CN221528244U - Reactor lead tension detector - Google Patents

Abstract

The utility model relates to the technical field of tension detectors, in particular to a reactor lead tension detector. The electric reactor lead tension detector comprises a test table and an upper supporting arm, wherein one end of one side of the test table is provided with a control panel, hydraulic pumps are arranged in grooves formed in two sides of the upper supporting arm, the top of each hydraulic pump is fixedly connected with a top plate, a clamping assembly is arranged on the bottom surface of the middle of each top plate, the clamping assembly and an auxiliary assembly fixed on the upper surface of the test table are positioned on the same vertical line, in the electric reactor lead tension detector, after a lead passes through the auxiliary assembly arranged on the upper surface of the test table, the two end parts of the lead are clamped and fixed by the clamping assembly at the bottom of the top plate, so that the problem that both ends of the lead are required to be clamped is solved, the test time is saved, and finally, the tensile strength value of the lead is observed through the control panel, and the hydraulic pumps push the top plate and the clamping assembly to carry out tension test on the lead.

Description

Reactor lead tension detector

Technical Field

The utility model relates to the technical field of tension detectors, in particular to a reactor lead tension detector.

Background

The tensile testing machine is also called a universal material testing machine. The universal tester is used for carrying out mechanical stress application for mechanical property tests such as static load, stretching, compression, bending, shearing, tearing, stripping and the like on various materials.

For the tensile force detector, there are many existing technologies, for example:

Chinese patent publication No. CN219065108U discloses a tension detector, which comprises a base plate, wherein a detecting structure is installed on one side of the top outer wall of the base plate, a fixing component is installed on one side of the detecting structure of the top outer wall of the base plate, and a controller is installed on one side of the top outer wall of the base plate; the detection structure comprises a detection column, a lifting groove formed in the outer wall of one side of the detection column, a driving motor arranged on the inner wall of the top of the detection column, a lifting screw arranged on an output shaft of the driving motor, and a mounting rod in threaded connection with the outer wall of the lifting screw. According to the utility model, the central rod is rotated by the driving handle, the contact rollers are mutually close to clamp the silk thread by the central rod through the bevel gear and the fixing screw rod, the driving motor drives the lifting screw rod to rotate, and the lifting screw rod drives the mounting rod to lift the silk thread to apply a force with a fixed value to the silk thread, so that the silk thread is convenient to fix and detect, and the silk thread is prevented from being strongly pressed at the fixed end

However, current pencil pulling force detects machine is when using, intercepts a section pencil generally, drives splint through rotating the bull stick and removes to this is fixed with pencil tip centre gripping, therefore, when fixed pencil, the both ends of pencil all need adopt this kind of fixed mode, thereby reduced fixed efficiency, influence the progress of test, moreover, the centre pole of above-mentioned setting, bevel gear and fixing screw, make the contact roller be close to each other and clip the silk thread, but the couple at top is broken the test piece easily when the test, influence the measurement of final test piece pulling force.

In view of the above, the utility model provides a reactor lead tension detector.

Disclosure of utility model

The utility model aims to solve the defects and provide a tension detector which is convenient for quickly fixing a reactor lead.

Through the auxiliary assembly that is equipped with at the testboard upper surface, pass auxiliary assembly with the lead wire after, the both ends tip of lead wire is fixed by the centre gripping subassembly centre gripping of roof bottom to solved the problem that the lead wire both ends all need the centre gripping, saved test time, finally, observe the tensile strength value of lead wire through control panel, the hydraulic pump promotes roof and centre gripping subassembly and carries out tensile test to the lead wire.

The utility model provides a reactor lead tension detector which comprises a test bench and an upper supporting arm, wherein one end of one side of the test bench is provided with a control panel, hydraulic pumps are arranged in grooves formed in two sides of the upper supporting arm, the tops of the hydraulic pumps are fixedly connected with a top plate, the bottom surface of the middle part of the top plate is provided with a clamping assembly, and the clamping assembly and an auxiliary assembly fixed on the upper surface of the test bench are positioned on the same vertical line.

As a further improvement of the technical scheme, the auxiliary assembly comprises an auxiliary wheel and a limiting wheel, the auxiliary wheel and the auxiliary wheel are respectively and coaxially connected with the rotating shaft, the auxiliary wheel and the limiting wheel are rotationally connected through the rotating shaft and the supporting rod, and the auxiliary wheel and the limiting wheel are tightly attached.

As a further improvement of the technical scheme, the clamping assembly consists of a left clamping plate and a right clamping plate, the left clamping plate and the right clamping plate are rotationally connected and fixed on a connecting shell at the bottom of the top plate, and tooth grooves are formed in the joint positions of the left clamping plate and the right clamping plate.

As a further improvement of the technical scheme, through holes are formed in the left clamping plate and the right clamping plate, a connecting nut is rotated in the through hole formed in the right clamping plate, the nut is in threaded connection with a screw rod, the end part of the screw rod is in sliding connection with a rotating rod, and the diameter of the end part of the rotating rod is larger than the width of the through hole.

Compared with the prior art, the utility model has the beneficial effects that:

In this reactor lead wire pulling force detects machine, through the auxiliary assembly that is equipped with at the testboard upper surface, pass the auxiliary assembly with the lead wire after, the both ends tip of lead wire is fixed by the centre gripping subassembly centre gripping of roof bottom to solved the problem that both ends of lead wire all need the centre gripping, saved test time, finally, observe the tensile strength value of lead wire through control panel, the hydraulic pump promotes roof and centre gripping subassembly and carries out tensile test to the lead wire.

Drawings

The utility model is described in more detail below, by way of example, with reference to the accompanying drawings, in which:

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

FIG. 2 is a schematic view of an auxiliary assembly structure according to the present utility model;

FIG. 3 is a schematic view of the top plate and clamping assembly of the present utility model;

FIG. 4 is a schematic view of the explosive structures of the left and right splints of the present utility model;

fig. 5 is a schematic view of the right clamping plate in the sectional structure of the utility model.

The meaning of each reference sign in the figure is:

100. a test bench; 101. an upper support arm; 102. a control panel;

200. A hydraulic pump; 201. a top plate;

300. An auxiliary component; 301. an auxiliary wheel; 302. a limiting wheel; 303. a support rod; 304. a rotating shaft;

400. A clamping assembly; 401. a left clamping plate; 402. a right clamping plate; 403. a through hole; 404. a screw rod; 405. a rotating rod; 406. and (3) a nut.

Detailed Description

However, current pencil pulling force detects machine is when using, intercepts a section pencil generally, drives splint through rotating the bull stick and removes to this is fixed with pencil tip centre gripping, therefore, when fixed pencil, the both ends of pencil all need adopt this kind of fixed mode, thereby reduced fixed efficiency, influence the progress of test, moreover, the centre pole of above-mentioned setting, bevel gear and fixing screw, make the contact roller be close to each other and clip the silk thread, but the couple at top is broken the test piece easily when the test, influence the measurement of final test piece pulling force.

As shown in fig. 1-5, the device comprises a test bench 100 and an upper supporting arm 101, wherein one end of one side of the test bench 100 is provided with a control panel 102, hydraulic pumps 200 are arranged in grooves formed in two sides of the upper supporting arm 101, the tops of the hydraulic pumps 200 on two sides are fixedly connected with a top plate 201, a clamping assembly 400 is arranged on the bottom surface of the middle part of the top plate 201, the clamping assembly 400 and an auxiliary assembly 300 fixed on the upper surface of the test bench 100 are positioned on the same vertical line, after a lead passes through the auxiliary assembly 300 and passes through the auxiliary assembly 300, the two end parts of the lead are clamped and fixed by the clamping assembly 400 at the bottom of the top plate 201, so that the problem that two ends of the lead need to be clamped is solved, the test time is saved, and finally, the tensile strength value of the lead is observed through the control panel 102, and the hydraulic pumps 200 push the top plate 201 and the clamping assembly 400 to carry out tensile test on the lead.

Specifically, the auxiliary assembly 300 includes an auxiliary wheel 301 and a limiting wheel 302, the auxiliary wheel 301 and the auxiliary wheel 301 are coaxially connected with a rotating shaft 304, the auxiliary wheel 301 and the limiting wheel 302 are rotatably connected through the rotating shaft 304 and a supporting rod 303, the auxiliary wheel 301 and the limiting wheel 302 are tightly attached, firstly, before testing the lead tension of the reactor, a section of lead is cut, the end of the lead passes through the attaching position of the auxiliary wheel 301 and the limiting wheel 302, the limiting wheel 302 prevents the lead passing through from being separated from the auxiliary wheel 301, the lead passes through the auxiliary wheel 301 with smooth notch surface, the lead is protected, the measuring result is more accurate, then, the ends of the two ends of the lead are kept aligned, and finally, the ends of the lead are clamped and fixed by the test bench 100, so that the fixing time is shortened, and the testing efficiency is improved.

Secondly, the clamping assembly 400 comprises a left clamping plate 401 and a right clamping plate 402, the left clamping plate 401 and the right clamping plate 402 are rotationally connected and fixed on a connecting shell at the bottom of the top plate 201, tooth grooves are formed in joint positions of the left clamping plate 401 and the right clamping plate 402, through holes 403 are formed in joint positions of the left clamping plate 401 and the right clamping plate 402, connecting nuts 406 are rotationally connected in the through holes 403 formed in the right clamping plate 402, nuts 406 are in threaded connection with screw rods 404, end portions of the screw rods 404 are slidingly connected with the screw rods 405, diameters of end portions of the screw rods 405 are larger than the width of the through holes 403, when a lead passes through joint positions of the auxiliary wheel 301 and the limiting wheel 302, according to lengths of two bundles of the lead wires, hydraulic pumps 200 on two sides drive the top plate 201 and the whole clamping assembly 400 to descend, when the clamping assembly 400 can clamp and fix the end portions of the lead wires, at the moment, the hydraulic pumps 200 are manually rotated reversely, the end portions of the lead wires extend into the space between the left clamping plate 401 and the right clamping plate 402, the end portions of the lead wires are rotated again, and the screw rods 405 are connected with the screw rods 404 through threads, accordingly, the screw rods 404 and the screw rods 404 are rotated inwards, the end portions of the screw rods 405 are contracted inwards, the lead wires are contracted inwards, the end portions of the top plate and the two clamping assembly is pulled down, and the end portions of the two end portions of the lead wires are further pulled down, and the end portions of the two end portions of the lead wires are pulled down, and the end respectively, and the end portions of the two end portions are further pulled down, and the end portions are respectively, and the end a tensile force, and the end portion is further, and a tensile force is a tensile value, and a tensile value is 201, and a tensile value is a tensile value, and a tensile value is and a tensile value and a tensile force.

To sum up, the working principle of the scheme is as follows: firstly, before testing the tensile force of the lead of the reactor, a section of the lead is cut, the end part of the lead passes through the joint of the auxiliary wheel 301 and the limiting wheel 302, the limiting wheel 302 prevents the passed lead from being separated from the auxiliary wheel 301, then, the end parts of the two ends of the lead are kept aligned, and finally, the end part of the lead is clamped and fixed by the test bench 100, so that the fixing time is shortened, and the testing efficiency is improved.

When the lead passes through the joint of the auxiliary wheel 301 and the limiting wheel 302, according to the lengths of the two bundles of the lead, the hydraulic pumps 200 at two sides drive the top plate 201 and the whole clamping assembly 400 to descend, when the clamping assembly 400 can clamp and fix the end parts of the lead, the hydraulic pumps 200 stop working, at the moment, the rotating rod 405 is manually rotated reversely, so that the left clamping plate 401 and the right clamping plate 402 at two sides are separated by a certain distance, then the end parts of the lead extend into the space between the left clamping plate 401 and the right clamping plate 402, the rotating rod 405 is rotated again, and as the screw 404 is in threaded connection with the nut 406, the end parts of the screw 404 are abutted against one side of the left clamping plate 401 and the right clamping plate 402 along with the rotation of the screw 404, and the screw 404 is contracted inwards to clamp and fix the end parts of the lead.

Further, the control panel 102 is used to observe the tensile strength of the wire, the hydraulic pumps 200 on both sides push the top plate 201 and the whole clamping assembly 400 to move upwards, and as the top plate 201 moves upwards, the two bundles of wires are tensioned, when the wire is broken, the numerical value on the control panel 102 is observed, and the half of the final measurement result is the tensile strength of the single bundle of wires.

The foregoing has shown and described the basic principles, principal features and advantages of the utility model. It will be understood by those skilled in the art that the present utility model is not limited to the above-described embodiments, and that the above-described embodiments and descriptions are only preferred embodiments of the present utility model, and are not intended to limit the utility model, and that various changes and modifications may be made therein without departing from the spirit and scope of the utility model as claimed. The scope of the utility model is defined by the appended claims and equivalents thereof.

Claims (4)

1. A reactor lead tension detector is characterized in that: including testboard (100) and last support arm (101), wherein, testboard (100) one side one end is equipped with control panel (102), be equipped with hydraulic pump (200) in the recess of seting up of going up support arm (101) both sides hydraulic pump (200) top fixed connection roof (201), roof (201) middle part bottom surface is equipped with clamping assembly (400), clamping assembly (400) are in same perpendicular with auxiliary assembly (300) of fixing at testboard (100) upper surface.

2. The reactor lead tension tester of claim 1, wherein: the auxiliary assembly (300) comprises an auxiliary wheel (301) and a limiting wheel (302), the auxiliary wheel (301) and the auxiliary wheel (301) are respectively coaxially connected with a rotating shaft (304), the auxiliary wheel (301) and the limiting wheel (302) are rotationally connected with a supporting rod (303) through the rotating shaft (304), and the auxiliary wheel (301) and the limiting wheel (302) are tightly attached.

3. The reactor lead tension tester of claim 1, wherein: the clamping assembly (400) is composed of a left clamping plate (401) and a right clamping plate (402), the left clamping plate (401) and the right clamping plate (402) are rotationally connected and fixed on a connecting shell at the bottom of the top plate (201), and tooth grooves are formed in joint positions of the left clamping plate (401) and the right clamping plate (402).

4. A reactor lead tension tester as recited in claim 3, wherein: through holes (403) are formed in the left clamping plate (401) and the right clamping plate (402), a connecting nut (406) is rotated in the through holes (403) formed in the right clamping plate (402), the nut (406) is connected with a screw rod (404) in a threaded mode, the end portion of the screw rod (404) is connected with a rotating rod (405) in a sliding mode, and the diameter of the end portion of the rotating rod (405) is larger than the width of the through holes (403).