CN211143832U - Energy-saving steel structure support frame - Google Patents

Abstract

The utility model relates to the technical field of building construction, in particular to an energy-saving steel structure support frame, which solves the problems that the support frame has small stress area when being supported, the bottom surface of a support plate is fixedly articulated with a first support frame and a second support frame through two first pin shafts respectively, and the right side surface of the first support frame is fixedly connected with two first support columns, the utility model realizes the support of the support plate by opening the first support frame and the second support frame, when a first connecting rod, a fixed rod and a second connecting rod are positioned at the same horizontal plane, the first base and the second base are all contacted with the ground, thereby realizing the increase of the contact area between the support part and the bottom surface and the support strength, avoiding the deformation of the support part due to too small stress area when in support, fixing the connection part of the first connecting rod and the fixed rod with the connection part of the second connecting rod and the fixed rod through a cutting sleeve, the stability of the first connecting rod and the second connecting rod is increased.

Description

Energy-saving steel structure support frame

Technical Field

The utility model relates to a construction technical field especially relates to an energy-conserving steel construction support frame.

Background

In the building industry, the support frame is very common, some components must be supported earlier when the installation to welding installation or overlap joint installation, steel structure support frame receives extensive use because of its light in weight, intensity height, the good, the strong characteristics of deformability of whole rigidity, but safety is the first forever in the building industry, present support frame generally supports by the supporting leg, the lifting surface area during the support is less, leads to the support intensity of support frame lower, for this reason we propose an energy-conserving steel structure support frame to solve above problem.

SUMMERY OF THE UTILITY MODEL

The utility model aims at solving the shortcoming that the lifting surface area is small when having the support frame to support among the prior art, and the energy-conserving steel construction support frame that proposes.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

the utility model provides an energy-conserving steel structure support frame, includes the backup pad, the underrun of backup pad has first carriage and second carriage through two first round pin axles fixed articulated respectively, two first support columns of right flank fixedly connected with of first carriage, every the right-hand member of first support column all articulates through second round pin axle is fixed has the head rod, two second support columns of left flank fixedly connected with of second carriage, every the left end of second support column all articulates through third round pin axle is fixed has the second connecting rod, two dead levers, every have been placed to the below of backup pad both ends all fixed hinge has the fourth round pin axle about the dead lever.

The top ends of the two second connecting rods are fixedly hinged with the right end of the fixed rod through a fourth pin shaft respectively, the top end of each first connecting rod is fixedly hinged with the left end of the fixed rod through the fourth pin shaft, each first supporting block is fixedly connected to the right side face of each first connecting rod, each first base is fixedly connected to the right side face of each first supporting block, each second supporting block is fixedly connected to the left side face of each second connecting rod, each second base is fixedly connected to the left side face of each second supporting block, two groups of baffles which are arranged equidistantly are placed in each first supporting frame and each second supporting frame, and each group of baffles are fixedly connected with the inner side walls of the first supporting frame and the second supporting frame at the left end and the right end.

Preferably, each equal fixedly connected with of upper surface of dead lever blocks two posts, the cutting ferrule has all been cup jointed to the surface of first connecting rod and the surface of second connecting rod, and the draw-in groove has all been seted up to the side that two cutting ferrules are close to each other.

Preferably, each anti-skid pad is placed above each baffle, and the bottom surface of each anti-skid pad is fixedly connected with the upper surface of each baffle.

Preferably, the outer surface of the first supporting block is fixedly connected with two first inclined rods, and the right end of each first inclined rod is fixedly connected with the left side face of the base.

Preferably, the outer surface of the second supporting block is fixedly connected with two second inclined rods, and the left end of each second inclined rod is fixedly connected with the right surface of the second base.

Preferably, the diameter values of the first connecting rod, the second connecting rod and the fixing rod are equal.

Preferably, the width of the clamping groove is larger than the diameter value of the clamping column, and the inner surface of the clamping groove is a smooth surface.

The utility model has the advantages that:

1. utilize first carriage and second carriage to open and realize supporting the backup pad, when head rod, dead lever and second connecting rod were located same horizontal plane, first base and second base all contacted with ground, realized increasing the area of contact of support position and bottom surface, increased support intensity, and the lifting surface area is too little when avoiding supporting, leads to the support position to take place deformation phenomenon.

2. Utilize the cutting ferrule to fix the junction of head rod and fixed rod and the junction of second connecting rod and fixed rod, realize increasing the stability of head rod and second connecting rod, avoid the head rod and the second connecting rod appear folding when using.

3. The non-slip mat has all been placed to the top that utilizes every baffle, and the bottom surface of every non-slip mat all is connected with the last fixed surface of baffle, carries out the antiskid through the non-slip mat to the baffle, avoids appearing the smooth phenomenon of foot when climbing to the top.

Drawings

Fig. 1 is a cross-sectional view of a front view of a first connecting rod of an energy-saving steel structure support frame provided by the present invention;

fig. 2 is a side view of a first support frame of the energy-saving steel structure support frame provided by the present invention;

fig. 3 is a side view of a cutting sleeve of the energy-saving steel structure support frame provided by the utility model;

fig. 4 is the utility model provides an enlarged schematic view of a structure in fig. 1 of energy-conserving steel construction support frame.

In the figure: the anti-skid device comprises a first pin shaft 1, a first supporting column 2, a first supporting frame 3, a first pin shaft 4, a supporting plate 5, a second supporting frame 6, a second inclined rod 7, a second supporting block 8, a second supporting column 9, a second base 10, a third pin shaft 11, an anti-skid pad 12, a baffle 13, a clamping sleeve 14, a clamping groove 15, a first connecting rod 16, a fourth pin shaft 17, a fixed rod 18, a clamping column 19, a second connecting rod 20, a first base 21, a first inclined rod 22 and a first supporting block 23.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments.

Referring to fig. 1-4, an energy-saving steel structure support frame, including backup pad 5, the bottom surface of backup pad 5 is fixed articulated respectively through two first round pin axles 4 and is had first carriage 3 and second carriage 6, two first support columns 2 of right flank fixedly connected with of first carriage 3, the right-hand member of every first support column 2 all has a head rod 16 through the fixed articulated second round pin axle 1, two second support columns 9 of left flank fixedly connected with of second carriage 6, the left end of every second support column 9 all has a second connecting rod 20 through the fixed articulated third round pin axle 11, two dead levers 18 have been placed to the below of backup pad 5, both ends all fix the articulated fourth round pin axle 17 in the left and right sides of every dead lever 18.

The top of two second connecting rods 20 is fixed articulated with the right end of dead lever 18 through fourth round pin axle 17 respectively, the top of every first connecting rod 16 is fixed articulated with the left end of dead lever 18 through fourth round pin axle 17 all, the equal fixedly connected with first supporting shoe 23 of the right flank of every first connecting rod 16, the equal fixedly connected with first base 21 of the right flank of every first supporting shoe 23, the equal fixedly connected with second supporting shoe 8 of the left flank of every second connecting rod 20, the equal fixedly connected with second base 10 of the left flank of every second supporting shoe 8, two sets of equidistance baffle 13 of arranging have all been placed to the inside of first carriage 3 and second carriage 6, both ends respectively with the inside wall fixed connection of first carriage 3 and second carriage 6 about every group baffle 13.

Furthermore, the upper surface of each fixing rod 18 is fixedly connected with two clamping columns 19, the outer surfaces of the first connecting rod 16 and the second connecting rod 20 are sleeved with clamping sleeves 14, and one side surface of each clamping sleeve 14 close to each other is provided with a clamping groove 15.

Further, slipmat 12 has all been placed to the top of every baffle 13, and the bottom surface of every slipmat 12 all is connected with the last fixed surface of baffle 13, carries out the antiskid through slipmat 12 to baffle 13, avoids appearing the smooth phenomenon of foot when climbing up.

Further, the outer fixed surface of the first supporting block 23 is connected with two first diagonal rods 22, the right end of each first diagonal rod 22 is fixedly connected with the left side surface of the base 21, the outer fixed surface of the second supporting block 8 is connected with two second diagonal rods 7, the left end of each second diagonal rod 7 is fixedly connected with the right side surface of the second base 10, the first base 21 and the second base 10 are supported through the first diagonal rods 22 and the second diagonal rods 7, and deformation caused by uneven stress of the first base 21 and the second base 10 is avoided.

Further, the diameter values of the first connecting rod 16, the second connecting rod 20 and the fixing rod 18 are equal, so that the sleeve 14 can slide conveniently, and the clamping column 19 can be clamped inside the clamping groove 15.

Further, the width of the clamping groove 15 is larger than the diameter value of the clamping column 19, and the inner surface of the clamping groove 15 is a smooth surface, so that the clamping sleeve 14 can be conveniently sleeved on the outer surface of the clamping column 19.

In this embodiment, the first support frame 3 and the second support frame 6 are opened, the first support frame 3 is opened to pull the first connecting rod 16 through the second bearing 1, the second support frame 6 pulls the second connecting rod 20 through the third pin 11, the first connecting rod 16 and the second connecting rod 20 pull the fixing column 18 through the fourth pin 17 to move downward, when the first connecting rod 16, the fixing rod 18 and the second connecting rod 20 are located at the same horizontal plane, the first base 21 and the second base 10 are both in contact with the ground, the cutting sleeve 14 is moved to clamp the clamping column 19 inside the clamping groove 15, and the connecting position of the first connecting rod 16 and the fixing rod 18 and the connecting position of the second connecting rod 20 and the fixing rod 18 are fixed through the cutting sleeve 14.

The above, only be the concrete implementation of the preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, the concept of which is equivalent to replace or change, should be covered within the protection scope of the present invention.

Claims (7)

1. The utility model provides an energy-conserving steel construction support frame, includes backup pad (5), its characterized in that: the bottom surface of the supporting plate (5) is fixedly hinged with a first supporting frame (3) and a second supporting frame (6) through two first pin shafts (4), the right side surface of the first supporting frame (3) is fixedly connected with two first supporting columns (2), the right end of each first supporting column (2) is fixedly hinged with a first connecting rod (16) through a second pin shaft (1), the left side surface of the second supporting frame (6) is fixedly connected with two second supporting columns (9), the left end of each second supporting column (9) is fixedly hinged with a second connecting rod (20) through a third pin shaft (11), two fixing rods (18) are placed below the supporting plate (5), and the left end and the right end of each fixing rod (18) are fixedly hinged with a fourth pin shaft (17);

the top ends of the two second connecting rods (20) are fixedly hinged with the right end of the fixed rod (18) through fourth pin shafts (17) respectively, the top end of each first connecting rod (16) is fixedly hinged with the left end of the fixed rod (18) through the fourth pin shafts (17), the right side surface of each first connecting rod (16) is fixedly connected with a first supporting block (23), the right side surface of each first supporting block (23) is fixedly connected with a first base (21), the left side surface of each second connecting rod (20) is fixedly connected with a second supporting block (8), and the left side surface of each second supporting block (8) is fixedly connected with a second base (10), two sets of baffles (13) that the equidistance was arranged have all been placed to the inside of first carriage (3) and second carriage (6), and every group both ends are respectively with the inside wall fixed connection of first carriage (3) and second carriage (6) about baffle (13).

2. The support frame with the energy-saving steel structure as claimed in claim 1, wherein two clamping columns (19) are fixedly connected to the upper surface of each fixing rod (18), the clamping sleeves (14) are sleeved on the outer surfaces of the first connecting rod (16) and the second connecting rod (20), and the clamping grooves (15) are formed in one side surfaces, close to each other, of the two clamping sleeves (14).

3. The energy-saving steel structure support frame according to claim 1, characterized in that a non-slip mat (12) is placed above each baffle (13), and the bottom surface of each non-slip mat (12) is fixedly connected with the upper surface of the baffle (13).

4. The support frame with an energy-saving steel structure as claimed in claim 1, wherein two first diagonal rods (22) are fixedly connected to the outer surface of the first support block (23), and the right end of each first diagonal rod (22) is fixedly connected to the left side surface of the base (21).

5. The energy-saving steel structure supporting frame according to claim 1, wherein two second diagonal rods (7) are fixedly connected to the outer surface of the second supporting block (8), and the left end of each second diagonal rod (7) is fixedly connected with the right surface of the second base (10).

6. The support frame of claim 1, wherein the diameter of the first connecting rod (16) is equal to the diameter of the fixing rod (18), and the diameter of the second connecting rod (20) is equal to the diameter of the fixing rod (18).

7. The support frame with an energy-saving steel structure as claimed in claim 2, wherein the width of the clamping groove (15) is larger than the diameter value of the clamping column (19), and the inner surface of the clamping groove (15) is smooth.

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