibility of sliding interaction, when the connecting bar is inserted into the receiving groove through the mounting hole. The mounting hole may be slightly wider than the receiving groove, facilitating the connection of the block body and connecting bars.

According to a preferred aspect of the invention, the width of the receiving groove is adapted to the width of the second lamellar branch, and two rod-shaped protrusions are used that extend from the mounting wall into the receiving groove, the thickness of the protrusions corresponding to the distance from the second lamellar branch to the front plate with long edges, leaving between them opposite the free edges of the gap corresponding to the thickness of the first branch. Two rod-shaped protrusions, thus, reduce the effective cross section of the receiving groove when viewed perpendicular to the mounting wall of the housing. The two rod-shaped protrusions do not extend all the way down to the mounting edge, but they end at a small distance above the mounting edge. Thus, in the remaining section of the receiving groove down to the mounting edge, the effective cross section of the receiving groove is larger than in the rest of the groove when viewed perpendicular to the mounting wall of the housing. The part with a large effective cross-section thus forms the aforementioned mounting hole.

According to a preferred aspect of the invention, the connecting block has an insertion end and a distal end opposite the insertion end, and the width of the cross-sectional contour of the connecting bar at the distal end is larger than the width of the cross-sectional contour of the receiving groove at the mounting hole. A preferred effect of this embodiment of the invention is that block insertion at the distal end of the connecting bar is prevented, and thus erroneous block insertion is eliminated. To increase the width of the contour of the cross section of the connecting bar at the distal end, there are many ways. You can increase the cross-sectional size of the first plate, or the second plate, or both. The increase in the width of the cross-sectional contour may not be large. Essentially, it would be sufficient to increase it to a small extent only to such a extent that the distal end of the connecting bar can still be inserted into the aforementioned mounting hole, but cannot be inserted into the remaining part of the receiving groove or can be inserted into it by pressing using a substantial efforts. Thus, the operator can easily recognize the difference between the insert on the right side of the connecting bar when the insert is unobstructed and the receiving groove on the connecting bar is slightly slipping, and the insert on the wrong side where unhindered insert is not possible.

According to a preferred object of the invention, the mutual adaptation of at least one of the connecting bar and its receiving groove is intended for connection using the transmission of force by friction. Friction force transfer can occur after connecting the receiving groove to the connecting bar and moving the housing to some extent along the connecting bar down so that slight sliding occurs in the first part of the insertion path, and the friction force transfer begins to act towards the end. The advantage is that due to the transfer of force by friction, a stable fixation of the block body on the mounting plate is achieved without any additional fixing means, such as hooks and the like, which can also be easily removed by simply pushing the block body back again. If the block body has more than one receiving groove, as described above, spaced apart from each other, only the mutual coupling of one of the connecting bars and one receiving groove for connection using the transmission of force by friction may be sufficient.

According to a preferred aspect of the invention, distance reducing means are applied on the free edge of at least one of the rod-like protrusions. Thus, the transfer of friction force is achieved by at least partially reducing the distance between the opposite free edges of the pair of rod-shaped protrusions facing each other. If the block body has more than one receiving groove, as described above, spaced apart from each other, an arrangement of distance-reducing means on the free edge of only one of the rod-shaped protrusions may be sufficient so that only one of several receiving grooves in the installation wall of the block body will have a reduced cross section for transmitting friction. The creation of friction force transmission in this way, achieved by reducing the cross section of the receiving groove of the housing, has the advantage that the mounting plate and connecting bars can not be modified.

According to a preferred aspect of the invention, the distance-reducing agent is a protrusion or bulge formed at least on one of the opposite free edges of a pair of two rod-shaped protrusions facing each other. Again, if the block body has more than one receiving groove, as described above, spaced apart from each other, it may be sufficient to form a protrusion or bulge on only one of the opposite free edges of a pair of two rod-shaped protrusions facing each other, so that only one of the several receiving slots in the mounting wall of the block body had a reduced cross section to transmit friction.

According to a preferred aspect of the invention, a contour expanding means is applied, applied to the contour in the cross section of the connecting bar. Thus, the transfer of friction force is achieved, at least in part, by increasing the contour of the cross section of the connecting bar. The creation of a friction force transmission, thus achieved by increasing the cross section of the connecting bar, has the advantage that the housing and receiving grooves in it can not be modified.

According to a preferred aspect of the invention, the contour expanding means is a thickness increasing means at least partially increasing the thickness of the second lamellar branch, so that friction is transmitted at least partially by increasing the thickness of the second lamellar branch.

According to a preferred aspect of the invention, at least one front expansion means is applied, applied to at least one of the front plate with the long edges of the mounting plate or the mounting wall of the housing. Thus, the transfer of friction force is achieved through the effect of jamming when the unit is connected to the mounting plate.

According to a preferred aspect of the invention, the front expansion means is a bulge protruding from the front plate with the long edges of the mounting plate.

According to a preferred object of the invention, the front expansion means is a bulge protruding from the mounting wall of the housing. An advantage of this embodiment of the invention is that it may be sufficient to provide only one bulge on the mounting wall of the housing and not modify the mounting strip, which makes the necessary modification very easy.

According to a preferred aspect of the invention, an elastic mounting lever that is loaded in a holding position is formed in the mounting wall of the block body by means of slots so that the mounting lever has a locking member protruding from the mounting wall, which is adapted to resiliently engage with a corresponding recess formed in the front a plate with long edges of the mounting plate, while the locking element can be released by pressing the mounting lever to the inner part to Orpusa. This is an alternative and / or additional means for fixing the block body to the mounting plate.

According to a preferred aspect of the invention, the free end of the elastic fastening lever has a pushing element at its end for pressing the end portion of the elastic fastening lever against the inside of the housing to release the locking clutch.

According to a preferred aspect of the invention, at least one spacer element is formed on the mounting wall of the housing and located near the locking element to limit the displacement of the elastic arm when the mounting wall of the housing is pressed against a flat surface.

The invention will be described in more detail by describing a variant of its implementation with reference to the accompanying drawings, in which:

FIG. 1 is a view of an embodiment of a distribution unit with a terminal block device in accordance with the invention,

FIG. 2 is a view of a block oriented to a mounting strip in a terminal block device in accordance with the invention,

FIG. 3a is a view of a block oriented to a mounting strip in a terminal block device according to a second embodiment of the invention,

FIG. 3b is a schematic side view and a view in the direction perpendicular to the mounting wall of the block in accordance with the embodiment of the invention shown in FIG. 3a

FIG. 4 is a cross-sectional view of a terminal block device according to the embodiment of the invention shown in FIG. 3a, the unit being mounted on a mounting strip,

FIG. 5 is a top sectional view of a terminal block device according to FIG. four,

FIG. 6 is an enlarged partial view of the mounting surface of the interface between the block mounted on the mounting strip in accordance with the embodiment shown in FIG. 3a

FIG. 7a is a schematic sectional view of a housing mounted with a mounting strip in a terminal block device in accordance with the invention,

FIG. 7b is a schematic cross-sectional view of a housing and a mounting strip in a terminal block device according to the invention before connecting to each other with a height increasing means increasing the height of a second lamellar branch of one of the connecting bars,

FIG. 7c is a schematic cross-sectional view of a housing and a mounting strip in a terminal block device in accordance with the invention before connecting to each other, in three embodiments, reducing distance means deposited on the free edge of at least one of the rod-shaped protrusions defining a receiving groove,

FIG. 7d is a schematic cross-sectional view of a housing and a mounting strip in a terminal block device in accordance with the invention before connecting to each other with two options for front expansion means applied to a front plate with long edges of the mounting strip or the mounting wall of the housing.

In FIG. 1-7 shows a distribution block 1 for electrical equipment. The distribution block 1 has a base 7 in the form of a circuit board. There are two points with the means for mounting the mounting rail 32, also called a DIN rail, on the base 7. Instead of the mounting rail 32 shown, any other kind of profiled busbar may be used which is allowed according to various technical standards that are used in different countries around the world electrical switchboards. The mounting rail is used to install electrical equipment devices such as microswitches, residual current circuit breakers, contactor devices, surge protection devices, etc. For example, in FIG. 1, the microswitch 33 is mounted on the mounting rail 32. In the switchboard 1 shown in FIG. 1, two such mounting rails can be installed in parallel and with reference to each other, although only one of them is shown, which is located near the upper edge 34 of the mounting plate 7 of the distribution block 1.

The distribution unit 1 also comprises a terminal block device 100, in particular for connecting protective earth wires and neutral wires. The terminal block device 100 is located on the upper edge of the circuit board 7. It can also be located on the lower edge opposite the upper edge, or terminal block devices can be used on both the upper edge and the lower edge. The terminal block device 100 has a mounting strip 2 and blocks 3, with only one block 3 shown in the exemplary embodiment of FIG. 1, which can be attached to mounting plate 2 next to another.

The terminal block device 100 typically has a conductive bus bar and a series of connecting elements for connecting conductors to the conductive bus. Each of the blocks 3 has at least one of the connecting elements. The blocks 3 have an insulating casing 4 and a busbar section (not shown here in FIG. 1), which is arranged within the housing 4. The busbar sections form a busbar, and the terminal block device has connections for electrically connecting the busbar sections of the blocks that are installed next to each other on the mounting plate.

The distribution unit 1 has first and second supports 5, 6 for mounting plate 2, located at a distance from each other on the base 7. Near the first and second supports 5, 6 are additional first and second supports 5 ', 6' located at a small distance lower than the first and second supports 5, 6. The height above the mounting plate 7 of the first and second supports 5, 6 is greater than the height above the mounting plate 7 of the additional first and second supports 5 ', 6'. Thus, the additional first and second supports 5 ', 6' provide for the installation of a mounting strip 2 near the mounting plate 7, and the first and second supports 5, 6 allow the installation of the mounting strip 2 at a certain distance above the mounting plate 7. An option may even be provided, in which has two mounting strips, each of which is equipped with terminal blocks, one on the first and second supports 5, 6 and the other on additional first and second supports 5 ', 6'. In FIG. 1 shows the situation when the first mounting plate 2 'is fixed on the additional first and second supports 5', 6 ', the second mounting plate 2 is shown in the position before installation on the supports, with the arrows indicating the direction of installation on the supports 5, 6.

The mounting plate 2 is attached to the supports 5, 6, for which the mounting plate 2 has a connecting part 8, 9 formed at its opposite narrow ends. Each of the connecting parts 8, 9 has a latch that can be released by pressing it in the direction of the movable support of the mounting plate 2 with a tool or finger. The latch moves to the holding position.

The mounting plate 2 is formed as an elongated cuboid rod. The rod has two rectangular plates 11, 12 with long edges, which are connected by two rectangular plates 13, 14 with narrow edges. The long edges of the plates 11, 12 with long edges and the narrow edges of the plates 13, 14 with narrow edges form two narrow sections 17, 18 of the side of the long edge.

Each of the cases 4 and the mounting plate 2 have devices for inserting the blocks 3 into the mounting plate 2 transverse to the longitudinal direction of the mounting plate 2. These devices on the side of the mounting strip 2 are formed as protruding bars 20, oriented transversely relative to the longitudinal direction of the mounting plate 2, arranged in parallel to each other and are formed outside one of their rectangular plates 11, 12 with long edges. These devices on the side of the insulating body are formed as at least one groove 21, oriented transversely relative to the longitudinal direction of the mounting plate 2 and adapted to force the block 2 to be locked in the groove 21 when inserting the block body 4 into the mounting plate 2.

Each housing 4 has a mounting wall 45 and at least one receiving groove 21 on the mounting wall 45. The mounting wall 45 has a mounting edge 42, and the receiving groove 21 has a mounting hole 43 in the mounting edge 42 extending from the mounting edge 42 upward second direction

The receiving groove 21 extends approximately half the distance from the mounting edge 42 in the direction of the second edge. The mounting hole 43 is slightly wider than the receiving groove 21, which facilitates the insertion of the block housing 4 into the connecting bars.

Inside the housing 4 are located and attached to the housing 4 all the parts that are required for the housing for a modular contact clamp, such as means for connecting cables and channels, a clamping spring with means for holding the clamping spring, screw terminals with a screw hole in the housing 4 and so on . All of these nodes are not described in detail here, although they can be observed in the figures, and one skilled in the art will recognize them in the figures.

The mounting plate 2 has a series of connecting bars 20 protruding from one of its two rectangular front plates 11 with long edges and oriented transverse to the longitudinal direction of the mounting plate 2. Thus, the receiving grooves 21 and connecting bars 20 form mating connecting devices. The connecting block 20 has a T-shaped cross section with a first lamellar branch 40 extending from the front plate 11 with long edges and with a second lamellar branch 41 formed at the free end and perpendicular to the first branch 40.

All connecting bars 20 are oriented parallel and transverse to the longitudinal direction of the mounting plate 2. They are spaced apart from each other by the same distance, forming a kind of raster. In FIG. 1, a raster of 16 connecting bars 20 can be seen, and in FIG. 2 and 3a, partial views from 6 and 7 of these connecting bars 20 can be observed. The block body 3 has four receiving grooves 21, while all of these receiving grooves 21 are located at the same distances from each other as the connecting bars 20. Thus, the raster of the receiving grooves 21 in the housing 4 of the block 3 is mated with the raster of the connecting bars 20 on the mounting plate 2. This design ensures the exact location of the buildings 4 of the block 3 with a raster lattice spacing along the longitudinal length of the mounting trims 2.

The connecting block 20 and the receiving groove 21 are slidably engaged when the connecting bar 20 is inserted into the receiving groove 21 in the mounting hole 43.

In the schematic FIG. 7a-7d, it can be seen that the width w of the receiving grooves 21 is adapted to the width w 'of the second lamellar branch 41, which means that when the second lamellar branch 41 is guided within the receiving groove 21, it can easily slide within the receiving groove 21. two rod-shaped protrusions 46, 47 extending from the mounting wall 45 into the receiving groove 21. The thickness t of the protrusions 46, 47 corresponds to the distance from the second lamellar branch 41 to the front plate 11 with long edges, leaving a gap d between their opposite free edges corresponding to the thickness t ′ of the first branch 40. In other words, the inner surface of the receiving groove 21 forms a kind of negative T-shaped configuration that mates with the T-shaped configuration of the connecting bar 20 in the sense of being adapted for sliding engagement when the connecting bars 20 are inserted into the receiving grooves 21.

The two rod-shaped protrusions 46, 47 do not completely reach the mounting edge 42, but they end at a small distance above the mounting edge 42. Thus, in the remaining section of the receiving groove 21 down to the mounting edge 42, the effective cross section of the receiving grooves 21 is larger than in the rest parts of the groove 21 when viewed perpendicular to the mounting wall of the housing, see FIG. 3b. The part with a large effective cross section thus forms the aforementioned mounting hole 43.

The connecting block 20 has an insertion end 48 and a distal end opposite the insertion end 48, see FIG. 2 and 3a. Reference numeral 48 is shown in the figures only once, but it is understood that other connecting bars can easily be identified in the figures when their structure is the same as that indicated by the reference position, and for clarity of the drawings, only one of many identical structures is indicated by the reference number.

The width of the cross-sectional contour of the connecting bar 20 at the insertion end is mated with the cross-sectional contour of the receiving groove 21 for easy insertion, but the cross-sectional contour of the connecting bar 20 at the distal end is larger than the width of the cross-sectional contour of the receiving groove 21 in the mounting hole 43, thus that insertion of block 3 at the distal end of connecting bar 20 is prevented, and thus erroneous insertion of block 3 is eliminated. The contour extension described is not shown in the figures, but it can be easily understood.

There are many ways to increase the width of the contour of the cross section of the connecting bar 20 at the distal end. You can increase the size of the cross section of the first lamellar branch 40 or the second lamellar branch 41 or both of them. The increase in the width of the contour of the cross section should not be large. Essentially, it would be sufficient to increase to a small extent only to such an extent that the distal end of the connecting bar 20 can still be inserted into the aforementioned mounting hole 43, but cannot be easily inserted into the rest of the receiving groove 21 or can be inserted into it by pressing with significant effort. Thus, the operator easily determines the difference between the insert on the right side of the connecting bar, where the insert is unobstructed, and there is a slight glide of the receiving groove on the connecting bar, and the insert on the wrong side, where the unobstructed insert is not possible.

Now with reference to FIG. 7a-7d describe how the mutual adaptation of at least one of the connecting bars 20 and its receiving groove 21 is arranged to be connected using the transmission of force by friction.

In these three embodiments of the invention shown in FIG. 7c (the right, middle, left parts of the figure, separated by a zigzag line to indicate three possible embodiments of the invention), distance reduction means 49, 50 applied to the free edge of at least one of the rod-shaped protrusions 46, 47 are applied, thus that the distance between the free ends of the protrusions is reduced to a smaller distance d ', and thus, the transfer of friction force is achieved by at least partially reducing the distance between the opposite free edges of the pairs s rod-shaped protrusions 46, 47 facing each other, from d to d '.

In the part shown on the left in FIG. 7c, the distance reducing means 49 is a protrusion 49 formed on both opposite free edges of a pair of two rod-shaped protrusions 46, 47 facing each other. In the part shown to the right in FIG. 7c, the distance reducing means 49 is a protrusion 49 formed on only one free edge of a pair of two rod-shaped protrusions 46, 47 facing each other.

In the part shown in the center of FIG. 7c, the distance-reducing means 50 are two bulges 50 formed on both free edges of a pair of two rod-shaped protrusions 46, 47 facing each other.

In the embodiment shown in FIG. 7b, contour expanding means are applied, applied to the contour in cross section of the connecting bar 20 'shown in the central part of FIG. 7b, in such a way that friction is transmitted by at least partially increasing the cross-sectional contour of the connecting bar 20 '. The contour-expanding means is a means 60 for increasing the thickness, for example, additionally thickening at least partially increasing the thickness h ′ of the second lamellar branch 41 ′, making it larger than the thickness h of the unchanged second lamellar branch 40 of the other two connecting bars 20 so that a transmission is achieved friction forces at least partially increasing the thickness h ′ of the second lamellar branch 41 ′.

In these two embodiments shown in FIG. 7d (on the right and left parts of the figure, separated by a zigzag line to indicate two possible embodiments of the invention), at least one front extension means 51, 51 ′ is applied, applied to at least one of the front plates with long edges 11 of the mounting plate 2 or the mounting wall 45 of the housing 4. The friction force is transmitted by the jamming effect when the unit 3 is connected to the mounting plate 2. On the left in FIG. 7d shows that the front expansion means is a bulge 51 protruding from the front plate 11 with the long edges of the mounting plate 2. To the right in FIG. 7d shows that the front expansion means is a bulge 51 ’that extends from the mounting wall 45 of the housing 4.

In FIG. 3a and 3b, an embodiment of the invention is shown in which an alternative or additional means is used to attach the housing 4 of the unit 3 to the mounting plate 2. An elastic mounting lever 52 is applied, which is loaded in a holding position. An elastic mounting lever is formed in the mounting wall 45 of the block body 4 by the slots 53, 54, 55. The mounting lever has a locking element 56, here in the form of a locking protrusion that extends from the mounting wall 45. In the front plate 11 with recesses of the mounting plate 2, recesses are formed 57, one of which is shown in FIG. 4. The recesses are arranged in a raster order corresponding to the raster of the connecting bars 20 and the receiving grooves 21, so that each of the recesses 57 is located between two adjacent connecting bars 21, just as each elastic mounting lever 52 is located between two adjacent receiving grooves 21. No the need to have as many elastic mounting levers as recesses. For small enclosures, just one elastic fastener may suffice. In the embodiment shown in FIG. 3a, only two elastic mounting levers are applied, which are located one on the left, one on the right, but not in the center. Each elastic mounting lever 52 is configured to have elastic locking engagement with a corresponding recess 57.

The free end of the elastic fastening lever 52 has a pushing member 58 at its end for pressing the end portion of the elastic fastening lever 52 to the inside of the housing 4. The locking element 56 can be released by pressing the pressing element 58 and, thus, by pressing the fastening lever 52 to the inside of the housing 4 to release the locking clutch. At least one spacer element 59 located on the mounting wall 45 of the housing 4 is located near the locking member 56. The purpose of the spacer is to limit the displacement of the elastic arm when the mounting wall 45 of the housing 4 is pressed against a flat surface.

As can be seen in FIG. 6, the pushing member 58 protrudes from the upper surface of the mounting plate 2 when the unit is attached to the mounting plate. Thus, the pushing member 58 is accessible for pressing operation with a finger or a tool, even when the housing 4 is attached to the mounting plate. Thus, it is possible to detach an individual housing from a combination of housings arranged in a row and attached to a mounting plate, even from within the combination.

List of Reference Items

1 - Distribution block

2 - The extended assembly level

3 - Block

4 - Case

5 - Support part

6 - Support part

7 - Mounting structure

8 - Connecting part

9 - Connecting part

11 - Front plate with long edges

12 - Front plate with long edges

13 - Narrow plate with short edges

14 - Narrow plate with short edges

20 - Connecting bar

21 - receiving groove

32 - Mounting rail

33 - Microswitch

34 - Edge of the supporting structure

40 - The first lamellar branch

41 - The second lamellar branch

42 - Mounting edge

43 - Mounting hole

44 - The second edge

45 - Installation wall

46 - Rod-like projection

47 - Rod-like protrusion

48 - Insert end

49 - Distance-reducing protrusion means 46

50 - Distance-reducing protrusion means 46, 47

51 - Front expansion tool

51 '- Front expansion tool

52 - Elastic mounting lever

53 - Groove-shaped notch

54 - groove in the form of a groove

55 - Groove cut

56 - Locking element

57 - Recess

58 - Push element

59 - Spacer

60 - Thickness increasing agent

100 - Terminal Block Device

w - Groove Width 21

w '- Width of the second branch

t - The thickness of the protrusions 46, 47

t '- Thickness of the first branch 40

h - Thickness of the second lamellar branch 41

d - Free distance between the free ends of the protrusions 46, 47

d '- Reduced free distance between the free ends of the protrusions 46, 47

Claims (16)

1. The device (100) of the terminal block, which has an elongated mounting plate (2), formed in the form of an elongated rod with two rectangular front plates (11, 12) with long edges provided with connecting parts (8, 9) at its opposite narrow ends (13, 14) for their connection with the supporting parts (5, 6) of the supporting structure (7), while the indicated device (100) of the terminal block has blocks (3) mating with the mounting plate (2) next to each other in a row moreover, these blocks (3) have an insulated housing (4), and each housing (3) and mount zhnaya strap (2) have mating connecting device (21, 20) for insertion blocks (3) in the mounting plate (2) transversely to the longitudinal direction of the mounting plate (2), characterized in that each housing (4) has a mounting wall (45) and at least one receiving groove (21) in the mounting wall (45) and that the mounting plate (2) has a series of connecting bars (20), departing from one of its two rectangular front plates (11) with long edges and oriented transverse to the longitudinal direction of the mounting plate (2) in such a way that the receiving groove (21) and connecting bars (20) form mating connecting devices, and the connecting bar (20) has T -shaped cross echenie branch with the first plate (40) extending from one of the two rectangular front plate (11) with the long edges, and the second branch of the plate (41) formed at the free end of the first leg (40) and perpendicular to it. 2. The terminal block device (100) according to claim 1, characterized in that the mounting wall (45) has a mounting edge (42), and that the receiving groove (21) has a mounting hole (43) in the mounting edge (42) extending from the mounting edge (42) upward in the direction of the second edge (44) of the housing (4), located against the mounting edge (43), and the fact that the connecting bar (20) and the receiving groove (21) are made with the possibility of sliding interaction, when the connecting bar (20) is inserted into the receiving groove (21) in the mounting hole (43). 3. The device according to p. 2, characterized in that the second lamellar branch (41) is made with the ability to be guided inside the receiving groove (21), and that there are two rod-shaped protrusions (46, 47), departing from the mounting wall (45) in the receiving groove (21), while the thickness (t) of the protrusions (46, 47) corresponds to the distance from the second lamellar branch (41) to the front plate (11) with long edges, leaving a gap (d) between their opposite free edges corresponding to thickness (t ') of the first branch (40). 4. The device according to p. 3, characterized in that the connecting block (20) has an insertable end (48) and a distal end opposite the inserted end (48), and the width of the cross-sectional contour of the connecting bar (20) at the distal end greater than the width of the cross-sectional contour of the receiving groove (21) in the mounting hole (43), so that insertion of the block (3) at the distal end of the connecting bar (20) is prevented, and thus, incorrect insertion of the block (3) is eliminated . 5. The device according to p. 3, characterized in that the mutual adaptation of at least one connecting bar (20) and the corresponding receiving groove (21) is made for connection using the transmission of force by friction. 6. The device according to p. 5, characterized in that it contains a distance-reducing means (49, 50) deposited on the free edge of at least one of the rod-shaped protrusions (46, 47) so that the transmission of friction by means of at least at least partially reducing the distance (d) between the opposite free edges of the pair of rod-shaped protrusions (46, 47) facing each other. 7. The device according to claim 6, characterized in that the distance-reducing means (49, 50) is a protrusion (49) or a bulge (50) formed at least on one of the opposite free edges of a pair of two rod-shaped protrusions (46, 47) , facing each other. 8. The device according to claim 5, characterized in that it contains means for expanding the circuit applied to the transverse contour of the connecting bar (20) in such a way that friction is transmitted at least partially by increasing the contour of the cross section of the connecting bar (20) . 9. The device according to claim 8, characterized in that the contour-expanding means is a thickness-increasing means (60), at least partially increasing the thickness (h) of the second lamellar branch (41), so that friction is transmitted by at least partially increasing the thickness (h) of the second lamellar branch (41). 10. The device according to p. 5, characterized in that it contains at least one front expansion device (51, 51 '), applied to at least one of the front plate (11) with long edges of the mounting plate (2) or mounting wall (45) of the housing (4) in such a way that friction is transmitted by the effect of jamming when the unit (3) is connected to the mounting plate (2). 11. The device according to claim 10, characterized in that the front expansion means is a bulge (51) protruding from the front plate (11) with long edges of the mounting plate (2). 12. The device according to p. 10, characterized in that the front expansion means is a bulge (51 '), protruding from the mounting wall (45) of the housing (4). 13. The device according to any one of the preceding paragraphs, characterized in that the elastic mounting lever (52), which is loaded in the holding position, is formed in the mounting wall (45) of the block housing (4) by means of slots (53, 54, 55), wherein the mounting lever has a locking element (56), departing from the mounting wall (45), which is configured to resiliently engage with a corresponding recess (57) formed in the front plate (11) with long edges of the mounting plate (2), while the locking element (56) may be released by pressing the mounting lever (52) to the inside of the housing (4). 14. The device according to p. 13, characterized in that the free end of the elastic mounting lever (52) has a pushing element (58) at its end for pushing the end part of the elastic mounting lever (52) to the inside of the housing (4) to release the locking clutch . 15. The device according to p. 14, characterized in that near the locking element (56) is located at least one spacer element (59) formed on the mounting wall (45) of the housing (4) to limit the displacement of the elastic arm when pressing the mounting wall ( 45) housing (4) to a flat surface.

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