CN219469242U - Stainless steel cable pay-off rack - Google Patents

Abstract

The utility model provides a stainless steel cable pay-off rack, which comprises a support, wherein a plurality of cross beams capable of rotating freely relative to the support are arranged on the support, a pay-off frame for placing cables is rotationally connected to the cross beams, the pay-off frame comprises a winding part and a limiting part for fixing the cables to the winding part, the support comprises a bottom support rod, a stand column vertically and fixedly arranged on the bottom support rod, a reinforcing beam arranged between the bottom support rod and the stand column and a connecting beam arranged between the stand columns, the cross beams are horizontally and rotationally arranged on the stand columns, and a pair of mounting assemblies which are oppositely arranged are fixedly arranged on the stand columns.

Description

Stainless steel cable pay-off rack

Technical Field

The utility model relates to the technical field of cables, in particular to a stainless steel cable pay-off rack.

Background

The stainless steel heating cable is formed by assembling and combining a stainless steel sheath, an intermediate insulating layer and an internal heating wire, and is subjected to repeated stretching and annealing to obtain a finished product. In the production process, the cable is coiled by a coiling machine, uncoiled, annealed by an annealing furnace and coiled. Because stainless steel is repeatedly drawn, the toughness of the cable is reduced, and the cable is easy to spring open when the stainless steel cable is unwound, so that the cable is wound. However, the existing stainless steel cable pay-off rack is mainly used for placing cables in a simple winding mode, so that a plurality of adverse effects exist in the aspect of cable taking and placing, and meanwhile, the winding mode is not ideal in cable fixing effect and is easy to cause the cables to drop from the winding connecting shaft.

Disclosure of Invention

In order to solve the technical problems, the utility model provides a stainless steel cable pay-off rack which can realize convenient taking and putting of cables and has good fixing effect on the cables, and the specific technical scheme is as follows:

the utility model provides a stainless steel cable pay off rack, includes the support, be provided with a plurality of crossbeams that can rotate for the support freedom on the support, rotate on the crossbeam and be connected with the pay off frame that is used for placing the cable, the pay off frame includes winding portion and is used for being fixed in the spacing portion of winding portion with the cable.

Preferably, the support comprises a bottom support rod, an upright post vertically fixed on the bottom support rod, a reinforcing beam arranged between the bottom support rod and the upright post, and a connecting beam arranged between the upright posts.

Preferably, the cross beam is horizontally rotatably arranged on the upright post.

Preferably, the stand is last to have set firmly two a set of installation component that set up relatively, the installation component includes two relative first mounting pieces that set up at the stand lateral wall and the second mounting piece that sets up between first mounting piece, the crossbeam tip is equipped with the adapter shaft with the switching of second mounting piece.

Preferably, the beam is rotatably connected with a rotating shaft for rotating the pay-off frame.

Preferably, the pay-off frame comprises a plurality of support rods distributed at intervals circumferentially, an inner check ring fixedly arranged at the top of the support rods, an outer check ring concentrically arranged at the periphery of the inner check ring and connected with the outer end part of the support rods, and an upper check ring concentrically arranged between the inner check ring and the outer check ring and fixedly connected with the outer check ring, wherein the vertical heights of the inner check ring, the upper check ring and the outer check ring relative to the support rods are gradually decreased.

Preferably, one end of each supporting rod is gathered at the periphery of the rotating shaft, the other end of each supporting rod is circumferentially divergent by taking the axis of the rotating shaft as the center, and the tail end of each supporting rod extends upwards to be fixedly connected with the outer baffle ring.

Preferably, a first connecting rod is arranged between the inner retainer ring and the supporting rod, and a second connecting rod is arranged between the upper retainer ring and the outer retainer ring.

According to the technical scheme, the utility model has the following beneficial effects: according to the utility model, when the stainless steel cable is annealed and uncoiled, the corresponding paying-off frame is rotated and pulled out of the support so as to facilitate the cable to be put into the winding part, after the cable is put into the paying-off frame, the stainless steel cable can be automatically dispersed due to the elastic force after being released, at the moment, the cable is limited in the paying-off frame under the limiting effect of the limiting part, the paying-off frame is pushed back to the support to be fixed, one end of the cable is pulled out of the paying-off frame during annealing, and uncoiling and annealing are completed through the annealing furnace.

Drawings

FIG. 1 is a perspective view of the present utility model;

FIG. 2 is an enlarged view of a portion A of FIG. 1;

FIG. 3 is a side view of the present utility model;

FIG. 4 is a schematic diagram of a pay-off frame;

fig. 5 is a side view of a pay-off spool.

In the figure: 10. a bracket; 110. a bottom strut; 120. a column; 130. a stiffening beam; 140. a connecting beam; 151. a first mounting tab; 152. a second mounting plate; 143. a transfer shaft; 20. a cross beam; 210. a rotating shaft; 30. paying-off frames; 310. a support rod; 320. an inner retainer ring; 330. an outer retainer ring; 340. an upper retainer ring; 350. a first connecting rod; 360. and a second connecting rod.

Detailed Description

The present utility model will be described in detail below with reference to the drawings and detailed embodiments, and before the technical solutions of the embodiments of the present utility model are described in detail, the terms and terms involved will be explained, and in the present specification, the components with the same names or the same reference numerals represent similar or identical structures, and are only limited for illustrative purposes.

Referring to fig. 1, a stainless steel cable pay-off rack comprises a support 10, wherein a plurality of beams 20 capable of rotating freely relative to the support 10 are arranged on the support 10, a pay-off frame 30 for placing cables is connected to the beams 20 in a rotating mode, the pay-off frame 30 comprises a winding portion and a limiting portion for fixing the cables to the winding portion, when the stainless steel cables are annealed and uncoiled, the corresponding pay-off frame 30 is pulled out of the support 10 in a rotating mode so that the cables are placed in the winding portion, after the cables are placed in the pay-off frame 30, the stainless steel cables are automatically scattered due to the action of elasticity after being released, at the moment, the cables are limited in the pay-off frame 30 under the limiting action of the limiting portion, the pay-off frame 30 is pushed back to be fixed in the support 10, one ends of the cables are pulled out of the pay-off frame 30 during annealing, and uncoiling annealing is completed through an annealing furnace.

As a preferred technical solution of the present utility model, referring to fig. 3, the bracket 10 includes a bottom support 110, a column 120, a reinforcement beam 130 and a connection beam 140, the column 120 is vertically fixed on the bottom support 110, the reinforcement beam 130 is disposed between the bottom support 110 and the column 120, the connection beam 140 is disposed between the columns 120, specifically, fixedly disposed on top of the column 120, the bottom support 110 is used as a bottom support, the column 120 and the connection beam 140 form a main body support structure, and the reinforcement beam 130 plays a role of improving the connection stability between the column 120 and the bottom support 110.

Further, the cross beam 20 is horizontally disposed on the upright 120 and is rotationally connected with the upright 120, however, it should be noted that the cross beam 20 is not limited to be horizontally disposed along the upright 120, and may be obliquely disposed along the upright 120, and only needs to satisfy the requirement that the cross beam 20 is rotationally disposed relative to the upright 120.

As a preferred technical solution of the present utility model, referring to fig. 2, a set of mounting assemblies are fixedly arranged on the upright 120, each mounting assembly includes a first mounting plate 151 and a second mounting plate 152, the number of the first mounting plates 151 is two, and the first mounting plates are oppositely arranged on the side wall of the upright 120, and the second mounting plates 152 are arranged between the first mounting plates 151, so that the second mounting plates 152 in the two mounting assemblies form a space for placing the cross beam 20, and the end portion of the cross beam 20 is provided with a transfer shaft 143 which is transferred to the second mounting plates 152, thereby realizing the rotational connection between the cross beam 20 and the upright 120 through the transfer shaft 143.

Further, in order to rotate the pay-off frame 30 along the beam 20, a rotating shaft 210 is rotatably connected to the beam 20, and the rotating shaft 210 is used for rotating the pay-off frame 30 relative to the beam 20.

As a preferred technical solution of the present utility model, referring to fig. 4 and 5, the pay-off frame 30 includes a plurality of support rods 310, an inner retainer ring 320, an outer retainer ring 330 and an upper retainer ring 340, where the number of the support rods 310 is a plurality of and circumferentially spaced, the inner retainer ring 320 is fixedly disposed at the top of the support rods 310, specifically, the inner retainer ring 320 is disposed near the inner end of the support rods 310, the outer retainer ring 330 is concentrically disposed with the inner retainer ring 320 and is disposed at the periphery of the inner retainer ring 320, and simultaneously, the outer retainer ring 330 is connected with the outer end of the support rods 310, the upper retainer ring 340 is also concentrically disposed with the inner retainer ring 320 and is located between the inner retainer ring 320 and the outer retainer ring 330, and the upper retainer ring 340 is fixedly connected with the outer retainer ring 330, and further, the vertical heights of the inner retainer ring 320, the upper retainer ring 340, the outer retainer ring 330 and the upper retainer ring 330 are sequentially decreased with respect to the support rods 310, so that an annular winding portion is formed by the support rods 310, the inner retainer ring 320, the outer retainer ring 330 and the upper retainer ring 340, which are used for placing cables, and the support rods can also be fixed.

Further, one end of the supporting rods 310 is gathered around the shaft 210, i.e. the inner end of the supporting rod 310 is centered around the shaft 210, and the other end of the supporting rod 310 is centered around the shaft 210, i.e. the outer end of the supporting rod extends upwards to be fixedly connected with the outer ring 330, so that the supporting rod 310 starts from the shaft 210 to form an L-shaped structure, so as to form an annular space for placing cables with the inner ring 320, the outer ring 330 and the upper ring 340.

Further, a first connecting rod 350 is disposed between the inner retainer ring 320 and the support rod 310, the first connecting rod 350 is convenient for fixing the inner retainer ring 320, a second connecting rod 360 is disposed between the upper retainer ring 340 and the outer retainer ring 330, and the second connecting rod 360 is convenient for fixing the upper retainer ring 340.

When the annealing and uncoiling device is used, when a stainless steel cable is annealed and uncoiled, the corresponding uncoiling frame 30 is pulled out of the support 10, the cable is placed in the frame, the stainless steel cable can be automatically scattered due to the action of elasticity after being loosened, at the moment, the outer retainer ring 330, the upper retainer ring 340 and the inner retainer ring 320 of the uncoiling frame 30 limit the cable in the frame, the uncoiling frame 30 is pushed back into the support 10 by utilizing the rotation of the cross beam 20 relative to the upright 120, one end of the cable is pulled out from the upper retainer ring 340 of the uncoiling frame 30 during annealing, and uncoiling and annealing are completed through an annealing furnace.

The above-described embodiments are merely illustrative of the preferred embodiments of the present utility model and are not intended to limit the scope of the present utility model, and various modifications and improvements made by those skilled in the art to the technical solution of the present utility model should fall within the scope of protection defined by the claims of the present utility model without departing from the spirit of the present utility model.

Claims (8)

1. The utility model provides a stainless steel cable pay off rack, includes support (10), its characterized in that, be provided with a plurality of crossbeams (20) that can freely rotate for support (10) on support (10), rotate on crossbeam (20) and be connected with pay off frame (30) that are used for placing the cable, pay off frame (30) include winding portion and are used for being fixed in the spacing portion of winding portion with the cable.

2. The stainless steel cable pay-off stand according to claim 1, characterized in that the bracket (10) comprises a bottom pole (110), a column (120) vertically fixed on the bottom pole (110), a reinforcement beam (130) arranged between the bottom pole (110) and the column (120), and a connection beam (140) arranged between the columns (120).

3. The stainless steel cable pay-off stand according to claim 2, characterized in that the cross beam (20) is horizontally rotatably arranged on the upright (120).

4. A stainless steel cable pay-off rack according to claim 3, characterized in that the upright (120) is fixedly provided with a set of mounting assemblies which are oppositely arranged in pairs, the mounting assemblies comprise first mounting pieces (151) which are oppositely arranged on the side wall of the upright (120) and second mounting pieces (152) which are arranged between the first mounting pieces (151), and the end part of the cross beam (20) is provided with a transfer shaft (143) which is transferred with the second mounting pieces (152).

5. Stainless steel cable pay-off rack according to claim 3 or 4, characterised in that the cross beam (20) is rotatably connected with a rotation shaft (210) for rotation of the pay-off rack (30).

6. The stainless steel cable pay-off rack according to claim 5, wherein the pay-off frame (30) comprises a plurality of support rods (310) distributed at intervals circumferentially, an inner retainer ring (320) fixedly arranged at the top of the support rods (310), an outer retainer ring (330) concentrically arranged at the periphery of the inner retainer ring (320) and connected with the outer side end part of the support rods (310), and an upper retainer ring (340) concentrically arranged between the inner retainer ring (320) and the outer retainer ring (330) and fixedly connected with the outer retainer ring (330), wherein the vertical heights of the inner retainer ring (320), the upper retainer ring (340) and the outer retainer ring (330) relative to the support rods (310) are sequentially decreased.

7. The stainless steel cable pay-off rack according to claim 6, wherein one end of the plurality of support rods (310) is gathered at the periphery of the rotating shaft (210), the other end of the support rods (310) is circumferentially divergent with the axis of the rotating shaft (210) as the center, and the tail ends thereof extend upwards to be fixedly connected with the outer baffle ring (330).

8. The stainless steel cable pay-off stand according to claim 7, characterized in that a first connecting rod (350) is arranged between the inner retainer ring (320) and the supporting rod (310), and a second connecting rod (360) is arranged between the upper retainer ring (340) and the outer retainer ring (330).