CN212366688U - A antidetonation support for installing chute - Google Patents

Abstract

The utility model belongs to the field of electromechanical equipment installation, in particular to an anti-seismic support for installing a cabling rack, which comprises two vertical strut components, two first diagonal strut components, two second diagonal strut components, a first transverse channel steel and a second transverse channel steel; the left end and the right end of the two transverse channel steels are respectively installed on the structural beam through the vertical stay bar assemblies, the left end and the right end of the first transverse channel steel are respectively fixed with the structural beam through the first inclined stay bar assemblies, and the left end and the right end of the second transverse channel steel are respectively fixed with the structural beam through the second inclined stay bar assemblies. The utility model has the advantages that: the ejector pin can rely on two second nuts to adjust the position on the fixing base, just so can make the distance between two ejector pins grow or diminish to adapt to not unidimensional chute, and certain fine setting can also be done to the square nut, and it is more convenient to use.

Description

A antidetonation support for installing chute

Technical Field

The utility model belongs to electromechanical device installs the field, concretely relates to antidetonation support for installing chute.

Background

The anti-seismic support is a support and hanger product used for supporting electromechanical pipeline equipment such as water pipes, air pipes, bridges, racks and the like and providing anti-seismic support, the existing anti-seismic support for supporting the racks is a fixed structure, the installation position of the racks cannot be adjusted, a single anti-seismic support can only support the racks with one size, and no anti-seismic support particularly suitable for double-layer racks or racks with more than double layers is available in the market.

SUMMERY OF THE UTILITY MODEL

In order to compensate for the deficiencies of the prior art, the utility model provides an antidetonation support technical scheme for installing chute.

The anti-seismic support for installing the cabling rack is characterized by comprising two vertical strut assemblies, two first diagonal strut assemblies, two second diagonal strut assemblies, a first transverse channel steel and a second transverse channel steel; the first transverse channel steel and the second transverse channel steel are horizontally arranged from top to bottom, the left ends and the right ends of the two transverse channel steels are respectively installed on the structural beam through vertical stay bar assemblies, the left ends and the right ends of the first transverse channel steel are respectively reinforced and fixed with the structural beam through first inclined stay bar assemblies, and the left ends and the right ends of the second transverse channel steel are respectively reinforced and fixed with the structural beam through second inclined stay bar assemblies; the inclined strut assembly comprises an inclined screw rod, a first connecting plate hinged to the upper end of the inclined screw rod, a second connecting plate hinged to the lower end of the inclined screw rod, a first fixing plate and a second fixing plate, wherein the first fixing plate is installed on the structural beam through a first anchor bolt and hinged to the first connecting plate, and the second fixing plate is hinged to the second connecting plate and installed in a matched mode with the corresponding vertical strut assembly; the left end and the right end of the transverse channel steel are respectively matched with a fixing seat, and an ejector rod used for clamping the cabling rack is screwed on the fixing seat.

The anti-seismic support for the installation cabling rack is characterized in that an inclined channel steel is fixedly sleeved outside an inclined screw.

The anti-seismic support for the installation cabling rack is characterized in that the vertical strut component comprises a vertical screw rod which is installed on the structural beam through a second anchor bolt and vertical channel steel which is fixedly sleeved outside the vertical screw rod.

The anti-seismic support for the installation cabling rack is characterized in that clamping plates and first nuts are arranged on the upper side and the lower side of the end portion of a transverse channel steel, and the clamping plates and the first nuts are sleeved on corresponding vertical screw rods and used for fixing the transverse channel steel on the vertical screw rods.

The anti-seismic support for installing the cabling rack is characterized in that the fixing seat is of an L-shaped structure, one horizontal side of the fixing seat is sleeved on the corresponding vertical screw rod and clamped between the corresponding first nut and the clamping plate, and one vertical side of the fixing seat is used for connecting the ejector rod.

The anti-seismic support for the installation cabling rack is characterized in that the second fixing plate is of an L-shaped structure, one horizontal side of the second fixing plate is sleeved on the corresponding vertical screw rod and clamped between the corresponding first nut and the fixing seat, and the vertical side of the second fixing plate is hinged to the second connecting plate.

The anti-seismic support for the installation of the cabling rack is characterized in that the connecting plate is of an L-shaped structure.

The anti-seismic support for the installation cabling rack is characterized in that the outer end of the ejector rod is in threaded connection with two second nuts, the fixed seat is clamped between the two second nuts, and the inner end of the ejector rod is in threaded connection with the square nut.

Compared with the prior art, the utility model discloses there is following advantage:

1) the ejector rods can be adjusted on the fixed seat by two second nuts, so that the distance between the two ejector rods can be increased or decreased to adapt to wiring racks with different sizes, and the square nuts can be finely adjusted to a certain extent, so that the use is more convenient;

2) the utility model adopts the inclined screw, the two ends of the inclined screw are hinged with the first connecting plate and the second connecting plate, and the two connecting plates are hinged with other parts, so that even if there is installation deviation, the inclined screw can be adjusted back through the inclined screw, and the utility model has the function of deviation rectification;

3) the first transverse channel steel and the second transverse channel steel are respectively supported by the first inclined strut assembly and the second inclined strut assembly, so that the supporting effect is better, and the double-layer cabling rack is particularly suitable for mounting a double-layer cabling rack;

4) the fixing seat, the second fixing plate and the transverse channel steel which are arranged on the same side are connected to the same position, so that the structure is more compact, and the space is saved.

Drawings

FIG. 1 is a schematic view of the structure of the present invention;

FIG. 2 is an enlarged view of FIG. 1 at A;

FIG. 3 is an enlarged view of FIG. 1 at B;

FIG. 4 is an enlarged view of FIG. 1 at C;

FIG. 5 is a right side view of the structure of the present invention;

fig. 6 is an enlarged view of fig. 5 at D.

Detailed Description

The present invention will be further explained with reference to the accompanying drawings.

As shown in the figures, an anti-seismic support for installing a cabling rack comprises two vertical strut assemblies, two first diagonal strut assemblies 50, two second diagonal strut assemblies 40, a first transverse channel steel 1 and a second transverse channel steel 2; first horizontal channel-section steel 1 and the horizontal setting from top to bottom of the horizontal channel-section steel 2 of second, both ends are installed in structural beam 3 through erecting the vaulting pole subassembly respectively about two horizontal channel-section steels, both ends are strengthened fixedly through first vaulting pole subassembly 50 and structural beam 3 respectively about first horizontal channel-section steel 1, both ends are strengthened fixedly through second vaulting pole subassembly 40 and structural beam 3 respectively about the horizontal channel-section steel 2 of second, wherein, first vaulting pole subassembly 50 is mutually perpendicular with first horizontal channel-section steel 2, second vaulting pole subassembly 40 constitutes an obtuse angle with the horizontal channel-section steel of second up to now, first vaulting pole subassembly 50 and the projection mutually perpendicular of second vaulting pole subassembly 40 on the horizontal plane. The inclined strut assembly comprises an inclined screw rod 4, a first connecting plate 5 hinged to the upper end of the inclined screw rod 4, a second connecting plate 6 hinged to the lower end of the inclined screw rod 4, a first fixing plate 8 which is arranged on the structural beam 3 through a first anchor bolt 7 and hinged to the first connecting plate 5, and a second fixing plate 9 which is hinged to the second connecting plate 6 and matched with the corresponding vertical strut assembly; the left end and the right end of the transverse channel steel are respectively matched with a fixed seat 10, and an ejector rod 12 used for clamping the cabling rack 11 is screwed on the fixed seat 10. The first transverse channel steel 1 and the second transverse channel steel 2 are collectively called transverse channel steel, the first vertical stay bar assembly and the second vertical stay bar assembly are collectively called vertical stay bar assemblies, and the first connecting plate 5 and the second connecting plate 6 are collectively called connecting plates.

In order to enhance the structural strength of the oblique screw rod 4, an oblique channel steel 13 is fixedly sleeved outside the oblique screw rod through a bolt.

The vertical stay bar component comprises a vertical screw rod 14 which is arranged on the structural beam 3 through a second anchor bolt 20 and vertical channel steel 15 which is fixedly sleeved outside the vertical screw rod 14, and the vertical channel steel 15 has the same function as the channel steel 13.

The upper and lower both sides of horizontal channel-section steel tip all set up splint 16 and first nut 17, and splint 16 presss from both sides between first nut 17 and horizontal channel-section steel, and splint 16 and first nut 17 cup joint on corresponding perpendicular screw rod 14, and wherein, first nut 17 and perpendicular screw rod 14 spiro union, splint 16 and first nut 17 are used for fixing horizontal channel-section steel on perpendicular screw rod 14. More specifically, fixing base 10 is the L shape structure, and its horizontal one side cup joints on corresponding perpendicular screw 14, and vertical one side is used for connecting ejector pin 12, and second fixed plate 9 also is the L shape structure, and its horizontal one side cup joints on corresponding perpendicular screw 14 equally, and vertical one side is used for articulating with second connecting plate 6, and fixing base 10 and the horizontal one side of second fixed plate 9 all press from both sides tightly between corresponding first nut 17 and splint 16, and the horizontal one side of fixing base 10 is located between second fixed plate 9 horizontal one side and splint 16.

The first connecting plate 5 and the second connecting plate 6 are both L-shaped structures, one side of each L-shaped structure is used for being hinged with the corresponding inclined screw rod 4, and the other side of each L-shaped structure is used for being hinged with the corresponding fixing plate.

One end of the ejector rod 12, which is back to the cabling rack 11, is screwed with two second nuts 18, the vertical side of the fixed seat 10 is clamped between the two second nuts 18, one end of the ejector rod 12, which faces the cabling rack 11, is screwed with a square nut 19, and the cabling rack 11 is clamped by the square nut 19.

The utility model has the advantages that:

1) the ejector rods can be adjusted on the fixed seat by two second nuts, so that the distance between the two ejector rods can be increased or decreased to adapt to wiring racks with different sizes, and the square nuts can be finely adjusted to a certain extent, so that the use is more convenient;

2) the utility model adopts the inclined screw, the two ends of the inclined screw are hinged with the first connecting plate and the second connecting plate, and the two connecting plates are hinged with other parts, so that even if there is installation deviation, the inclined screw can be adjusted back through the inclined screw, and the utility model has the function of deviation rectification;

3) the first transverse channel steel 1 and the second transverse channel steel are respectively supported by the first inclined strut assembly 50 and the second inclined strut assembly 40, so that the supporting effect is better, and the double-layer cabling rack is particularly suitable for mounting a double-layer cabling rack;

4) the fixing seat, the second fixing plate and the transverse channel steel which are arranged on the same side are connected to the same position, so that the structure is more compact, and the space is saved.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; while the invention has been described in detail and with reference to the foregoing embodiments, it will be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; and the modifications or the substitutions do not make the essence of the corresponding technical solutions depart from the scope of the technical solutions of the embodiments of the present invention.

Claims (8)

1. An anti-seismic support for mounting a cabling rack is characterized by comprising two vertical strut assemblies, two first diagonal strut assemblies (50), two second diagonal strut assemblies (40), a first transverse channel steel (1) and a second transverse channel steel (2); the first transverse channel steel (1) and the second transverse channel steel (2) are horizontally arranged from top to bottom, the left ends and the right ends of the two transverse channel steels are respectively installed on the structural beam (3) through vertical strut assemblies, the left ends and the right ends of the first transverse channel steel (1) are respectively reinforced and fixed with the structural beam (3) through first diagonal strut assemblies (50), and the left ends and the right ends of the second transverse channel steel (2) are respectively reinforced and fixed with the structural beam (3) through second diagonal strut assemblies (40); the inclined strut assembly comprises an inclined screw rod (4), a first connecting plate (5) hinged to the upper end of the inclined screw rod (4), a second connecting plate (6) hinged to the lower end of the inclined screw rod (4), a first fixing plate (8) which is installed on the structural beam (3) through a first anchor bolt (7) and hinged to the first connecting plate (5), and a second fixing plate (9) which is hinged to the second connecting plate (6) and matched with the corresponding vertical strut assembly; the left end and the right end of the transverse channel steel are respectively matched with a fixing seat (10), and a mandril (12) used for clamping the cabling rack (11) is screwed on the fixing seat (10).

2. An anti-seismic support for a mounting rack according to claim 1, characterized in that the oblique screw (4) is externally fitted with an oblique channel (13).

3. An anti-seismic support for installation racks, according to claim 1, characterized in that the vertical stay assembly comprises a vertical screw (14) mounted to the structural beam (3) by means of a second anchor bolt (20) and a vertical channel (15) fixed externally to the vertical screw (14).

4. An anti-seismic support for a mounting rack according to claim 3, characterized in that the upper and lower sides of the end of the transverse channel are provided with a clamping plate (16) and a first nut (17), the clamping plate (16) and the first nut (17) are sleeved on the corresponding vertical screw (14) for fixing the transverse channel on the vertical screw (14).

5. An anti-seismic support for installing racks according to claim 4, characterized in that the holders (10) are L-shaped structures, with the horizontal side sleeved on the corresponding vertical screw (14) and clamped between the corresponding first nut (17) and clamping plate (16), and the vertical side for connecting the top bar (12).

6. An anti-seismic support for installing racks according to claim 5, characterized in that the second fixing plate (9) is of L-shaped configuration, with the horizontal side thereof sleeved on the corresponding vertical screw (14) and clamped between the corresponding first nut (17) and the fixed seat (10), and the vertical side thereof hinged to the second connecting plate (6).

7. An anti-seismic support for a mounting rack according to claim 1, wherein the connection plate is of L-shaped configuration.

8. An anti-seismic support for an installation rack according to claim 1, characterized in that the outer end of the post rod (12) is screwed with two second nuts (18), the fixing base (10) is clamped between the two second nuts (18), and the inner end of the post rod (12) is screwed with a square nut (19).

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