KR101379770B1 - Apparatus for testing screw strength of ball joint - Google Patents

Abstract

The present invention relates to a screw strength testing apparatus for a ball joint which can understand a correlation between the thread fastening thrust and the frictional force and easily set a mass production condition (thread fastening torque value) in view of a rear driving condition (load condition), by performing a screw proof load test and a nut fastening torque test of the ball joint at the same time and thus securing real-time data between the thrust of the screw and the nut fastening force. The apparatus includes a rotating unit for rotating a nut (2) fastened to a threaded portion (1c) of a ball joint (1); a first sensor for measuring the fastening torque when the nut (2) is rotated by the rotating unit; a second sensor (140) for measuring a tensile load acting on the threaded portion (1c) when the nut (2) is rotated by the rotating unit; and a control unit for storing values measured by the first and second sensors.

Description

Ball Joint Thread Strength Tester {APPARATUS FOR TESTING SCREW STRENGTH OF BALL JOINT}

The present invention relates to a ball joint screw strength test apparatus, and relates to a ball joint screw strength test apparatus capable of measuring the tightening axial force and the tightening rotation force acting on the ball joint.

In general, the ball joint is widely used as a joint means having a function of a spherical joint.

1 is a view showing a ball joint.

The ball joint 1 is formed at a ball-shaped shoe portion 1a, a body portion 1b having a tapered shape extending from the shoe portion 1a, and an upper end portion of the body portion 1b. It consists of a screw portion (1c) for fastening with a nut to the structure.

Such ball joints are used in automobiles to connect the lower arm of the suspension and the knuckles or the tie rods and knuckles. As described above, in order to mount the ball joint to the vehicle, the nut must be fastened to the threaded portion 1c with a set torque value. Therefore, the screwed portion 1c must have a tensile and tightening strength of the nut fastening torque greater than or equal to the set value. Since additional tensile force is applied to the threaded portion 1c by vibration, the threaded portion 1c must have a screw axial force greater than or equal to a set value to withstand such tensile force.

Therefore, a test apparatus is required to test whether the threaded portion 1c of the ball joint meets the criteria of such thread strength (fastening torque and screw axial force).

2 shows a device for testing a conventional ball joint screw axial force, and FIG. 3 shows a device for testing a conventional ball joint fastening torque.

Referring to FIG. 2, a driving member is applied upward to apply a tensioning force to the fixing member 11 for fixing the shoe portion 1a of the ball joint 1 and the threaded portion 1c of the ball joint 1. And a load cell 13 for measuring the tensile strength of the screw, that is, the axial force, by measuring the axial displacement of the ball joint 1 generated by the driving of the driving unit 12 and the driving unit 12.

According to this test apparatus, when the driving part 12 is driven so that the load set on the screw part 1c acts, the shoe part 1a of the ball joint 1 is fixed by the fixing member 11, and thus the screw part 1c. ), The tensile force is applied to the displacement in the axial direction. In this case, if the displacement is measured by the load cell 13, the thread axial force of the threaded portion 1c of the ball joint 1 meets the set criteria, i.e., the minimum required longitudinal tension load on the threaded portion 1c. It is possible to measure whether the tensile load withstands more than the guaranteed load.

Referring to FIG. 3, a fixing member 14 surrounding and fixing the shoe 1c of the ball joint 1, a knuckle 15 fitted to the body 1b of the ball joint 1, and a ball The fastening torque acting on the screw part 1c by the rotation drive part 16 for rotating the nut 2 spirally coupled to the screw part 1c of the joint 1, and the said rotation drive part 16 is measured. Torque sensor 17 is provided for.

According to the test apparatus, when the rotary drive unit 16 is driven at a set torque value, the fastening torque of the screw unit 1c can be sensed, and the rotary drive unit 16 is operated until the screw unit 1c is broken. When the nut 2 is rotated, it is possible to know whether the fastening torque of the screw portion 1c satisfies the set criteria.

As described above, the conventional ball joint screw strength test apparatus has a problem in that it takes a lot of time for the screw strength test because the screw axial force and the fastening torque are respectively tested in separate test apparatuses.

In addition, in a real vehicle, since the screw axial force and the rotational torque act at the same time, when the screw axial force and the tightening torque are tested separately, there is a problem in that the reference value is set without considering the correlation between the screw axial force and the rotational torque.

The present invention has been made to solve the above-mentioned problems, by real-time data between the screw axial force and the nut tightening friction force of the ball joint by performing the screw guarantee load test and the nut tightening torque test at the same time, The purpose of the present invention is to provide a ball joint screw strength test apparatus that is easy to set the mass production assembly condition (screw tightening torque value) in consideration of the relationship between friction forces and further considering the actual vehicle condition (load condition).

Ball joint screw strength test apparatus of the present invention, the rotation drive unit for rotating the nut (2) fastened to the threaded portion (1c) of the ball joint (1); A first sensor for measuring a tightening torque when the nut 2 is rotated by the rotary driver; A second sensor 140 for measuring a tensile load acting on the screw part 1c when the nut 2 is rotated by the rotation driving part; It includes a control unit for storing the values measured by the first sensor and the second sensor.

The rotation driving unit may be formed of a nut rotation jig 130 coupled to an outer circumferential surface of the nut 2 and a motor for providing a rotation driving force to the nut rotation jig 130.

The second sensor 140 may be a compression load sensor for measuring the compression force acting in the direction to tension the screw portion (1c).

The first fastening target member 110 is inserted into the body portion 1b connected to the screw portion 1c of the ball joint 1 to fix the body portion 1b so as not to move in the direction of the nut, and the first When the nut 2 is rotated so as to be spaced apart from the fastening target member 110 so as to exert a tensile force on the screw portion 1c, the nut is contacted with the first fastening target member 110 to be narrowed. Further comprising a second fastening member 120 to be installed; The second sensor 140 may be configured to detect a compressive force acting as close as the interval between the first fastening target member 110 and the second fastening target member 120 is close.

The body portion 1b is formed in a tapered shape, and the first tapered shape corresponding to the shape of the body portion 1b also in the first fastening target member 110 into which the body portion 1b is inserted. The ball stud insertion groove 113 may be formed.

The first fastening target member 110 and the second fastening target member 120 are further positioned outside the fixing grooves 111 and 121 and the fixing grooves 111 and 121 in which the second sensor 140 is installed to detect the compressive force. The protruding flanges 112 and 122 may be formed to face each other.

According to the ball joint screw strength test apparatus of the present invention, it is possible to perform the screw guarantee load test and the nut tightening torque test of the ball joint at the same time, compared to the case where the screw guarantee load test and the nut tightening torque test are performed separately. Productivity can be improved by reducing the time required.

In addition, real-time data can be secured between the screw axial force and the nut tightening friction force, making it easy to understand the correlation between screw tightening axial force and friction force and further establish mass production assembly conditions (screw tightening torque values) considering actual vehicle conditions (load conditions). There is one effect.

1 shows a ball joint,
2 shows a device for testing a conventional ball joint screw axial force,
3 shows a device for testing a conventional ball joint fastening torque,
4 is a view showing a ball joint screw strength test apparatus according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Wherein like reference numerals refer to like elements throughout.

Before describing the test apparatus of the present invention, the term used herein is defined as having the following meaning.

The screw axial force refers to the tensile load generated on the screw by assembling the bolt and nut, and the compression load acts on the member to be fastened as much as the tensile load. At this time, the screw axial force that can withstand the threaded portion of the ball joint is set. Must be satisfied.

The clamping force means a compressive load generated on the member to be fastened by assembling the bolt and the nut, which is equivalent to the screw axial force, also called a clamping force, and a tensile load acts on the screw as much as the clamping load.

Proof load means the minimum required tensile load on the screw, and the tensile load measured by the test apparatus according to the present invention must be equal to or more than the guarantee load to meet the set criteria.

Tightening torque refers to the rotational frictional force generated when rotating the bolt and nut, and the bolt is tensioned in the longitudinal direction by one pitch per screw rotation of the nut, and the rotational frictional force that can withstand the threaded portion of the ball joint These established criteria must be met.

4 is a view showing a ball joint screw strength test apparatus according to the present invention.

Referring to Figure 4, the ball joint screw strength test apparatus according to the present invention, a rotary drive unit for rotating the nut (2) fastened to the threaded portion (1c) of the ball joint 1, the nut by the rotary drive unit ( 2) a first sensor (not shown in the figure) for measuring the tightening torque during the rotation of the second; a second load for measuring the tensile load acting on the screw portion 1c when the nut 2 is rotated by the rotary driving unit; Sensor 140, and a control unit for storing the values measured by the first sensor and the second sensor.

The ball joint 1 is formed at a ball-shaped shoe portion 1a, a body portion 1b having a tapered shape extending from the shoe portion 1a, and an upper end portion of the body portion 1b. It consists of a screw portion (1c) for fastening with a nut to the structure of the vehicle, the nut (2) is fastened to the screw portion (1c).

The rotation driving unit may be formed of a nut rotation jig 130 coupled to an outer circumferential surface of the nut 2 and a motor for providing a rotation driving force to the nut rotation jig 130.

The nut rotation jig 130 is formed such that the shape of the inner circumferential surface corresponds to the shape of the outer circumference of the nut 2, and when the nut 2 is inserted into the nut rotation jig 130, the nut rotation jig 130 is formed. The nut 2 is rotated in one piece.

The nut rotation jig 130 is to be rotated by the drive of the motor, the screw (1c) length by one pitch per screw 1 rotation of the nut (2) when rotating the nut (2) to tighten the screw (1c) The deformation is made so that is tensioned.

In this case, a frictional force acts between the contact surface of the nut 2 and the threaded portion 1c, and the tightening torque value of the nut 2 is set based on the frictional force, so that the frictional force generated when driving the rotary drive unit is measured. A first sensor (not shown) is provided.

On the other hand, the first fastening target member 110 and the second fastening target member 120 are fitted to the body portion 1b of the ball joint 1, and the first fastening target member 110 and the second fastening target A second sensor 140 is provided between the members 120 to measure the compressive force generated when the distance between the first fastening member 110 and the second fastening member 120 is near.

In order to interpose the second sensor 140 between the first fastening member 110 and the second fastening member 120, the first fastening groove 111 is disposed in the first fastening target member 110. And a first flange portion 112, and a second fixing groove 121 and a second flange portion 122 are formed in the second fastening member 120.

Therefore, the flanges 112 and 122 protrude further outward than the fixing grooves 111 and 121, and the first fixing groove 111 and the first flange 112 are disposed at one side with the second sensor 140 interposed therebetween. ) Is positioned, and the second fixing groove 121 and the second flange portion 122 are positioned on the opposite side thereof, so that a gap between the first fastening target member 110 and the second fastening target member 120 is increased. When close, the compressive force acts on the second sensor 140.

The second sensor 140 may be configured to detect the compression load from the displacement generated when the compression force is applied, such as a load cell.

On the other hand, a first ball stud insertion groove 113 is formed in the central portion of the first fastening member 110 to insert the body portion 1b of the ball joint 1, and has a tapered shape. The first ball stud insertion groove 113 also has a tapered shape so as to correspond to the body portion 1 b, and the body portion 1 b is inserted into the first ball stud insertion groove 113 by a predetermined depth or more. Is prevented so that the position of the ball joint 1 is fixed.

In addition, a second ball stud insertion groove 123 is formed through the center portion of the second fastening member 120, and the threaded portion 1c of the ball joint 1 is the second ball stud insertion groove 123. It will be located through.

In this case, one side of the nut 2 is installed to be in close contact with one side of the second fastening member 120 in which the second ball stud insertion groove 123 is formed.

The operation of the test apparatus according to the present invention having the above configuration will be described.

When the motor of the rotary drive unit is driven, the nut rotation jig 130 is rotated, and the nut 2 is integrally rotated according to the rotation of the nut rotation jig 130.

When the nut 2 rotates, the gap between the first fastening target member 110 and the second fastening target member 120 is pushed toward the first fastening target member 110 in the direction of the first fastening target member 110. The first flange 112 and the second flange 122 are in close contact with one side and the other side of the second sensor 140 to compress the second sensor 140.

In this case, the first sensor detects a frictional force acting between the threaded portion 1c and the nut 2, that is, a fastening torque when the rotational force is applied by the rotational drive part, and the screw axial force is a compressive load in the second sensor 140. And sensed values of the first sensor and the second sensor 140 are input to a controller (not shown).

In this way, it is possible to measure the screw axial force and the tightening torque at the same time by simply driving one rotary drive unit, which not only reduces the time required for the test but also uses the screw axial force and the tightening torque values simultaneously input to the controller. The correlation between the tightening torques can be analyzed, and it becomes possible to set the criteria for the screw axial force and the tightening torque that meet the actual vehicle conditions.

As described above, the present invention is not limited to the above-described embodiments, and various changes and modifications may be made without departing from the scope of the present invention as defined in the appended claims. And such modifications are within the scope of the present invention.

1: Ball Joint 1a: Shoe Parts
1b: body 1c: screw
2: nut 110: first fastening member
111: first fixing groove 112: first flange portion
113: first ball stud insertion groove 120: second fastening target member
121: second fixing groove 122: second flange portion
123: second ball stud insertion groove 130: nut rotation jig
140: second sensor

Claims (6)

A rotation driving unit for rotating the nut 2 fastened to the threaded portion 1c of the ball joint 1;
A first sensor for measuring a tightening torque when the nut 2 is rotated by the rotary driver;
A second sensor 140 for measuring a tensile load acting on the screw part 1c when the nut 2 is rotated by the rotation driving part;
It includes a control unit for storing the values measured by the first sensor and the second sensor,
The second sensor 140 is made of a compression load sensor for measuring the compressive force acting in the direction to tension the screw portion (1c),
The first fastening target member 110 is inserted into the body portion 1b connected to the screw portion 1c of the ball joint 1 to fix the body portion 1b so as not to move in the direction of the nut, and the first When the nut 2 is rotated so as to be spaced apart from the fastening target member 110 so as to exert a tensile force on the screw portion 1c, the nut is contacted with the first fastening target member 110 to be narrowed. Further comprising a second fastening member 120 to be installed;
The second sensor 140 is a ball joint screw strength test device consisting of detecting the compressive force acting as close to the gap when the distance between the first fastening member 110 and the second fastening member 120 is close .
The method of claim 1,
The rotary drive unit is coupled to the outer circumferential surface of the nut 2, the nut rotating jig 130 for applying a rotational force, and a ball for characterized in that the motor for providing a rotational driving force to the nut rotation jig 130 Joint thread strength tester.
delete delete The method of claim 1,
The body portion 1b is formed in a tapered shape, and the first tapered shape corresponding to the shape of the body portion 1b also in the first fastening target member 110 into which the body portion 1b is inserted. Ball joint screw strength test apparatus, characterized in that the ball stud insertion groove 113 is formed.
The method of claim 1,
The first fastening target member 110 and the second fastening target member 120 are further positioned outside the fixing grooves 111 and 121 and the fixing grooves 111 and 121 in which the second sensor 140 is installed to detect the compressive force. Ball joint thread strength test apparatus, characterized in that the protruding flanges 112, 122 are formed so as to face each other.

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