CN219997060U - Multi-angle experimental compaction device for massive metal samples - Google Patents

Abstract

The utility model discloses a multi-angle experimental compacting device for a block-shaped metal sample, which comprises a base, a workbench, a controller, a mounting block, a chute, an elastic traction rope and a sliding block, wherein the compacting device is arranged above the base, a compacting plate structure is arranged at the bottom of the compacting device, the compacting plate is driven by a telescopic connecting rod compacting plate to stretch, so that the inclination angle of the compacting plate is changed, the multi-angle change of the compacting device is realized, the application range of the device is improved, the multi-angle experiment of the metal sample is facilitated, the compacting plate is driven by a crank lever to compact the block-shaped metal sample, the automatic compaction of the metal sample is realized, and the working efficiency is effectively improved.

Description

Multi-angle experimental compaction device for massive metal samples

Technical Field

The utility model relates to the field of metal smelting, in particular to a multi-angle experimental compaction device for a massive metal sample.

Background

In the field of metal smelting, component detection is required after metal in the smelting process is sampled, so that timely monitoring of the production process or component detection is realized on finished metal, the quality of finished metal delivered from a factory is ensured, and a device for compacting a metal sample is required in the detection process.

The application number CN202211244390.8 discloses a compressing and cleaning device and method for detecting a massive metal sample, the device comprises a workbench and a detecting head arranged in the center of the workbench, wherein a compressing mechanism and a cleaning mechanism are respectively arranged on two sides of the detecting head, the compressing mechanism comprises a first rotary cylinder fixedly arranged on the workbench, a swing arm is fixedly connected to a rotary table of the first rotary cylinder, a compressing cylinder is fixedly arranged at the end part of the swing arm, and an elastic compressing mechanism is fixedly connected to a telescopic rod of the compressing cylinder; the cleaning mechanism comprises a second rotary cylinder fixed on the workbench, and a lower swinging plate is fixedly connected to a rotary table of the second rotary cylinder.

When the device is used, the fixed pressing mechanism is adopted to press the metal sample from top to bottom in parallel, the pressing block cannot be adjusted in pressing angle due to the structure, when different directions of the metal sample need to be detected, the device cannot meet the requirements of users, the following detection process cannot be carried out, and the multi-angle experiment of the metal sample is not facilitated.

Disclosure of Invention

Therefore, in order to solve the above-mentioned shortcomings, the present utility model provides a multi-angle experimental compaction device for a bulk metal sample.

The utility model is realized in such a way, a multi-angle experimental compacting device for a block-shaped metal sample is constructed, the device comprises a base, a workbench fixedly connected to the top end surface of the base, a controller arranged on the right side of the workbench, a mounting block fixedly embedded in the center of the top end surface of the workbench, a first sliding chute arranged on the front side and the rear side of the mounting block, elastic traction ropes fixedly connected to the front side and the rear side of the mounting block, a sliding block fixedly connected to the tail ends of the elastic traction ropes, a connecting block fixedly connected to the top end surface of the base, the sliding block is slidingly embedded into the first sliding chute, and the compacting device is arranged on the top end surface of the base.

Preferably, the compressing device includes:

the electric push rod is fixedly connected to the base;

the switching block is rotationally connected to the front end of the push rod of the electric push rod through an auxiliary connecting rod P, and the auxiliary connecting rod P is rotationally connected with the switching block;

the rectangular sliding groove is arranged at the top of the adapter block;

the embedded block is embedded into the rectangular chute in a sliding manner;

the crank lever is fixedly connected to the top end of the embedded block, and the A part of the crank lever is rotationally embedded into the outer wall of the connecting block;

the electric sliding rail is fixedly arranged in the top end of the crank lever;

the second sliding chute is arranged on the left side and the right side of the shell at the top end of the crank lever;

the sliding rail connecting rod is fixedly connected to the left side and the right side of a sliding block on the electric sliding rail, and is slidably embedded into the second sliding groove;

the top end of the rotary connecting rod is rotationally connected to the bottom of the sliding rail connecting rod;

the compacting plate structure is arranged at the bottom of the crank lever.

Preferably, the compacting plate structure includes:

the first mounting block is rotatably connected to the bottom end of the rotary connecting rod;

the pressing plate is fixedly connected to the bottom of the first mounting block;

the second mounting block is fixedly connected to the top end face of the pressing plate;

the rotating block is rotationally connected to the inner side of the second installation block;

the connecting column is fixedly connected to the top end face of the pressing plate and is positioned at the front side of the second mounting block;

the telescopic connecting rod is fixedly connected to the bottom of the rotating block, and the bottom of the push rod of the telescopic connecting rod is rotationally connected with the inside of the top end of the connecting column;

the spring is fixedly connected to the top end of the rotating block

The telescopic rod is fixedly connected to the top end of the rotating block, and is positioned in the spring;

the top of the rotating block is slidably embedded into the groove at the bottom end of the crank lever, and the top of the spring is fixedly connected with the top of the groove at the bottom end of the crank lever.

The utility model has the following advantages: the utility model provides a multi-angle experimental compaction device for a massive metal sample through improvement, which has the following improvement compared with the same type of equipment:

according to the multi-angle experimental compressing device for the massive metal samples, the compressing device is arranged above the base, and the compressing device is driven by the telescopic connecting rod compressing plate to stretch, so that the inclination angle of the compressing plate is changed, the multi-angle change of the compressing device is realized, the using range of the device is enlarged, and the multi-angle experimental compressing device is beneficial to multi-angle experiments of the metal samples.

According to the multi-angle experimental compacting device for the massive metal samples, the compacting plate structure is arranged at the bottom of the compacting device, and the crank bar drives the compacting plate to compact the massive metal samples, so that automatic compaction of the metal samples is realized, and the working efficiency is effectively improved.

Drawings

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is a schematic view of the structure of the compressing apparatus of the present utility model;

FIG. 3 is an exploded view of the compression device of the present utility model;

FIG. 4 is an exploded view of the compression device of the present utility model;

FIG. 5 is a schematic view of the structure of the compacting plate of the present utility model;

fig. 6 is an exploded view of the compacting plate structure of the utility model.

Wherein: the device comprises a base-1, a workbench-2, a controller-3, a mounting block-4, a first sliding chute-5, an elastic traction rope-6, a sliding block-7, a connecting block-8, a pressing device-9, an electric push rod-91, a switching block-92, a rectangular sliding chute-93, an embedded block-94, a crank lever-95, an electric sliding rail-96, a second sliding chute-97, a sliding rail connecting lever-98, a rotating connecting rod-99, a pressing plate structure-910, a first mounting block-9101, a pressing plate-9102, a second mounting block-9103, a rotating block-9104, a connecting column-9105, a telescopic connecting rod-9106, a spring-9107 and a telescopic rod-9108.

Detailed Description

The principles and features of the present utility model are described below with reference to fig. 1-6, the examples being provided for illustration only and not for limitation of the scope of the utility model. The utility model is more particularly described by way of example in the following paragraphs with reference to the drawings. Advantages and features of the utility model will become more apparent from the following description and from the claims. It should be noted that the drawings are in a very simplified form and are all to a non-precise scale, merely for convenience and clarity in aiding in the description of embodiments of the utility model.

It will be understood that when an element is referred to as being "fixed to" another element, it can be directly on the other element or intervening elements may also be present. When a component is considered to be "connected" to another component, it can be directly connected to the other component or intervening components may also be present. When an element is referred to as being "disposed on" another element, it can be directly on the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like are used herein for illustrative purposes only.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this utility model belongs. The terminology used herein in the description of the utility model is for the purpose of describing particular embodiments only and is not intended to be limiting of the utility model. The term "and/or" as used herein includes any and all combinations of one or more of the associated listed items.

Embodiment one:

referring to fig. 1 to 6, the multi-angle experimental compaction device for a block metal sample of the present utility model includes a base 1, a workbench 2 fixedly connected to a top end surface of the base 1, a controller 3 disposed on a right side of the workbench 2, a mounting block 4 fixedly embedded in a center of the top end surface of the workbench 2, a chute 1 disposed on front and rear sides of the mounting block 4, elastic traction ropes 6 fixedly connected to front and rear sides of the mounting block 4, a slider 7 fixedly connected to an end of the elastic traction ropes 6, a connection block 8 fixedly connected to the top end surface of the base 1, the slider 7 slidably embedded in the chute 1, and a compaction device 9 disposed on the top end surface of the base 1.

The compacting plate structure 910 includes, first installation piece 9101 rotates to be connected in rotation connecting rod 99 bottom, compacting plate 9102 fixed connection is in first installation piece 9101 bottom, second installation piece 9103 fixed connection is in compacting plate 9102 terminal surface, rotation piece 9104 rotates to be connected in second installation piece 9103 inboard, spliced pole 9105 fixed connection is in compacting plate 9102 terminal surface, and be located second installation piece 9103 front side, flexible connecting rod 9106 fixed connection is in rotation piece 9104 bottom, and the push rod bottom and the inside rotation of spliced pole 9105 top of flexible connecting rod 9106 are connected, spring 9107 fixed connection is in rotation piece 9104 top, flexible pole 9108 fixed connection is in rotation piece 9104 top, and flexible pole 9108 is located spring 9107 inside, rotation piece 9104 top slip embedding crank lever 95 bottom's fluting is inside, spring 9107 top and crank lever 95 bottom's fluting top fixed connection

The elastic traction rope 6 is used for traction of the sliding block 7, so that the sliding block 7 clamps and positions the massive metal sample, and the follow-up compression process is convenient.

The working principle of the multi-angle experimental compaction device for the massive metal sample based on the embodiment 1 is as follows: the staff put through the device on power, then put into installation piece 4 tops again the cubic metal sample, under the effect of elasticity haulage rope 6, slider 7 carries out the centre gripping to cubic metal sample, staff rethread controller 3 circuit control electronic slide rail 96 inside slider back-and-forth movement, thereby drive slide rail even thick stick 98 and remove in spout two 97, at slide rail even thick stick 98 removal in-process, the rotating block 9104 that is located the clamp plate 9102 top rotates in the inboard of second installation piece 9103, and flexible connecting rod 9106 stretches out and draws back under the drive of clamp plate 9102, finally make the inclination between rotating connecting rod 99 and the clamp plate 9102 change, lead to clamp plate 9102 to the contact angle of experimental article to change under slide rail even thick stick 98 drive, realize closing device's multi-angle change, the application range of device has been improved, be favorable to the multi-angle experiment of metal sample.

Embodiment two:

referring to fig. 1 to 6, in the multi-angle experimental compaction device for a bulk metal sample according to the present utility model, compared with the first embodiment, the embodiment further includes: the compressing device 9 comprises an electric push rod 91 fixedly connected to a base 1, an adapter block 92 is rotatably connected to the front end of the push rod of the electric push rod 91 through an auxiliary connecting rod P, the auxiliary connecting rod P is rotatably connected with the adapter block 92, a rectangular sliding groove 93 is formed in the top of the adapter block 92, an embedded block 94 is slidably embedded into the rectangular sliding groove 93, a crank bar 95 is fixedly connected to the top end of the embedded block 94, an A part of the crank bar 95 is rotatably embedded into the outer wall of the connecting block 8, an electric sliding rail 96 is fixedly installed inside the top end of the crank bar 95, a sliding groove II 97 is formed in the left side and the right side of a shell of the top end of the crank bar 95, a sliding rail connecting bar 98 is fixedly connected to the left side and the right side of a sliding block on the electric sliding rail 96, the sliding rail connecting bar 98 is slidably embedded into the sliding groove II 97, the top end of the rotating connecting rod 99 is rotatably connected to the bottom of the sliding rail connecting bar 98, and a compressing plate structure 910 is arranged at the bottom of the crank bar 95.

The redundant extrusion force of the pressing device 9 can be removed under the mutual cooperation of the spring 9107 and the telescopic rod 9108, so that the pressing device 9 is prevented from excessively extruding the metal sample.

In this embodiment: after the angle adjustment of the compacting plate 9102 is finished, a worker controls the electric push rod 91 to start to operate through a circuit of the controller 3, the electric push rod 91 moves forwards under the control of the circuit and passes through the auxiliary connecting rod P, the adapter block 92 rotates inside the connecting block 8, the adapter block 92 pushes the embedded block 94 to rotate outwards, the angle of the crank lever 95 is driven to change, the crank lever 95 drives the compacting plate 9102 to compact a blocky metal sample, automatic compaction of the metal sample is achieved, and the working efficiency is effectively improved.

According to the multi-angle experimental compressing device for the block-shaped metal sample, the compressing device 9 is arranged above the base 1, the compressing plate structure 910 is arranged at the bottom of the compressing device 9, the compressing plate 9102 is driven by the telescopic connecting rod 9106 to stretch, so that the inclination angle of the compressing plate 9102 is changed, the multi-angle change of the compressing device is realized, the using range of the device is improved, the multi-angle experiment of the metal sample is facilitated, the compressing plate 9102 is driven by the crank lever 95 to compress the block-shaped metal sample, the automatic compression of the metal sample is realized, and the working efficiency is effectively improved.

The basic principle and main characteristics of the utility model and the advantages of the utility model are shown and described above, standard parts used by the utility model can be purchased from market, special-shaped parts can be customized according to the description of the specification and the drawings, the specific connection modes of the parts adopt conventional means such as mature bolt rivets and welding in the prior art, the machinery, the parts and the equipment adopt conventional models in the prior art, and the circuit connection adopts conventional connection modes in the prior art, so that the description is omitted.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present utility model. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the utility model. Thus, the present utility model is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (8)

1. The utility model provides a multi-angle experiment closing device of cubic metal sample, includes base (1), fixed connection in workstation (2) of base (1) terminal surface, set up in controller (3) on workstation (2) right side, fixed embedding installation piece (4) at workstation (2) terminal surface center, set up spout one (5) in both sides around installation piece (4), fixed connection in elasticity haulage rope (6) of both sides around installation piece (4), fixed connection in slider (7) of elasticity haulage rope (6) end, fixed connection in connecting block (8) of base (1) terminal surface, wherein, slider (7) slip embedding spout one (5) are inside, its characterized in that still includes:

the pressing device (9) is arranged on the top end face of the base (1).

2. Multi-angle experimental compaction device for bulk metal samples according to claim 1, characterized in that the compaction device (9) comprises:

an electric push rod (91), wherein the electric push rod (91) is fixedly connected to the base (1);

the switching block (92), the switching block (92) is connected to the front end of the push rod of the electric push rod (91) through an auxiliary connecting rod P in a rotating way, and the auxiliary connecting rod P is connected with the switching block (92) in a rotating way;

the rectangular sliding groove (93), the rectangular sliding groove (93) is arranged at the top of the adapter block (92).

3. Multi-angle experimental compaction device for bulk metal samples according to claim 2, characterized in that the compaction device (9) further comprises:

the embedded block (94), the said embedded block (94) is slipped and embedded in the said rectangular runner (93);

the crank lever (95), crank lever (95) fixed connection in embedded block (94) top, and the A department of crank lever (95) rotates and imbeds in connecting block (8) outer wall.

4. A multi-angle experimental compaction device for bulk metal samples according to claim 3, wherein the compaction device (9) further comprises:

the electric sliding rail (96), the electric sliding rail (96) is fixedly arranged in the top end of the crank lever (95);

and the second sliding chute (97) is arranged on the left side and the right side of the top end shell of the crank lever (95).

5. The multi-angle experimental compaction device for bulk metal samples according to claim 4, wherein the compaction device (9) further comprises:

the sliding rail connecting rod (98), the sliding rail connecting rod (98) is fixedly connected to the left side and the right side of a sliding block on the electric sliding rail (96), and the sliding rail connecting rod (98) is slidably embedded into the second sliding groove (97);

the top end of the rotating connecting rod (99) is rotatably connected to the bottom of the sliding rail connecting rod (98);

and the pressing plate structure (910), wherein the pressing plate structure (910) is arranged at the bottom of the crank lever (95).

6. The multi-angle experimental compaction device for a bulk metal sample according to claim 5, wherein the compaction plate structure (910) comprises:

the first mounting block (9101), the first mounting block (9101) is rotatably connected to the bottom end of the rotary connecting rod (99);

a hold-down plate (9102), the hold-down plate (9102) being fixedly connected to the bottom of the first mounting block (9101);

and the second mounting block (9103), wherein the second mounting block (9103) is fixedly connected to the top end surface of the pressing plate (9102).

7. The multi-angle experimental compaction device for a bulk metal sample according to claim 6, wherein the compaction plate structure (910) further comprises:

a rotating block (9104), the rotating block (9104) being rotatably connected to the inside of the second mounting block (9103);

a connecting column (9105), wherein the connecting column (9105) is fixedly connected to the top end surface of the pressing plate (9102) and is positioned at the front side of the second mounting block (9103);

a telescopic connecting rod (9106), the telescopic connecting rod (9106) is fixedly connected with the rotating block (9104)

The bottom of the push rod of the telescopic connecting rod (9106) is rotatably connected with the inside of the top end of the connecting column (9105).

8. The multi-angle experimental compaction device for a bulk metal sample according to claim 7, wherein the compaction plate structure (910) further comprises:

a spring (9107), the spring (9107) is fixedly connected to the top end of the rotating block (9104);

a telescopic rod (9108), the telescopic rod (9108) is fixedly connected to the top end of the rotating block (9104),

and the telescopic rod (9108) is positioned inside the spring (9107);

the top of the rotating block (9104) is slidably embedded into a groove at the bottom end of the crank lever (95), and the top of the spring (9107) is fixedly connected with the top of the groove at the bottom end of the crank lever (95).