KR200246331Y1 - Fracture tester for spools - Google Patents

Abstract

The present invention relates to a spool fracture tester for judging the quality of the spool by forcibly separating the core tube and the flange of the spool used for winding the wire rod to grasp the weld bonding force.

The spool failure tester according to the present invention has a fixed side base plate 22, a fixed side reinforcement plate 23, and a fixed side latch formed with a spool mounting groove SH each having an 'U' shaped inner circumferential surface open at one side thereof. The plate 24 and the rotating side engaging plate 24 ', the rotating first reinforcing plate 23', the rotating second reinforcing plate 23 ', and the rotating side base plate 22' are parallel to each other in a series of orders. Four connecting rods 25 pass through the main through-holes H formed in the four corners of the plates, so that the two base plates 22 and 22 'are connected to the four connecting rods. (25) Each of the reinforcing plates 23, 23 ', 23' and the latching plates 24, 24 'arranged between the two base plates are completely fixed to each end, and the fixed plate set and the rotating plate set are fixed to each other. While linear rotation is possible along the connecting rod 25, the outer surface (22S) of the fixed side base plate through the fixed side base plate through the center of the outer surface (22S) of the fixed side base plate Load cell (L) having a load sensing shaft (LA) coupled to the center portion and an indicator displaying the measured load is attached, and is coupled to the center of the outer side of the rotating side of the second reinforcement plate (23 'S) so that one end is rotatable And a rotating bolt (B) having a rotary handle (HA) at the other end thereof through the central portion of the rotating side base plate (22 ') by screwing.

The tester of the present invention is not only capable of measuring the accurate breaking strength of the spool while having a simple structure, but also significantly reduces the test time compared to the conventional universal testing machine, and enables accurate and rapid spool inspection. By determining the quality of the spool, there is an advantage that the failure of the steel cord due to the breakage of the spool in use and the inability of the production process can be prevented.

Description

Fracture tester for spools

The present invention relates to a spool fracture tester used for winding wire rods, and more particularly, a cylindrical core barrel in which the wire rod is wound and a wire rod wound on the outer circumferential surface of the core barrel can be wound to the same height over the entire length of the outer circumferential surface of the core barrel. In order to inspect the quality of the wire winding and conveyance spool consisting of a hollow disk flange which is welded and attached to each end surface of the core tube to serve as a guide, the flanges are separated from both ends of the core tube to grasp the welding bond force. A spool failure tester for determining the quality of a spool.

A spool (also called bobbin) is a winding tool for winding wire such as wire or thread. Generally, as shown in FIG. 1, the spool 1 includes a core barrel 11 to which a wire is wound, and a core barrel ( 11 is attached to both ends of the flange 12 to serve as a guide.

Since the spool 1 is transported in a state where the wire is wound, and may be used or stored for a long time, the spool 1 should have appropriate rigidity according to the material of the wire to be wound. In general, the spool is made of synthetic resin or metal.

Since the wire wound on the spool is in a tensioned state, the wire wound on the spool exerts a contraction force in a direction perpendicular to the axis on the outer circumferential surface of the core, which constitutes the spool, and is perpendicular to the flange surface of both ends of the core. When exerted on an external force, the spool must have sufficient physical properties to withstand the forces exerted by the wound wire.

In particular, in the case of a spool for winding a steel cord which is a tire material having excellent elasticity, the rigidity of the spool is a very important factor.

The steel cord is made by twisting a plurality of metal wires and is embedded in tire rubber to maintain the rigidity of the tire. The steel cord is drawn out on a spool in a steel cord twisted pair, and then supplied to a demander. The ball spools with steel cords are then returned to the steel cord manufacturing plant for reuse.

Therefore, a spool wound and maintained for a long time in a state where a high elastic steel cord is tensioned should have a considerable stiffness, and the coupling force between the core tube and the flange coupled by welding, rather than the core tube having sufficient rigidity, is sufficient It is an important factor to decide.

In general, the core of the spool made of metal material has sufficient rigidity, but there is a high possibility that the welding joint will be insufficient due to the welding defects remaining in the joint of the core and the flange joined by welding. As the flange separates from the core during winding, transport or use, the steel cord is released from the spool and can not be used, or in each process, non-operation can occur and reduce productivity.

Therefore, the spool used for winding high elastic wire rods such as steel cords is inspected for the quality of the spool when the new spool is received or when the used spool is recovered and reused, and the quality of the spool is determined by the welding coupling force between the core tube and the flange. The quality is determined.

Therefore, the spool should be well formed so that the weld joint between the core tube and the flange is not lacking, and the spool should be removed before using the spool to prevent the steel cord wound around the spool from being damaged or in the process. It must be sampled to check the weld bond between the core and the flange to prevent the use of bad spools.

However, conventionally, since there was no dedicated tester capable of inspecting the weld bonding force between the core and the flange constituting the spool, a wire rope is provided to each of the mutually opposing grips of the universal testing machine, which is typically used for tensile testing of metal materials. While the other side of the wire rope caught on each grip is hooked on the two flanges and the welds of the core tube, while the other side is hooked, the two grips are opened as shown in the tensile test to measure the load when the flange of the spool is separated from the core tube. In this way, the weld bonding force between the flange and the core tube constituting the spool was examined.

The above method requires not only the time for the wire rope to hang on the grip and the spool of the universal testing machine, but also the time required to apply the load equal to the welding coupling force between the flange and the core to the wire rope caught between the grip and the spool. There is a problem that the test time is long, and the accuracy of the test is poor.

In other words, accurate results can be obtained only if the final load transmitting part of the tester and the test object, that is, the flange, are in direct contact with each other in a safe state. The wire rope is elastically deformed between the flanges of the test chain spool, and the contact state between the wire rope and the flange is not uniformly contacted and is not stable so that the load is concentrated in one place.

Therefore, there is a problem that the deviation of the measured value with respect to the breaking load of the spool is not only large for each test, but also the accuracy of the test is lowered.

As described above, the contact state between the tester and the test object can be maintained uniformly so that the load under test is not imparted to the test object, and a rigid body that does not undergo plastic deformation under the welding bond force of the spool is separated from the grip of the tester and the flange of the spool. The jig can be used in place of the wire rope, but because it is a universal testing machine used for various tests, there is a problem in that it is not only hassle to install and dismantle the heavy jig at each test, and also it is not easy to manufacture the jig.

The present invention was devised to solve all the problems of the conventional spool fracture test method for inspecting the weld bonding force between the flange and the core of the spool, and uniform the inner surface of the flange in the flange side direction from the outer peripheral surface of the spool. It is provided with two mutually opposing latches that can be supported while hanging, and a load cell connected with an indicator indicating the number of loads and a device that can easily move the latches on one side are combined to form a spool. It is an object of the present invention to provide a manual spool fracture tester capable of quickly and accurately measuring weld bonding force.

1 is a perspective view of a spool.

Figure 2 is a perspective view of an embodiment tester of the present invention.

Figure 3 is a front view of an embodiment tester of the present invention.

Figure 4 is a plan view of an embodiment tester of the present invention.

5 is an exploded coupling view of the fixed side reinforcement plate and the locking plate constituting the present invention.

Figure 6 is an exploded coupling of the rotating side engaging plate and the first and second reinforcing plate constituting the present invention.

((Explanation of symbols for main part of drawing))

1. spool 2. testing machine of the present invention

11.Body pain 12.Flange

22. Fixed side base plate 22 '. Rotating Side Base Plate

23. Fixed side gusset 23 '. Rotating side first reinforcement plate

23 '. Rotating side 2nd reinforcement plate 24. Fixed side stopping plate

24 '. Rotating side stop plate 25. Connecting rod

26. Fixing side fixing bolt 26 '. Rotating side fixing bolt

The object of the present invention is that the width is larger than the outer diameter of the core of the spool, but smaller than the flange outer diameter, and has a 'U' shaped inner peripheral surface and the two engaging plates formed with flange engaging grooves open at one side, the load cell and one side locking It is achieved by a rotating bolt with a rotating hand for imparting a separate load on the flange against the core of the spool which has been stopped by moving the plate forward and backward.

The spool mounted on the spool fracture tester of the present invention has a portion of the outer peripheral surface of both ends of the core tube contacting the inner peripheral surface of each flange engaging groove formed on the two engaging plates constituting the main body of the tester so that the core cylinder is supported by the internal groove of the engaging groove. In the state, the inner surface of the two flanges coupled to both ends of the spool are in contact with the outer surface of the two locking plates, respectively, and when the spool is mounted, the handle coupled to one end of the rotation bolt is rotated to reverse the one locking plate, thereby stopping. A failure test of the spool, which is given a separate load of the flange against the broken core, is carried out.

One of the two stopping plates constituting the spool fracture tester of the present invention is coupled to the fixed side reinforcement plate connected to the load cell is almost no movement, the other locking plate is coupled to the rotating side reinforcement plate is connected to the rotating bolt is rotated When the handle of the rotating bolt provided at one end of the bolt rotates, linear reciprocating rotation of the forward and reverse is performed with respect to the fixed side locking plate fixed to the load cell together with the rotating side reinforcement plate.

In addition, the load measured when the spool is broken is displayed as a number on the indicator connected to the load cell, so that the correct welding coupling force between the spool, that is, the core and the flange, can be grasped, and the outer surface of the stopping plate and the inner surface of the flange are in uniform contact with each other. Is maintained, the weld bonding force is accurately measured.

The base plate, the reinforcement plate, and the hanger plate constituting the tester of the present invention are all made of a rectangular plate metal, and all the plates are parallel to each other by four connecting rods through a main through hole formed at four corners of each plate. The connecting rods also serve as guides for all stopping plates and reinforcing plates that rotate forward and backward.

The details of the purpose and technical constitution according to the present invention, including the effect thereof, will be clearly understood by the following description with reference to the drawings showing preferred embodiments of the present invention.

2 is a perspective view of an embodiment of the present invention spool failure tester, a front view in FIG. 3, a plan view in FIG. 4, a side view in FIG. 5, an exploded coupling of the fixed side reinforcement plate and the locking plate in FIG. FIG. 7 illustrates an exploded coupling of the rotating side stopping plate and the first and second reinforcing plates.

As shown, the tester 2 of the present invention has a rectangular plate-shaped fixed side base plate 22 to which the load cell L is coupled to the center portion 22S of the outer surface, and the penetrating side base plate 22 penetrating the above. One side is opened so that the load sensing shaft LA of the load cell L is coupled to the fixed side reinforcement plate 23 coupled to the center of the outer surface 23S, and the inner surface of one flange of the spool is supported on the outer surface 24S ' A fixed side locking plate 24 having a spool mounting groove SH having a U'-shaped inner circumferential surface, and the same spool mounting groove as the fixed side locking plate 24 so that the other side flange inner surface of the spool is supported on the outer surface 24'S. A rotating side engaging plate 24 'having an SH), a rotating side first reinforcing plate 23' for reinforcing the rotating side stopping plate, and the rotating side stopping plate 24 'and a rotating first reinforcing plate And a second side reinforcing plate 23 'which is fixed to each other together with 23' and connected to a center portion of the outer surface 23'S so that one end of the rotation bolt B is rotatable, and the other side. The rotating bolt (B) having a rotary handle (H) at the end is screwed through and the rotating side base plate (22 ') of the square plate of the square plate forming an outer frame together with the fixed side base plate 22 are all Arranged in parallel, all the plates 22, 23, 24, 24 ', 23', 23 ', 22' are connected to the four connecting rods 25 through the main through hole H formed at each of four corners. ).

At this time, the two base plates 22 and 22 'are completely fixed to both ends of the four connecting rods 25, but the reinforcing plates 23, 23' and 23 'and the engaging plate are arranged between the two base plates. 24, 24 'is in a state where linear rotation is possible along the connecting rod.

In other words, the fixed side reinforcement plate 23 and the locking plate 24 serves to maintain the gap between the two plates 23 and 24, and the gap between the reinforcing plate 23 and the locking plate 24 is maintained. Four fixed side fixings simultaneously penetrating the auxiliary through holes H 'formed inside the main through holes H of the two plates 23 and 24 in a state of being fitted into the fixed side bushings 26B serving to hold them. The bolts 26A and the nuts 26C screwed thereon are fixed to each other as one body to form the fixed plate sets 23, 24 and 26, and the fixed plate sets fixed as described above are connected to the connecting rod 25. The connecting rod 25 penetrates the main through hole H so as to enable linear rotation with respect to the.

In addition, the rotating side stopping plate 24 'and the first and second reinforcing plates 23' and 23 'are also fixed to the rotating side stopping plate 24' and the first reinforcing plate 23 '. Between the first side bushing 26'B and the second bushing 26'C, which serve to maintain the spacing therebetween and between the first reinforcing plate 23 'and the second reinforcing plate 23', respectively. Four fixing side fixing bolts 26A which simultaneously penetrate the auxiliary through holes H 'formed inside the main through holes H of the three plates 24', 23 'and 23' and screwed thereto. The rotary plate sets 24 ', 23', 23 ', and 26' are fixed to each other as one body by a nut 26C, and the rotary plate sets fixed as described above are connected to the connecting rod 25. The connecting rod 25 penetrates the main through hole H so as to enable linear rotation with respect to the main rod hole H. FIG.

That is, in the state where the load cell L and the rotation bolt B are not connected, the fixed side reinforcement plate 23 and the locking plate 24 and the rotation side locking plate 24 'and the two reinforcement plates 23'. The fixed plate set and the rotating plate set each composed of 23 'can be linearly rotated along the connecting rod 25 between the two base plates 22 and 22' fixed to both ends of the connecting rod 25, respectively. It is a structure that is combined.

Therefore, when the rotating handle H of the rotating bolt penetrating the central part of the rotating side base plate 22 'in a state in which the spool is attached to the two locking plates in one direction, the rotating side stopping plate ( 24. The rotating plate set consisting of the first and second reinforcing plates 23 'and 23' is moved from the fixed plate set connected to the load sensing shaft 22S of the load cell while being moved toward the rotating side base plate 22 '. By moving away, a load is applied between the core and the flange of the spool.

The load applied between the core and the flange of the spool is measured by the load cell L through the load sensing shaft LA of the load cell connected to the outer surface 23S of the fixed side locking plate, By being displayed on the indicator (not shown) connected to the load cell (L), it is possible to measure the breaking strength of the spool, that is, the welding coupling force between the core and the flange.

And, reference numeral 'T' is a mounting table on which the tester 2 of the present invention is placed.

Table 1 shows the results of the test time required when the breakdown test of the spool is carried out in the tester and the conventional universal testing machine of the present invention constructed and operated as described above.

division Test Unit Time Universal testing machine 5 pcs 30 minutes Inventive tester 5 pcs 10 minutes

* The test subject spool is new standard

As can be seen in Table 1, the test time per one spool was found to be reduced by more than 60%, the conventional test time is excessively required as described above, in the case of a universal material tester compared to the testing machine of the present invention This is because excessive time is required for mounting and setting the spool using a wire rope in the tester.

Furthermore, when the spool is attached to the universal testing machine using a wire rope, the breaking strength of the spool measured according to the grip of the tester and the condition of the wire rope caught in the spool is more than 1 ton when the breaking condition of the wire rope is severe. A large deviation occurred, but was accurately measured in the present tester.

As described above, the tester of the present invention is a dedicated tester for determining the spool of the spool by grasping the welding coupling force between the core tube and the flange of the spool. Compared with the conventional universal testing machine, the test time is significantly reduced, and thus, there is an advantage in that the accurate and rapid spool inspection can be performed.

And, by determining the quality of the spool by accurate inspection, there is an advantage that the failure of the steel cord due to the breakage of the spool in use and the inability of the production process can be prevented.

Claims (2)

A tester for investigating the breaking strength of a wire winding spool, the spool mounting groove having a fixed-side base plate 22, a fixed-side reinforcement plate 23, and one side open and having a 'U'-shaped inner circumferential surface, all of which are rectangular plates. Fixed side engaging plate 24 and rotating side engaging plate 24 'formed with SH, rotating side first reinforcing plate 23', rotating side second reinforcing plate 23 ', and rotating side base. Main through holes H formed in the four corner portions of the plates 22, 23, 24, 24 ', 23', 23 ', and 22' with the plates 22 'arranged in parallel in a sequence. Four connection rods 25 are penetrated through the two base plates 22 and 22 ', and the two base plates 22 and 22' are completely fixed to both ends of the four connection rods 25, and the reinforcement plates are arranged between the two base plates. (23, 23 ', 23') and locking plates (24, 24 ') are mutually connected by two fixing bolts (26) (26') into which bushings (26B), 26'B, 26'C are fitted. The fixed plate set (23, 24, 26) and the rotating plate set (24 ', 23', 23 ', 26') that are fixedly coupled The load sensing shaft is coupled to the center of the outer surface 22S of the fixed side base plate through a fixed side base plate in the center of the outer surface 22S of the fixed side base plate. A load cell (L) having an LA and an indicator indicating a measurement load is attached thereto, and is coupled to the center of the second reinforcing plate outer surface 23'S so that one end thereof is rotatable, and a rotary knob HA at the other end thereof. Swivel bolt breaking tester characterized in that the rotating bolt (B) having a structure that penetrates through the central portion of the rotating side base plate (22 '). 2. The rotating side first reinforcing plate according to claim 1, wherein the fixed side base plate (22) and the fixed side reinforcement plate (23), between the rotating side locking plate (24 ') and the rotating first reinforcing plate (23'), and the rotating side first reinforcement. The spacing between the plate (23 ') and the pivoting second reinforcement plate (23') is equal to the length of the bushing (26B) (26'B) (26'C), respectively.