CN213116949U

CN213116949U - Can splice skeleton

Info

Publication number: CN213116949U
Application number: CN202021893853.XU
Authority: CN
Inventors: 曲鸣; 聂红伟; 汤龙舟; 秦耕; 徐华勒; 张旭怡; 欧阳明
Original assignee: Hangzhou Banghui Automation Engineering Technology Co ltd; China Nuclear Power Operation Technology Corp Ltd
Current assignee: Hangzhou Banghui Automation Engineering Technology Co ltd; China Nuclear Power Operation Technology Corp Ltd
Priority date: 2020-09-02
Filing date: 2020-09-02
Publication date: 2021-05-04
Anticipated expiration: 2030-09-02

Abstract

The utility model provides a can splice skeleton constitutes a square frame by first base plate, in this frame, a plurality of second base plate mutually perpendicular vertically and horizontally staggered arrangement to first base plate height is half of second base plate height, both lower bottom surface parallel and level, on two adjacent sides of aforementioned square frame, first base plate and second base plate cross section set up the first cylinder that has first counter bore, on two adjacent sides in addition of the frame, first base plate and second base plate cross section set up the second cylinder that has first boss. Particularly, a third column, a fourth column, a fifth column and a sixth column are arranged on four angular points of the splicing framework, so that the strength of the angular point positions is improved, the columns on the angular points can be spliced into smooth columns, and the appearance is neat and elegant; in addition, the first column body and the second column body on the side edge of the framework are mutually clamped, so that the spliced framework is very firm.

Description

Can splice skeleton

Technical Field

The utility model relates to a can splice skeleton, concretely relates to a can splice skeleton for installing mosaic function piece.

Background

The mosaic instrument control screen is an important component of a large-scale enterprise scheduling monitoring system all the time, and is widely applied to industries such as nuclear power, coal, environmental protection, railways, aviation, chemical engineering and the like. The instrument control panel usually needs to be laid with a supporting framework before installing corresponding functional devices. For such a supporting framework, common techniques are: 1) the integrated casting type supporting framework is heavy, not flexible and changeable, and cannot well cope with various situations on site; 2) a modular support frame, as taught in ZL201410127591.9, is patented as a keel frame for at least mounting a plurality of mosaic coverings, which keel frame, while being easily portable and flexible for field installation, is still cumbersome to install. Therefore, there is a need in the art for a new solution to solve this problem.

Disclosure of Invention

The utility model discloses the technical problem that will solve is: the utility model provides a can splice skeleton for installing mosaic function piece, it can carry out nimble concatenation according to actual need, and the skeleton tow sides after the concatenation are all comparatively level, intensity is higher.

The utility model provides a can splice skeleton constitutes a square frame by first base plate, and in this frame, a plurality of second base plate mutually perpendicular vertically and horizontally staggered arranges to first base plate height is the half of second base plate height, bottom surface parallel and level under both, its characterized in that: on two adjacent sides of the square frame, a first column body with a first counter bore is arranged at the intersection of the first substrate and the second substrate, on the other two adjacent sides of the square frame, a second column body with a first boss is arranged at the intersection of the first substrate and the second substrate, and a third column body, a fourth column body, a fifth column body and a sixth column body are respectively arranged at four corner points of the square frame, namely the intersection of the first substrate; and the fifth cylinder and the sixth cylinder are spliced to form an eighth cylinder with a smooth outer surface.

Preferably, the first counter bore and the first boss are in concave-convex matching relationship.

Preferably, the seventh column has a second boss, the eighth column has a second groove, and the second boss and the second groove are in a concave-convex fit. Furthermore, the seventh cylinder and the second cylinder are the same in shape, and the eighth cylinder and the first cylinder are the same in shape.

Preferably, the first column and the second column are hollow cylinders.

Typically, the fifth column is formed from section 1/4 of the first column, the sixth column is formed from section 3/4 of the first column, the third column is formed from section 1/4 of the second column, and the fourth column is formed from section 3/4 of the second column.

Preferably, the first cylinder and the second cylinder are spliced to form a tenth cylinder with a smooth outer surface.

Preferably, ninth pillars are provided at the positions where the second substrates intersect with each other. Furthermore, the ninth cylinder is hollow cylinder, the height of the ninth cylinder is greater than that of the second substrate, and the ninth cylinder is arranged in the middle of the second substrate in the height direction.

Preferably, the ninth cylinder and the tenth cylinder have the same shape.

It should be noted that the frame that can be spliced can be used alone, and also can be used after a plurality of frames that can be spliced are spliced.

Through the design scheme, the utility model discloses the beneficial effect who brings does: the third column, the fourth column, the fifth column and the sixth column are arranged on four angular points of the splicing framework, so that the strength of the angular point positions is improved, the columns on the angular points can be spliced into smooth columns, and the appearance is neat and elegant; in addition, the first column body and the second column body on the side edge of the framework are mutually clamped, so that the spliced framework is very firm.

Drawings

Fig. 1 is a schematic diagram of a three-dimensional structure of a spliceable framework in an embodiment of the present invention;

FIG. 2 is a schematic structural diagram of a spliced position after two spliceable frameworks are spliced with each other; (first splicing type)

FIG. 3 shows a schematic structural diagram of a spliced position after two spliceable frameworks are spliced with each other; (second splicing type)

FIG. 4 shows a schematic structural diagram of four spliceable frameworks after being spliced with each other;

Detailed Description

Embodiments of the present invention will be described below with reference to the drawings.

As shown in fig. 1 to fig. 3, a frame capable of being spliced is a square frame formed by a first substrate (1), in the frame, a plurality of second substrates (2) are arranged vertically and horizontally in a staggered manner, and the height of the first substrate (1) is half of the height of the second substrate (2), and the lower bottom surfaces of the first substrate and the second substrate are flush, and is characterized in that: on two adjacent sides of the square frame, a first cylinder (3) with a first counter bore (31) is arranged at the intersection of the first substrate (1) and the second substrate (2), on the other two adjacent sides of the frame, a second cylinder (4) with a first boss (41) is arranged at the intersection of the first substrate (1) and the second substrate (2), and a third cylinder (5), a fourth cylinder (6), a fifth cylinder (7) and a sixth cylinder (8) are respectively arranged at four corner points of the square frame, namely the intersection of the first substrate (1); the third cylinder (5) and the fourth cylinder (6) are spliced to form a seventh cylinder (56) with a smooth outer surface, and the fifth cylinder (7) and the sixth cylinder (8) are spliced to form an eighth cylinder (78) with a smooth outer surface.

Preferably, the seventh cylinder (56) is provided with a second boss (561), the eighth cylinder (78) is provided with a second groove (781), and the second boss and the second groove are in concave-convex matching. Furthermore, the seventh cylinder (56) and the second cylinder (4) are the same in shape, and the eighth cylinder (78) and the first cylinder (3) are the same in shape.

Preferably, the first column (3) and the second column (4) are hollow cylinders.

Preferably, as shown in fig. 4, the first cylinder (3) and the second cylinder (4) are spliced to form a tenth cylinder (10) with a smooth outer surface.

Preferably, as shown in fig. 1, ninth pillars (9) are provided at the positions where the second substrates (2) intersect with each other. Furthermore, the ninth cylinder is hollow and cylindrical, the height of the ninth cylinder is larger than that of the second substrate (2), and the ninth cylinder (9) is arranged in the middle of the second substrate (2) in the height direction.

Preferably, as shown in fig. 4, the ninth cylinder (9)) and the tenth cylinder (10) have the same shape.

The above embodiment is only a preferable embodiment of the present invention, but is not limited to the above embodiment. Obviously, the spliceable frameworks can be used independently or spliced with each other. The design mode or design thought pointed out by the utility model should be considered within the protection scope of the utility model.

Claims

1. The utility model provides a can splice skeleton constitutes a square frame by first base plate, and in this frame, a plurality of second base plate mutually perpendicular vertically and horizontally staggered arranges to the height of first base plate is the half of second base plate height, its characterized in that: on two adjacent sides of the frame, a first column body with a first counter bore is arranged at the intersection of the first substrate and the second substrate, on the other two adjacent sides of the frame, a second column body with a first boss is arranged at the intersection of the first substrate and the second substrate, and a third column body, a fourth column body, a fifth column body and a sixth column body are respectively arranged at the intersection of the first substrate and the second substrate; and the fifth cylinder and the sixth cylinder are spliced to form an eighth cylinder with a smooth outer surface.

2. A spliceable framework as claimed in claim 1, wherein: the seventh column body is provided with a second boss, and the eighth column body is provided with a second groove; the second boss and the second groove are in concave-convex matching relationship.

3. A spliceable backbone according to claim 1 or 2, wherein: the seventh cylinder is the same as the second cylinder in shape, and the eighth cylinder is the same as the first cylinder in shape.

4. A spliceable framework as claimed in claim 1, wherein: the first cylinder and the second cylinder are hollow cylinders, and the first counter bore and the first boss are in concave-convex matching relation.

5. A spliceable framework as claimed in claim 1, wherein: and the first cylinder and the second cylinder are spliced to form a tenth cylinder with a smooth outer surface.

6. A spliceable framework as claimed in claim 1, wherein: ninth columns are arranged at the position where the second substrates are staggered with each other.

7. The spliceable framework of claim 6, wherein: the ninth cylinder and the tenth cylinder are the same in shape.

8. The spliceable framework of claim 6, wherein: the ninth cylinder is in a hollow cylinder shape, and the height of the ninth cylinder is greater than that of the second substrate; and in the height direction, the ninth column is arranged in the middle relative to the second substrate.

9. A spliceable framework as claimed in claim 1, wherein: the splicing framework can be used independently, and a plurality of splicing frameworks can be spliced and then used.