CN214685094U - Copper alloy heat insulation jig structure - Google Patents

Abstract

The utility model relates to a disconnected hot tool technical field just discloses a disconnected hot tool structure of copper alloy, including the base, the inboard activity at base middle part has cup jointed the copper alloy and has contained the groove part, and the outside that the copper alloy contains the groove part is provided with first cylinder subassembly, the top surface fixedly connected with backup pad of base one side. The utility model discloses the first cylinder subassembly and the second cylinder subassembly that set up can contain the groove part and carry out the concentric centre gripping of automatic positioning with disconnected hot structure spare to the copper alloy respectively under the cooperation support of base and movable plate, make the copper alloy contain the center between groove part and disconnected hot structure spare on same vertical line, reduce staff's intensity of labour when satisfying the suit condition, and then follow-up cooperation backup pad, the lifting unit that steps down, from the installation part, the movable plate, the back is used together to the roof pressure mechanism of first two segmentation groove assembly equipments of stepping down, can realize disconnected hot structure spare and copper alloy and contain the installation of groove part high efficiency and automation, be applicable to mass production.

Description

Copper alloy heat insulation jig structure

Technical Field

The utility model relates to a disconnected hot tool technical field specifically is a disconnected hot tool structure of copper alloy.

Background

The copper alloy is an alloy formed by adding one or more other elements into pure copper serving as a matrix, the pure copper is purple red, the pure copper is also called as red copper and has excellent electrical conductivity, thermal conductivity, ductility and corrosion resistance, the copper alloy is mainly used for manufacturing electrical equipment such as a generator, a bus, a cable, a switching device, a transformer and the like and heat conducting equipment such as a heat exchanger, a pipeline, a flat plate collector of a solar heating device and the like, at present, in order to enable the copper alloy to have heat insulation performance, a heat insulation material is usually added into a copper alloy workpiece through manual operation, although the purpose can be achieved, the labor intensity of workers is high, the working efficiency is low, and the mass production requirements cannot be met, so that the copper alloy heat insulation jig structure is provided for solving the problems.

SUMMERY OF THE UTILITY MODEL

Not enough to prior art, the utility model provides a disconnected hot tool structure of copper alloy has solved the problem that above-mentioned background art provided.

The utility model provides a following technical scheme: the utility model provides a copper alloy heat insulation tool structure, includes the base, the inboard activity at base middle part has cup jointed the copper alloy and has contained the slot part, the outside that the copper alloy contains the slot part is provided with first cylinder component, the top surface fixedly connected with backup pad of base one side, the front fixed mounting at backup pad top has the lifting unit that steps down, the bottom fixedly connected with movable plate of the lifting unit that steps down, first groove of stepping down has been seted up to the inside of movable plate, the inside activity in first groove of stepping down has cup jointed the heat insulation structure spare, the outside at heat insulation structure spare top is provided with second cylinder component and space limiting unit respectively, the top surface of space limiting unit is provided with from the installation component, second cylinder component, from the installation component, the equal fixed mounting in the top surface of movable plate in space limiting unit three's bottom.

Carefully, first cylinder subassembly is inside including four first roof pressure cylinders, and four first roof pressure cylinders use the central point of base as the benchmark to carry out the circumference array setting, four the equal fixed connection in bottom surface of first roof pressure cylinder is on the inner wall at base top, the first clamp plate of one side fixedly connected with of first roof pressure cylinder, the first blotter of one side fixedly connected with of first clamp plate, the inboard at the base top is cup jointed with the equal activity of first blotter to first clamp plate.

Carefully, the inside of the part of stepping down elevating part is including first electric putter, and the fixed surface in the middle part of first electric putter is connected with two fixed lagging, two the reverse side fixed connection of fixed lagging is on the front in backup pad middle part.

The second cylinder assembly comprises four second jacking cylinders, the four second jacking cylinders are arranged in a circumferential array mode with the central axis of the self-installation component as the reference, the bottom surfaces of the four second jacking cylinders are fixedly connected to the top surface of the movable plate, one side of each second jacking cylinder is fixedly connected with a second pressing plate, one side of each second pressing plate is fixedly connected with a second cushion pad, the bottom surfaces of the second pressing plate and the second cushion pads are not in contact with the top surface of the movable plate, guide rails are clamped inside the two sides of the movable plate respectively, the reverse sides of the guide rails are fixedly connected to the front sides of the two sides of the supporting plate, and the central point of the second cylinder assembly and the central point of the first cylinder assembly are on the same vertical line.

Carefully, including second electric putter from the inside of installing the part, and the fixed mount that has cup jointed in the surface at second electric putter middle part, second electric putter's bottom fixedly connected with holding down plate.

Carefully, the inside of spacing part in space is including limiting plate, and the inboard at limiting plate middle part has seted up the second groove of stepping down, two supports of bottom surface fixedly connected with of limiting plate both sides, the bottom fixed connection of support is at the top surface of movable plate, the second groove of stepping down's length width value is greater than the length width value from the inside holding down plate of installation part, but is less than the length width value of disconnected hot structure spare.

Compared with the prior art, the utility model discloses possess following beneficial effect:

1. the utility model discloses the first cylinder subassembly and the second cylinder subassembly that set up can contain the groove part and carry out the concentric centre gripping of automatic positioning with disconnected hot structure spare to the copper alloy respectively under the cooperation support of base and movable plate, make the copper alloy contain the center between groove part and disconnected hot structure spare on same vertical line, reduce staff's intensity of labour when satisfying the suit condition, and then follow-up cooperation backup pad, the lifting unit that steps down, from the installation part, the movable plate, the back is used together to the roof pressure mechanism of first two segmentation groove assembly equipments of stepping down, can realize disconnected hot structure spare and copper alloy and contain the installation of groove part high efficiency and automation, be applicable to mass production.

2. The utility model discloses the spacing part in space that sets up can make disconnected hot structure highly carry out reasonable limit for height location at the first inslot suit that steps down, when avoiding artifical installation, disconnected hot structure appears too high or the suit position of crossing low excessively in the first inslot that steps down, further promotes the reliability of the operation of above-mentioned two segmentation roof pressure mechanisms.

Drawings

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

FIG. 2 is a left side view of the structure of the present invention;

FIG. 3 is a schematic bottom view of the structure of the present invention;

fig. 4 is an enlarged schematic view of the structure of the present invention at a in fig. 1.

In the figure: 1. a base; 2. a copper alloy channel-containing component; 3. a first cylinder assembly; 31. a first jacking cylinder; 32. a first platen; 33. a first cushion pad; 4. a support plate; 5. a abdication lifting component; 51. a first electric push rod; 52. fixing the sleeve plate; 6. moving the plate; 7. a first abdicating groove; 8. a heat-insulated structural member; 9. a second cylinder assembly; 91. a second jacking cylinder; 92. a second platen; 93. a second cushion pad; 10. a self-mounting component; 101. a second electric push rod; 102. a fixed mount; 103. a lower pressing plate; 11. a space limiting component; 111. a limiting plate; 112. a second abdicating groove; 113. a support; 12. a guide rail.

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. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-4, a copper alloy heat insulation jig structure comprises a base 1, a copper alloy groove-containing component 2 is movably sleeved on the inner side of the middle of the base 1, a first cylinder component 3 is arranged on the outer side of the copper alloy groove-containing component 2, four first jacking cylinders 31 are arranged in the first cylinder component 3, the four first jacking cylinders 31 are circumferentially arrayed on the basis of the central point of the base 1, the bottom surfaces of the four first jacking cylinders 31 are fixedly connected to the inner wall of the top of the base 1, one side of each first jacking cylinder 31 is fixedly connected with a first pressing plate 32, one side of each first pressing plate 32 is fixedly connected with a first cushion pad 33, the first pressing plate 32 and the first cushion pad 33 are movably sleeved on the inner side of the top of the base 1, the four first jacking cylinders 31 in the first cylinder component 3 are used for driving the first pressing plate 32 and the first cushion pad 33 which are respectively connected to move in a similar manner, the automatic clamping and positioning operation of the copper alloy groove-containing component 2 can be realized, the automatic service performance of the primary lifting device is realized, the top surface of one side of the base 1 is fixedly connected with the supporting plate 4, the front surface of the top of the supporting plate 4 is fixedly provided with the abdicating lifting component 5, the inside of the abdicating lifting component 5 comprises a first electric push rod 51, the surface of the middle part of the first electric push rod 51 is fixedly connected with two fixed sleeve plates 52, the reverse surfaces of the two fixed sleeve plates 52 are fixedly connected on the front surface of the middle part of the supporting plate 4, the abdicating lifting component 5 takes the first electric push rod 51 as a power component to provide abdicating lifting for a subsequently arranged movable plate 6 and a structure arranged by the top surface of the movable plate 6, the bottom of the abdicating lifting component 5 is fixedly connected with the movable plate 6, the inside of the movable plate 6 is provided with a first abdicating groove 7, the heat insulation structural component 8 is movably sleeved in the inside of the first abdicating groove 7, the outer side of the top of the adiabatic structure 8 is provided with a second cylinder assembly 9 and a space limiting component 11, the inside of the second cylinder assembly 9 comprises four second jacking cylinders 91, the four second jacking cylinders 91 are arranged in a circumferential array mode by taking the central axis from the installation component 10 as a reference, the bottom surfaces of the four second jacking cylinders 91 are fixedly connected to the top surface of the moving plate 6, one side of each second jacking cylinder 91 is fixedly connected with a second pressing plate 92, one side of each second pressing plate 92 is fixedly connected with a second cushion pad 93, the bottom surfaces of the second pressing plates 92 and the second cushion pads 93 are not in contact with the top surface of the moving plate 6, the insides of the two sides of the moving plate 6 are respectively clamped with a guide rail 12, the reverse surfaces of the guide rails 12 are fixedly connected to the fronts of the two sides of the supporting plate 4, the central point of the second cylinder assembly 9 and the central point of the first cylinder assembly 3 are on the same vertical line, and the second pressing plates 92 and the second cylinder 91 connected with the four second pressing cylinders 91 in the second assembly 9 are respectively The two buffer pads 93 perform approximate movement to realize automatic clamping and positioning operation on the heat insulation structural part 8, after the first cylinder assembly 3 is matched, the copper alloy groove-containing component 2 and the heat insulation structural part 8 are automatically and concentrically clamped, the self-installation component 10 comprises a second electric push rod 101, the surface of the middle part of the second electric push rod 101 is fixedly sleeved with a fixing frame 102, the bottom end of the second electric push rod 101 is fixedly connected with a lower pressing plate 103, and after the two-section type jacking mechanism assembled by the support plate 4, the abdicating lifting component 5, the self-installation component 10, the moving plate 6 and the first abdicating groove 7 is used together, the high-efficiency and automatic installation of the heat insulation structural part 8 and the copper alloy groove-containing component 2 can be realized, the automatic installation device is suitable for mass operation production, the self-installation component 10 is arranged on the top surface of the space limiting component 11, the second cylinder assembly 9, From installing component 10, the equal fixed mounting in the top surface of movable plate 6 in space stop component 11 three's bottom, the inside of space stop component 11 includes limiting plate 111, and limiting plate 111 middle part's inboard has been seted up the second groove of stepping down 112, two supports 113 of the bottom surface fixedly connected with of limiting plate 111 both sides, the bottom fixed connection of support 113 is at the top surface of movable plate 6, the length and width value in second groove of stepping down 112 is greater than the length and width value from installing component 10 inside holding down plate 103, but is less than the length and width value of adiabatic structure 8, rely on space stop component 11 as adiabatic structure 8 highly carry out reasonable height-limiting location in the inside suit of first groove of stepping down 7, when avoiding manual installation, adiabatic structure 8 appears too high or the suit position of crossing excessively in the inside of first groove of stepping down 7, further promote the reliability of the operation of above-mentioned two segmentation roof pressure mechanisms.

The working principle is as follows: when the device is used, the copper alloy groove-containing component 2 is placed at the approximate position of the middle part of the top surface of the base 1, then the four first jacking cylinders 31 in the first cylinder component 3 are synchronously started, then the telescopic rods in the four first jacking cylinders 31 push the first pressing plates 32 and the first buffer cushions 33 which are respectively connected with the four first jacking cylinders to clamp and position the four surfaces of the copper alloy groove-containing component 2, after the device is completed, the heat-insulating structural component 8 is sleeved into the space limiting component 11 from bottom to top through the first yielding groove 7, then the four second jacking cylinders 91 in the second cylinder component 9 are synchronously started according to the same principle as the first cylinder component 3, then the telescopic rods in the four second jacking cylinders 91 push the second pressing plates 92 and the second buffer cushions 93 which are respectively connected with the heat-insulating structural component 8 to clamp and position the four surfaces at the top of the heat-insulating structural component 8, and after the heat-insulating structural component 8 is aligned with the groove body in the copper alloy groove-containing component 2, then, the first electric push rod 51 in the abdicating lifting component 5 is started, the telescopic rod in the first electric push rod 51 pushes the movable plate 6 and the structure arranged at the top of the movable plate 6 to move downwards for the first section, so that the bottom of the heat-insulating structural component 8 is firstly sleeved with a part of the structure in the copper alloy groove-containing component 2, then the four second jacking air cylinders 91 in the second air cylinder assembly 9 are closed, the clamping and positioning of the heat-insulating structural component 8 are finished, then the second electric push rod 101 in the self-mounting component 10 is started, then the telescopic rod in the second electric push rod 101 pushes the lower press plate 103 to pass through the second abdicating groove 112 to press the heat-insulating structural component 8 downwards for the second section to descend, so that the heat-insulating structural component 8 is completely sleeved in the copper alloy groove-containing component 2, after the second electric push rod 101 is closed, the lower press plate 103 is reset, and the first electric push rod 51 is closed, and resetting the movable plate 6 and the structure arranged at the top of the movable plate 6, closing the four first jacking cylinders 31 in the first cylinder assembly 3, and taking out the combination of the copper alloy groove-containing component 2 and the adiabatic structural component 8.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Simultaneously in the utility model discloses an in the drawing, fill the pattern and just do not do any other injecions for distinguishing the picture layer.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. The utility model provides a disconnected hot tool structure of copper alloy, includes base (1), its characterized in that: the copper alloy that has cup jointed in the inboard activity of base (1) middle part contains slot part (2), the outside that the copper alloy contains slot part (2) is provided with first cylinder subassembly (3), top surface fixedly connected with backup pad (4) of base (1) one side, the front fixed mounting at backup pad (4) top has the lifting unit that steps down (5), the bottom fixedly connected with movable plate (6) of the lifting unit that steps down (5), first groove (7) of stepping down has been seted up to the inside of movable plate (6), the inside activity of first groove (7) of stepping down has cup jointed disconnected hot structure spare (8), the outside at disconnected hot structure spare (8) top is provided with second cylinder subassembly (9) and space limiting part (11) respectively, the top surface of space limiting part (11) is provided with from installing part (10), second cylinder subassembly (9), The bottoms of the self-installation part (10) and the space limiting part (11) are fixedly installed on the top surface of the movable plate (6).

2. The copper alloy heat insulation jig structure according to claim 1, characterized in that: first cylinder subassembly (3) is inside including four first roof pressure cylinders (31), and four first roof pressure cylinders (31) use the central point of base (1) to carry out circumference array setting, four the equal fixed connection in bottom surface of first roof pressure cylinder (31) is on the inner wall at base (1) top, one side fixedly connected with first clamp plate (32) of first roof pressure cylinder (31), one side fixedly connected with first blotter (33) of first clamp plate (32), first clamp plate (32) and the equal activity of first blotter (33) cup joint the inboard at base (1) top.

3. The copper alloy heat insulation jig structure according to claim 1, characterized in that: the inside of the abdicating lifting component (5) comprises a first electric push rod (51), the surface of the middle part of the first electric push rod (51) is fixedly connected with two fixed sleeve plates (52), and the reverse sides of the fixed sleeve plates (52) are fixedly connected to the front side of the middle part of the support plate (4).

4. The copper alloy heat insulation jig structure according to claim 1, characterized in that: the interior of the second cylinder component (9) comprises four second jacking cylinders (91), and four second jacking cylinders (91) are arranged in a circumferential array by taking the central axis of the self-mounting component (10) as a reference, the bottom surfaces of the four second jacking cylinders (91) are all fixedly connected with the top surface of the moving plate (6), one side of the second jacking cylinder (91) is fixedly connected with a second pressure plate (92), one side of the second pressure plate (92) is fixedly connected with a second cushion pad (93), the bottom surfaces of the second pressure plate (92) and the second cushion pad (93) are not contacted with the top surface of the moving plate (6), the inner parts of the two sides of the moving plate (6) are respectively clamped with a guide rail (12), the back surface of the guide rail (12) is fixedly connected with the front surfaces of the two sides of the support plate (4), the central point of the second cylinder assembly (9) and the central point of the first cylinder assembly (3) are on the same vertical line.

5. The copper alloy heat insulation jig structure according to claim 1, characterized in that: the inside of installing component (10) is including second electric putter (101), and the fixed surface at second electric putter (101) middle part has cup jointed mount (102), the bottom fixedly connected with holding down plate (103) of second electric putter (101).

6. The copper alloy heat insulation jig structure according to claim 1, characterized in that: the inside of space limiting component (11) is including limiting plate (111), and the inboard at limiting plate (111) middle part has seted up the second and has stepped down groove (112), two supports (113) of bottom surface fixedly connected with of limiting plate (111) both sides, the bottom fixed connection of support (113) is at the top surface of movable plate (6), the length width value in second groove (112) of stepping down is greater than the length width value from installing component (10) inside holding down plate (103), but is less than the length width value of disconnected hot structure spare (8).

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