KR102385905B1 - Apparatus and method for simulating frictional force generated at a fork terminal - Google Patents

Abstract

The present invention includes: a modeling unit that generates a fuse model based on shape information and physical property information of a fuse and generates a fork terminal model based on shape information and physical property information of a fork terminal; a setting unit that sets a first contact condition applied when the fuse model is inserted into the fork terminal model and sets a second contact condition applied when the fuse model is separated from the fork terminal model; a simulation unit that performs simulation in which the fuse model is inserted into the fork terminal model under the first contact condition and performs simulation in which the fuse model is separated from the fork terminal model under the second contact condition; and a detection unit that detects a frictional force generated between the fuse model and the fuse terminal model according to the simulations. According to the present invention, it is possible to improve reliability of a fork terminal design.

Description

Apparatus and method for simulation of fork terminal friction force

The present invention relates to a fork terminal friction force simulation apparatus and method, and to a fork terminal friction force simulation apparatus and method capable of simulating a friction force generated in a fork terminal according to insertion or removal of a fuse.

A fork terminal is provided on a printed circuit board provided in a vehicle. A finger part is provided at one side of the fork terminal so that the fuse can be fastened. The finger part serves to prevent the fuse from being separated from the fork terminal by fixing the fuse at the time of performing an electrical contact with the fuse.

The finger part of the fork terminal should provide an appropriate level of frictional force to prevent the fuse from being dislodged. Therefore, when the fork terminal is designed, a test is performed to verify whether the frictional force generated between the fork terminal and the fuse satisfies the design specification when the fuse is inserted into the fork terminal or the fuse is separated from the fork terminal.

In general, the test is performed by applying the same friction coefficient condition to the case of inserting the fuse into the fork terminal and the case of removing the fuse from the fork terminal. In this case, there is a problem in that the shape of the fork terminal is changed due to the insertion of the fuse during the test, so that the change in frictional force generated between the fuse and the fork terminal cannot be reflected.

The background technology of the present invention is disclosed in 'fork terminal' of Korean Patent Application Laid-Open No. 10-2017-0047946 (2017.05.08.).

The present invention was devised to solve the above problems, and an object according to one aspect of the present invention is to apply different coefficients of friction to the case of inserting the fuse into the fork terminal and the case of separating the fuse from the fork terminal. An object of the present invention is to provide an apparatus and method for simulating the friction force of a fork terminal capable of simulating the friction force of a fork terminal according to insertion and separation.

A fork terminal frictional force simulation apparatus according to an aspect of the present invention includes: a modeling unit that generates a fuse model based on shape information and physical property information of a fuse, and generates a fork terminal model based on shape information and physical property information of the fork terminal; a setting unit configured to set a first contact condition applied when the fuse model is inserted into the fork terminal model, and set a second contact condition applied when the fuse model is separated from the fork terminal model; a simulation unit that performs a simulation of inserting the fuse model into the fork terminal model under the first contact condition, and performs a simulation of separating the fuse model from the fork terminal model under the second contact condition; and a detection unit configured to detect a friction force generated between the fuse model and the fork terminal model according to the simulation.

In the present invention, the setting unit sets the first friction coefficient input from the outside as the first contact condition, and sets the second friction coefficient input from the outside as the second contact condition.

In the present invention, the friction force detected by the detection unit is compared with a preset reference range, and as a result of the comparison, if the friction force detected by the detection unit is out of the preset reference range, a determination unit that determines that the fork terminal model is inappropriate It is characterized in that it further includes;

In the present invention, as a result of the comparison, when the friction force detected by the detection unit is included in a preset reference range, the determination unit determines that the fork terminal model is suitable.

A fork terminal frictional force simulation method according to an aspect of the present invention comprises the steps of: generating, by a modeling unit, a fuse model based on shape information and physical property information of a fuse, and generating a fork terminal model based on shape information and physical property information of the fork terminal; ; setting, by a setting unit, a first contact condition applied when the fuse model is inserted into the fork terminal model, and setting a second contact condition applied when the fuse model is separated from the fork terminal model; performing, by a simulation unit, a simulation of inserting the fuse model into the fork terminal model under the first contact condition, and performing a simulation of separating the fuse model from the fork terminal model under the second contact condition; and detecting, by a detection unit, a friction force generated between the fuse model and the fork terminal model according to the simulation.

In the setting step in the present invention, the setting unit sets the first friction coefficient input from the outside as the first contact condition, and sets the second friction coefficient input from the outside as the second contact condition do.

Comparing, by the determination unit, the friction force detected through the detection unit with a preset reference range in the present invention; and determining, by the determination unit, that the fork terminal model is inappropriate when the friction force detected by the detection unit is out of a preset reference range as a result of the comparison.

In the present invention, when the friction force detected by the detection unit is included in the preset reference range as a result of the comparison in the present invention, determining, by the determination unit, that the fork terminal model is suitable; characterized in that it further comprises.

According to one aspect of the present invention, different coefficients of friction are applied to the case of inserting the fuse into the fork terminal and the case of separating the fuse from the fork terminal, thereby simulating the friction force of the fork terminal according to the insertion and separation of the fuse. Reliability can be improved.

1 is a block diagram illustrating a fork terminal friction force simulation apparatus according to an embodiment of the present invention.
2 is an exemplary view for explaining a modeling unit of the fork terminal friction force simulation apparatus according to an embodiment of the present invention.
3 is an exemplary view for explaining a detection unit of the fork terminal friction force simulation apparatus according to an embodiment of the present invention.
4 is a first flow chart for explaining a method for simulating a fork terminal friction force according to an embodiment of the present invention.
5 is a second flowchart for explaining a method for simulating the friction force of a fork terminal according to an embodiment of the present invention.

Hereinafter, an apparatus and method for simulating friction force of a fork terminal according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings. In this process, the thickness of the lines or the size of the components shown in the drawings may be exaggerated for clarity and convenience of explanation. In addition, the terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to the intention or custom of the user or operator. Therefore, definitions of these terms should be made based on the content throughout this specification.

Referring to FIG. 1 , an apparatus for simulating friction force of a fork terminal according to an embodiment of the present invention includes a modeling unit 100 , a setting unit 200 , a simulation unit 300 , a detection unit 400 , and a determination unit 500 . may include

The modeling unit 100 may generate a fuse model based on shape information and physical property information of the fuse, and may generate a fork terminal model based on shape information and physical property information of the fork terminal.

The shape information of the fuse may be information for defining the shape of the fuse model generated in the 3D space, and the information on the physical properties of the fuse may be information for defining the material of the fuse model generated in the 3D space. The above-described shape information and physical property information of the fuse may be included in the design drawing of the fuse, and the modeling unit 100 receives the design drawing of the fuse, and generates the fuse model in a three-dimensional space based on the received design drawing of the fuse. can be created on the

The shape information of the fork terminal may be information for defining a shape of a fuse model generated in a three-dimensional space, and information on physical properties of the fork terminal may be information for defining a material of a fork terminal model generated in a three-dimensional space. . The above-described shape information and physical property information of the fork terminal may be included in the design drawing of the fork terminal, and the modeling unit 100 receives the design drawing of the fork terminal, and based on the received design drawing of the fork terminal, the fork terminal A model can be created in 3D space.

FIG. 2A shows a fuse model generated in a three-dimensional space, and FIG. 2B shows a fork terminal model generated in a three-dimensional space. The fuse model may be inserted or removed from the fork terminal model as shown in FIG. 2C .

In general, a PCB board is provided in an indoor integrated power controller (ICU) of a vehicle, and a fork terminal is provided on the PCB board to connect a fuse to the PCB board. On the other hand, an appropriate level of frictional force must be generated between the fork terminal and the fuse to prevent the fuse from being easily separated from the fork terminal while the vehicle is being driven and to easily couple the fuse to the fork terminal when assembling the product.

Therefore, prior to producing a product, a test is performed to verify the frictional force generated during insertion or separation between the fork terminal and the fuse in the product design stage. At this time, in general, a test is performed to verify the friction force by applying the same friction coefficient condition to the case of removing the fuse from the fork terminal and the case of inserting the fuse into the fork terminal.

However, when the fuse is removed from the fork terminal, the friction coefficient changes as the surface shape of the fork terminal changes due to the insertion of the fuse. It is necessary to set the contact conditions (coefficient of friction).

Referring back to FIG. 1 , the setting unit 200 sets a first contact condition applied when the fuse model is inserted into the fork terminal model, and a second contact applied when the fuse model is separated from the fork terminal model. You can set conditions.

According to an embodiment of the present invention, the setting unit 200 receives a first friction coefficient from the outside, sets the input first friction coefficient as a first contact condition, receives a second friction coefficient from the outside, The input second friction coefficient may be set as the second contact condition.

That is, the setting unit 200 may receive a first friction coefficient from the outside (user), and may set the received first friction coefficient as a first contact condition to be applied when the fuse model is inserted into the fork terminal model. . In addition, the setting unit 200 may receive a second coefficient of friction from the outside (user), and may set the received second coefficient of friction as a second contact condition to be applied when the fuse model is separated from the fork terminal model. .

On the other hand, according to another embodiment of the present invention, the setting unit 200 predicts the degree of change in the surface shape of the fork terminal model according to the insertion of the fuse model based on the shape information of the fuse model and the fork terminal model, and the predicted result and The second friction coefficient may be calculated based on the first friction coefficient input from the outside.

As described above, the present invention applies different coefficients of friction to the case of inserting the fuse into the fork terminal and the case of separating the fuse from the fork terminal, so that the friction coefficient changes as the surface shape of the fork terminal changes due to the insertion of the fuse. It is possible to perform a simulation to detect frictional force due to insertion or separation between the fork terminal and the fuse by reflecting the

Meanwhile, in the first and second contact conditions, in addition to the friction coefficient, information on the magnitude and direction of the force (normal drag) to be applied to the fuse model to move the fuse model when the fuse model is inserted or disconnected from the fork terminal model is included. may be included.

The simulation unit 300 may perform a simulation of inserting the fuse model into the fork terminal model under the first contact condition, and perform a simulation of separating the fuse model from the fork terminal model under the second contact condition.

For example, the simulation unit 300 performs a first simulation of inserting the fuse model into the fork terminal model in an environment in which the friction coefficient between the fuse model and the fork terminal model is the first coefficient of friction, and between the fuse model and the fork terminal model. A second simulation of separating the fuse model from the fork terminal model may be performed in an environment in which the friction coefficient is the second coefficient of friction.

The detection unit 400 may detect a friction force generated between the fuse model and the fork terminal model according to the simulation.

For example, the detection unit 400 may detect a friction force generated between the fuse model and the fork terminal model while performing a first simulation of inserting the fuse model into the fork terminal model. Also, the detection unit 400 may detect a friction force generated between the fuse model and the fork terminal model while performing a second simulation of separating the fuse model from the fork terminal model.

Referring to FIG. 3 , the frictional force generated between the fork terminal model and the fuse model during the first simulation of inserting the fuse model into the fork terminal model is shown from 0 seconds to 1 second, and from 1 second to 2 seconds The frictional force generated between the fork terminal model and the fuse model during the second simulation of separating the fuse model from the fork terminal model is shown.

The determination unit 500 compares the friction force detected by the detection unit 400 with a preset reference range, and when the friction force detected through the detection unit 400 is out of the preset reference range as a result of comparison, the fork terminal model is deemed inappropriate. can judge When it is determined that the fork terminal model is inappropriate, the simulation unit 300 changes the shape information of the fork terminal model through the input unit, or after changing the first contact condition or the second contact condition through the setting unit 200 , the simulation can be performed again.

On the other hand, if the friction force detected by the comparison result detection unit 400 is included in the preset reference range, it may be determined that the fork terminal model is suitable. In this case, the determination unit 500 may output the friction force detected through the detection unit 400 to the outside.

For example, the determination unit 500 may output the friction force detected by the detection unit 400 through an output device such as a display or output in the form of an electronic document.

As described above, the present invention provides a fork terminal design by simulating the friction force of the fork terminal according to the insertion and removal of the fuse by applying different coefficients of friction to the case of inserting the fuse into the fork terminal and the case of separating the fuse from the fork terminal. can improve the reliability of

4 is a first flowchart illustrating a method for simulating a fork terminal friction force according to an embodiment of the present invention, and FIG. 5 is a second flowchart illustrating a method for simulating a fork terminal friction force according to an embodiment of the present invention.

Hereinafter, a fork terminal frictional force simulation method according to an embodiment of the present invention will be described with reference to FIGS. 4 and 5 .

First, referring to FIG. 4 , the modeling unit 100 may generate a fuse model based on shape information and physical property information of the fuse, and may generate a fork terminal model based on shape information and physical property information of the fork terminal. (Step S100)

Subsequently, the setting unit 200 may set a first contact condition applied when the fuse model is inserted into the fork terminal model, and set a second contact condition applied when the fuse model is separated from the fork terminal model. .(Step S200)

For example, the setting unit 200 may receive a first friction coefficient from the outside (user), and set the received first friction coefficient as the first contact condition to be applied when the fuse model is inserted into the fork terminal model. can In addition, the setting unit 200 may receive a second coefficient of friction from the outside (user), and may set the received second coefficient of friction as a second contact condition to be applied when the fuse model is separated from the fork terminal model. .

For example, the setting unit 200 receives a first friction coefficient from the outside, sets the input first coefficient of friction as a first contact condition, receives a second friction coefficient from the outside, and receives the input second friction The coefficient can be set as the second contact condition.

Subsequently, the simulation unit 300 may perform a simulation of inserting the fuse model into the fork terminal model under the first contact condition, and perform a simulation of separating the fuse model from the fork terminal model under the second contact condition (S300). step)

For example, the simulation unit 300 performs a first simulation of inserting the fuse model into the fork terminal model in an environment in which the friction coefficient between the fuse model and the fork terminal model is the first coefficient of friction, and between the fuse model and the fork terminal model. A second simulation of separating the fuse model from the fork terminal model may be performed in an environment in which the friction coefficient is the second coefficient of friction.

Subsequently, the detection unit 400 may detect a friction force generated between the fuse model and the fork terminal model according to the simulation (step S400).

For example, the detection unit 400 may detect a friction force generated between the fuse model and the fork terminal model while performing a first simulation of inserting the fuse model into the fork terminal model. Also, the detection unit 400 may detect a friction force generated between the fuse model and the fork terminal model while performing a second simulation of separating the fuse model from the fork terminal model.

Then, the determination unit 500 may compare the friction force detected through the detection unit 400 with a preset reference range. (Step S500)

As a result of the comparison, when the friction force detected by the detection unit 400 is included in the preset reference range, the determination unit 500 may determine that the fork terminal model is suitable. (Step S600)

When it is determined that the fork terminal model is suitable, the determination unit 500 may output a result detected through the detection unit 400 to the outside. (Step S700)

On the other hand, referring to FIG. 5 , when the friction force detected by the comparison result detection unit 400 is out of a preset reference range, the determination unit 500 may determine that the fork terminal model is inappropriate. (Step S800 )

When it is determined that the fork terminal model is inappropriate, the simulation unit 300 changes the shape information of the fork terminal model through the input unit or after changing the first contact condition or the second contact condition through the setting unit 200, Simulation can be performed again. (Step S900)

Meanwhile, even when it is determined that the fork terminal model is inappropriate, the determination unit 500 may output a result detected through the detection unit 400 to the outside. (Step S1000)

As described above, in the fork terminal frictional force simulation apparatus and method according to an embodiment of the present invention, different friction coefficients are applied when the fuse is inserted into the fork terminal and when the fuse is separated from the fork terminal. It is possible to perform a simulation to detect frictional force due to insertion or separation between the fork terminal and the fuse by reflecting the change in the friction coefficient as the surface shape of the fork terminal changes.

Implementations described herein may be implemented in, for example, a method or process, an apparatus, a software program, a data stream, or a signal. Although discussed only in the context of a single form of implementation (eg, discussed only as a method), implementations of the discussed features may also be implemented in other forms (eg, as an apparatus or program). The apparatus may be implemented in suitable hardware, software and firmware, and the like. A method may be implemented in an apparatus such as, for example, a processor, which generally refers to a computer, a microprocessor, a processing device, including an integrated circuit or programmable logic device, or the like. Processors also include communication devices such as computers, cell phones, portable/personal digital assistants (“PDA”) and other devices that facilitate communication of information between end-users.

Although the present invention has been described with reference to the embodiment shown in the drawings, this is merely exemplary, and it is understood that various modifications and equivalent other embodiments are possible by those of ordinary skill in the art. will understand Accordingly, the true technical protection scope of the present invention should be defined by the following claims.

100: modeling unit
200: setting unit
300: simulation unit
400: detection unit
500: judgment unit

Claims (8)

a modeling unit generating a fuse model based on shape information and physical property information of the fuse, and generating a fork terminal model based on shape information and physical property information of the fork terminal;
a setting unit that sets a first contact condition applied when the fuse model is inserted into the fork terminal model and sets a second contact condition that is applied when the fuse model is separated from the fork terminal model;
a simulation unit that performs a simulation of inserting the fuse model into the fork terminal model under the first contact condition, and performs a simulation of separating the fuse model from the fork terminal model under the second contact condition; and
a detection unit configured to detect a friction force generated between the fuse model and the fork terminal model according to the simulation;
The setting unit sets a first friction coefficient as the first contact condition, and sets a second friction coefficient different from the first friction coefficient as the second contact condition.
delete The method of claim 1,
A determination unit that compares the friction force detected through the detection unit with a preset reference range, and determines that the fork terminal model is inappropriate when the friction force detected through the detection unit is out of the preset reference range as a result of the comparison; Fork terminal frictional force simulation device, characterized in that.
4. The method of claim 3,
As a result of the comparison, when the friction force detected by the detection unit falls within a preset reference range, the determination unit determines that the fork terminal model is suitable.
generating, by the modeling unit, a fuse model based on shape information and physical property information of the fuse, and generating a fork terminal model based on shape information and physical property information of the fork terminal;
setting, by a setting unit, a first contact condition applied when the fuse model is inserted into the fork terminal model, and setting a second contact condition applied when the fuse model is separated from the fork terminal model;
performing, by a simulation unit, a simulation of inserting the fuse model into the fork terminal model under the first contact condition, and performing a simulation of separating the fuse model from the fork terminal model under the second contact condition; and
detecting, by a detection unit, frictional force generated between the fuse model and the fork terminal model according to the simulation;
In the setting step, the setting unit,
A method for simulating the friction force of a fork terminal, characterized in that a first coefficient of friction is set as the first contact condition, and a second coefficient of friction different from the first coefficient of friction is set as the second contact condition.
delete 6. The method of claim 5,
comparing, by a determination unit, the friction force detected through the detection unit with a preset reference range; and
and determining, by the determination unit, that the fork terminal model is inappropriate when the friction force detected by the detection unit is out of a preset reference range as a result of the comparison.
8. The method of claim 7,
and determining, by the determination unit, that the fork terminal model is suitable when, as a result of the comparison, the friction force detected by the detection unit falls within a preset reference range.

Images