KR101199877B1 - Quantification Method Of Clicking Feeling Of Connector - Google Patents

Abstract

PURPOSE: A method for quantifying a click feeling of a connector is provided to quantify a subjective click feeling of a connector, thereby accurately determining influences to the click feeling due to various design changes. CONSTITUTION: Insertion power to a connector(10) or a connection target(20) is measured. The maximum value and mean value of the measured insertion power are calculated. A first displacement section and a second displacement section are calculated. Second displacement where insertion power is maximum is subtracted from first displacement until complete insertion of the connection target in the first displacement section. Third displacement at initial contact timing between the connection target and the connector is subtracted from the second displacement in the second displacement section. The maximum value and mean value of the insertion power and the first and second displacement sections are used as independent variables. An index of a click feeling is determined by using the independent variables.

Description

Quantification Method of Clicking Feeling Of Connector

The present invention relates to a method for quantifying the click feeling of a connector, and more particularly, to quantify the click feeling generated when the connector is coupled to a mating object such as a mating connector or a flexible cable.

The connector is designed to create a click feeling when engaged with a mating object such as a mating connector or a flexible cable.

The connector is manufactured so that the operator can feel a click when the connector is engaged, and when joining the connector, the operator can be sure that the connector is fully engaged according to the click feeling.

Republic of Korea Patent Publication No. 2010-116130 is a board to board connector (Board to Board Connector) for connecting the printed circuit boards to each other, to provide a feeling of click when assembling the connector.

In addition, the Republic of Korea Patent Publication No. 2007-17902 is a rotary pressure type connector for connecting a flexible substrate, it is to generate a sufficient click feeling through the pressing member when rotating the pressing member to connect the flexible substrate to the connector.

In addition to the prior art, the connector field is required to generate a sufficient click feeling when the connector is coupled.

However, since the click feeling is a subjective sense that the worker feels, even if one feels that there is a click feeling, the other person may feel lacking the click feeling, and even the same person may not always feel the same click feeling.

The present invention has been made to solve the above problems, it is an object of the present invention to quantify the sense of click depending on the subjective sense can be objectively calculated.

How to quantify the click feeling of a connector,

Step 1 for positioning the object to be connected to the connector immediately before insertion;

Measuring an insertion force acting on the connector or the connection object while inserting the connector into the connection object or the connection object into the connector by a predetermined displacement per predetermined time;

Calculating a maximum value and an average value of the measured insertion force;

In the first displacement until the insertion object reaches the maximum value at the first displacement until the connection object is fully inserted into the connector, the first displacement section limits the first displacement interval, and when the connector and the connection object first contact at the second displacement. Calculating a second displacement interval limiting a third displacement of the fourth displacement;

A step 5 of determining a click-feel index by using the maximum value, the average value of the insertion force and the first and second displacement sections calculated in the above steps 3 and 4 as independent variables; It is characterized by comprising.

The click feeling index is characterized by the following equation.

Another way to quantify the click feel of a connector is

Step 1 for positioning the object to be connected to the connector immediately before insertion;

Measuring an insertion force acting on the connector or the connection object while inserting the connector into the connection object or the connection object into the connector at a constant displacement per predetermined time;

Calculating a maximum value and an average value of the measured insertion force;

The first time limiting the second time when the insertion force reaches the maximum value from the first time until the connection object is fully inserted into the connector, and the first time when the connector and the connection object first touch at the second time. Calculating a second time limiting the third time;

Determining a click feeling index by using the maximum value, the average value, and the first and second times of the insertion force calculated in the above steps 3 and 4 as independent variables; It is characterized by comprising.

The click feeling index is characterized by the following equation.

Another way to quantify the click feel of a connector is

Inserting a connection object into a connector having a pressing member;

Measuring a rotational force for rotating the pressing member while rotating the pressing member at a predetermined angle per predetermined time;

Calculating a maximum value and an average value of the measured rotational force;

The first rotation angle section limits the second rotation angle when the rotational force reaches the maximum value at the first rotation angle when the pressing member reaches the final pressurized state, and the pressing member and the connecting object are first fitted at the second rotation angle. Calculating a second rotation angle section that limits the third rotation angle when the touch is made;

Determining a click feeling index by using the maximum value, the average value of the rotational force and the first and second rotation angle sections calculated as the independent variables as the independent variables; It is characterized by comprising.

The click feeling index is characterized by the following equation.

Another way to quantify the click feel of a connector is

Inserting a connection object into a connector having a pressing member;

Measuring a rotational force for rotating the pressing member while rotating the pressing member at a predetermined angle per predetermined time;

Calculating a maximum value and an average value of the measured rotational force;

The first time limiting the second time when the rotational force reaches the maximum value at the first time when the pressing member reaches the final pressing state, and the first time when the pressing member and the connecting object first touch the second time. Calculating a second time limiting time to three;

Determining a click feeling index by using the maximum value, the average value, and the first and second times of the rotational force calculated in the above steps 3 and 4 as independent variables; It is characterized by comprising.

The click feeling index is characterized by the following equation.

According to the present invention, the click feeling determined by the subjective sense can be quantified, and the effect of various design changes on the click feeling can be accurately determined.

1 is a cross-sectional view of a board-to-board connector of Embodiment 1 of the present invention.
2 is a conceptual diagram for an experimental measurement of the first embodiment of the present invention.
Figure 3 is a diagram of the insertion force and time relationship of Example 1 of the present invention.
4 is a view for explaining an example of the design change using the present invention click feeling index.
5 is a cross-sectional view of the rotary pressure connector of the second embodiment of the present invention.

Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings.

≪ Example 1 >

1 is a cross-sectional view of a board-to-board connector to be described in Embodiment 1. FIG.

Board-to-board connectors are connected by installing a plug connector and a receptacle connector on each printed circuit board to exchange signals with each other, and fitting the plug connector and the receptacle connector to each other.

Both connectors are provided with terminals having projections 12 and 22 in the synthetic resin housings 11 and 21, respectively, and the connectors are connected to the printed circuit boards 1 and 2 by soldering portions 13 and 23 of the terminals. Is installed. When the two connectors are fitted together, as the protrusions 12 and 22 ride over each other, a feeling of click occurs.

Hereinafter, in Example 1, the receptacle connector will be referred to as a "connector" and the plug connector will be referred to as a "connection object".

FIG. 2 shows a displacement control device including a first jig 30, a rod 60 movable up and down, a load cell 50 for measuring a load, and a second jig 40 for fixing a connection object. Prepare as follows.

The printed circuit board of reference 1 to which the connector 10 is fixed is installed on the first jig 30, and the printed circuit board of reference 2 to which the connection object 20 is fixed to the second jig 40. . This installation is made by double-sided adhesive tape or adhesive.

In the present embodiment, the printed circuit boards 1 and 2 on which the connector 10 and the connection object 20 are fixed are installed on the first and second jigs 30 and 40, but the connector 10 and the connection object 20 are fixed. It is also possible to directly install the first and second jig (30, 40).

When such installation is completed, step 1 of positioning the connection object 20 to the stage immediately before inserting the connector 10 is completed.

After that, the connection object is moved downward by using the displacement control device. At this time, the displacement control device moves the second jig 40 downward at a constant speed of about 0.1 mm / sec, the load cell 50 is to measure the insertion force. (Step 2)

Measurement by the displacement control device was made every 0.01 seconds, and the time, displacement, and insertion force at the time of measurement are input to the computer.

When the connection object is completely inserted into the connector, the connection object is again removed from the connector, wherein the value measured by the load cell 50 is called a pulling force for separating the connection object from the connector.

3 is a diagram showing a relationship between visual and insertion force measured through Step 2; Through this diagram, the maximum and average values of the insertion force can be obtained. (Step 3) These calculations can be calculated by a computer program, and a detailed description thereof will be omitted. In FIG. 3, since the negative load is a step of removing the connection object from the connector, it is natural to exclude the average value.

Next, the first time T1 is obtained by subtracting the second time t2 when the insertion force reaches the maximum value at the first time t1 until the connection object is fully inserted into the connector. Then, at the second time t2 when the insertion force reaches the maximum value, the second time T2 is obtained by subtracting the third time t3 when the connector and the connection object first touch. (Step 4)

At this time, what is necessary is just to set the 3rd time t3 when the connector and a connection object contact for the first time to the point which the insertion force acts on the load cell 50.

The feeling of click can be defined using the maximum value, the average value, and the first and second times of the insertion force calculated in the above steps 3 and 4 as independent variables. (Step 5)

The larger the deviation between the mean value and the maximum value in the insertion force, the larger the feeling of click is. If the ratio of the second time / first time is large, the lightness of the click feeling is felt.

Therefore, it is preferable to determine a click feeling index by following formula (1).

------- (1)

------- (One)

As described above, since the displacement control device operates at a constant speed of about 0.1 mm / sec, the first, second, and third views have a linear proportional relationship with the displacement of the connection object.

Therefore, instead of the first, second, and third time periods, the displacement at each time is set to the first, second, and third displacements, and the displacement section corresponding to each time is replaced with the first, second, and second displacement sections instead of the first and second time periods. Even if it is set to, the same click feeling index can be obtained, and the click feeling index is preferably determined by the following equation (2).

------- (2)

------- (2)

The measurement / calculation of the maximum value / average value of the insertion force, the measurement and calculation of the first, second, and third time points, the first, second, and third displacements, the calculation of the click feeling index, etc. are measured by the computer program / The detailed description is omitted as it may be calculated.

In Example 1 as described above, although the click feeling index was experimentally calculated by using the displacement control device and the real object of the connector / connection object, the insertion force and the time of the insertion force and time were measured by modeling the connector and the connection object. Since the relationship, the insertion force, and the relationship between the displacement can be obtained, such a click feeling index calculation method is not limited to experimentally obtained.

As described above, the click feeling index is defined, and the click feeling index is calculated through various experimenters for various connectors, and the click feeling index is calculated. It was found to have a range of about 2.5 to 4.5. As the size of the product became smaller, the click feeling index of products that felt better in click feeling tended to appear lower.

This click-feel index can be reflected in the design in the following form.

4 is a form of the initial model, the click feeling is good, but the amount of overlap (A) between the connection object and the projections 12 and 22 of the connector is large, there is a problem that the permanent deformation occurs in the connector terminal.

In this case, reducing the amount of overlap decreased the permanent deformation of the connector terminal, but the click feeling also tended to decrease. As a result of moving the projection downward, the first time T1 was decreased and the second time T2 was increased. As a result, the permanent deformation of the terminal was reduced but the click feeling could be maintained. .

Therefore, by quantifying the click feeling index, it is possible for a designer to design and produce a connector having excellent performance while securing a click feeling without numerous trial and error.

<Example 2>

Embodiment 2 is a rotary pressure type connector 100 for connecting the flexible substrate 200, as shown in Figure 5, so that the contact portion 110 of the terminal to press the flexible substrate 200 by rotating the pressing member 120 of the connector One type of connector.

The connection object in the second embodiment is a flexible substrate. Compared to the connector of Example 1, the rotational pressure type connector of Example 2 has a difference in that the insertion force is changed to the rotational force.

According to this difference, the force acting on the pressing member 120 will be defined as the rotational force, and the amount of rotation of the pressing member will be defined as the rotation angle.

The rotational force may be measured by measuring a force acting perpendicularly to the pressing surface 121 of the pressing member 120, and a moment obtained by multiplying the force acting on the pressing surface by the distance from the center of rotation C of the pressing member. You may measure with. Equipment for measuring this experimentally can be easily manufactured by those skilled in the art to understand the technical spirit of the present invention, a detailed description thereof will be omitted.

In Example 2, similar to Example 1, by measuring the rotational force and the rotation angle of the pressing member while rotating the pressing member at a predetermined angle per predetermined time, it is possible to obtain a relationship diagram similar to that of FIG.

The first time is obtained by subtracting the second time when the rotational force reaches the maximum value at the first time when the pressing member of the connector reaches the final pressing state. Then, at the second time when the rotational force reaches the maximum value, the second time is obtained by subtracting the third time when the connector and the connection object first touch.

At this time, what is necessary is just to set the 3rd time when the connector and a connection object contact for the first time to the point where the rotational force starts to increase for the first time in a load cell.

Further, the first rotation angle section limits the second rotation angle when the rotational force reaches the maximum value at the first rotation angle when the pressing member reaches the final pressing state, and the pressing member and the connection object are connected at the second rotation angle. It is possible to calculate the second rotation angle section that limits the third rotation angle when the first contact is made.

Accordingly, in the connector as in Example 2, the concept of the rotation angle instead of the displacement is introduced, as shown in Equation (3) below, where the maximum and average values of the rotation force and the first and second rotation angle sections are independent variables. Can be.

------ (3)

------ (3)

In the connector as in Example 2, the concept of rotation angle instead of displacement introduces the concept of rotation angle, and the click feeling index is expressed by the following equation (4) using the maximum value, average value, and first and second times of rotation force as independent variables. Can be defined.

------ (4)

------ (4)

Accordingly, the click feeling index can be quantified even in a connector having a pressing member, so that a designer can design and produce a connector having excellent performance while ensuring click feeling without trial and error.

1,2: printed circuit board 10: connector 20: connection object
11, 21 housing 12, 22 protrusion 13, 23 solder

Claims (8)

Step 1 for positioning the object to be connected to the connector immediately before insertion;
Measuring an insertion force acting on the connector or the connection object while inserting the connector into the connection object or the connection object into the connector by a predetermined displacement per predetermined time;
Calculating a maximum value and an average value of the measured insertion force;
In the first displacement until the insertion object reaches the maximum value at the first displacement until the connection object is fully inserted into the connector, the first displacement section limits the first displacement interval, and when the connector and the connection object first contact at the second displacement. Calculating a second displacement interval limiting a third displacement of the fourth displacement;
A step 5 of determining a click-feel index by using the maximum value, the average value of the insertion force and the first and second displacement sections calculated in the above steps 3 and 4 as independent variables; A method for quantifying the click feeling of a connector comprising a.
The method of claim 1,
The click feeling index is determined by the following equation (2).

-----(2) Step 1 for positioning the object to be connected to the connector immediately before insertion;
Measuring an insertion force acting on the connector or the connection object while inserting the connector into the connection object or the connection object into the connector at a constant displacement per predetermined time;
Calculating a maximum value and an average value of the measured insertion force;
The first time limiting the second time when the insertion force reaches the maximum value from the first time until the connection object is fully inserted into the connector, and the first time when the connector and the connection object first touch at the second time. Calculating a second time limiting the third time;
Determining a click feeling index by using the maximum value, the average value, and the first and second times of the insertion force calculated in the above steps 3 and 4 as independent variables; A method for quantifying the click feeling of a connector comprising a.
The method of claim 3, wherein
The click feeling index is a method for quantifying the click feeling of a connector, characterized by the following equation (1).

-----(One)
Inserting a connection object into a connector having a pressing member;
Measuring a rotational force for rotating the pressing member while rotating the pressing member at a predetermined angle per predetermined time;
Calculating a maximum value and an average value of the measured rotational force;
The first rotation angle section limits the second rotation angle when the rotational force reaches the maximum value at the first rotation angle when the pressing member reaches the final pressurized state, and the pressing member and the connecting object fit for the first time at the second rotation angle. Calculating a second rotation angle section that limits the third rotation angle when the touch is made;
Determining a click feeling index by using the maximum value, the average value of the rotational force and the first and second rotation angle sections calculated as the independent variables as the independent variables; A method for quantifying the click feeling of a connector comprising a.
The method of claim 5, wherein
The click feeling index is determined by the following equation (3).

----- (3)
Inserting a connection object into a connector having a pressing member;
Measuring a rotational force for rotating the pressing member while rotating the pressing member at a predetermined angle per predetermined time;
Calculating a maximum value and an average value of the measured rotational force;
The first time limiting the second time when the rotational force reaches the maximum value at the first time when the pressing member reaches the final pressing state, and the first time when the pressing member and the connecting object first touch the second time. Calculating a second time limiting time to three;
Determining a click feeling index by using the maximum value, the average value, and the first and second times of the rotational force calculated in the above steps 3 and 4 as independent variables; A method for quantifying the click feeling of a connector comprising a.
The method of claim 7, wherein
The click feeling index is determined by the following equation (4).

-----(4)

Images