The present application claims priority from Japanese application JP2006-066906 filed on Mar. 13, 2006, the content of which is hereby incorporated by reference into this application.
The present invention relates to a method and system for supporting design of home electric appliances, OA devices, and the like.
As a method for quantitatively evaluating a parts assembling time in the product design, for example, JP-A-2003-39260 discloses a method for analyzing the product parts assembling operation and calculating the assembling time for each of the parts. This is an assembly time estimation method including a step for making about 50 types of assembly operations and attribute assembly difficulties into coefficients in advance, a step for analyzing the assembly operations and attributes of parts of a product, a calculation step for calculating the assembling time of each part according to the analyzed data and the assembly difficulty by using Expression (1) given below, and a step for displaying the calculation result.
[Assembly time tx]=[toperation x]×[βattribute y1]×[βattribute y2]× . . . (1),
wherein toperation x represents the assembling operation time when no attribute exists, and βattribute y represents a ratio of the affect given to the assembling operation time by the attribute accompanying the assembling operation (assembly difficulty (attribute)).
Moreover, as a method for quantitatively evaluating a defective assembly occurrence ratio, for example, JP-A-10-334151 discloses a method for analyzing a product parts assembling operation and calculating a defective assembly occurrence ratio for each part. This is a defective assembly occurrence ratio estimation method including a step for making defective assembly potential of about 50 types of assembling operations and attributes into coefficients in advance, a step for analyzing product parts assembling operations and attributes, a calculation step for calculating a defective assembly occurrence ratio of each part from the analyzed data and the defective assembly coefficient by using Expression (2) given below, and a step for displaying the calculation result
[Defective assembly occurrence ratio ux]=[uoperation x]×[θattribute y1]×[θattribute y2]× (2),
wherein u operation x represents the defective assembly occurrence ratio when no attribute exists, and θattribute y represents a ratio of the affect given to the defective assembly occurrence ratio by the attribute accompanying the assembling operation (defective assembly coefficient (attribute)).
Moreover, as a method for creating improvements for solving the problems, for example, Matrix 2003: Updating the TRIZ Contradiction Matrix (Darrell Mann, Simon Dewulf, Boris Zlotin, Alla Zusman, CREAX Press, Belgium, 2003) suggests a method for selecting an item to be improved and a problem generated by the improvement from a two-dimensional table and guiding the page describing a hint for the improvement. The method divides an enormous amount of patent items in the past into items to be improved such as “weight of a moving object” and items degraded by the improvement such as “strength of the moving object” and summarizes “how to solve the problems of the items degraded when the improvement item is executed.”Firstly, a two-dimensional table is created with “improvement items” arranged vertically and “degraded items” arranged horizontally. Then, at their intersecting points, numbers attached to “the solution examples” are written. Another table is prepared with the numbers and “the solution examples”. A designer firstly searches for a corresponding number in the two-dimensional table. Next, the designer searches for the solution example described in the column of the number. Lastly, by referencing the solution example, the designer creates an improvement configuration.
However, even if it is possible to estimate the assembling time for each part and the defective assembly occurrence ratio, it is impossible to know how the assembling operation of the part and the attribute affect the total assembling cost obtained by adding the assembling cost and a loss caused by defective assembly and it is impossible to specify an improvement object. Moreover, even if it is possible to identify a part requiring a long assembling time and a part causing a high defective assembly occurrence ratio, it is impossible to create a configuration plan for improving them.
Moreover, since the aforementioned Matrix 2003 aims at improvement of the basic performance and has a problem that it cannot be employed for reducing the assembling time concerning a specific part assembling operation and attribute and reducing the defective assembly occurrence ratio.
It is therefore an object of the present invention to provide a method and a system for supporting design capable of supporting creation of improvement measures to reduce the assembling time and defective assembly and deciding priority of the assembling time reduction measure and the defective assembly reduction measure.
In order to achieve the aforementioned object, the present invention provides a design support method for extracting an improvement guideline for reducing the assembling time and an improvement guideline for reducing the defective assembly in a design to be improved by using the design support system. The method stores in advance, as a database, coefficients indicating assembly difficulties of respective operations and attributes and coefficients indicating defective assembly potentials which have been decided from a plenty of design examples in the past and improvement guideline data collected as improvement guidelines for the assembling operations/attributes and reducing the assembling time of the assembling operations/attributes and improvement guidelines for reducing defective assembly which collected and spread in a hierarchy while being correlated with one another. The method extracts elements requiring a long assembling time and elements having a high defective assembly generation ratio from the parts, the assembling operations, and the attributes in the design examples. The extracted elements are converted into assembling costs and assembly loss costs to compare the importance so as to decide the element requiring improvement. The guideline for improving the element is extracted.
According to the present invention, it is possible to extract improvement guidelines for reducing an assembling time and reducing defective assembly by inputting assembling operation analysis data on the product to be improved.
Other objects, features and advantages of the invention will become apparent from the following description of the embodiments of the invention taken in conjunction with the accompanying drawings.
Description will now be directed to embodiments of the present invention with reference to the attached drawings.
Firstly, explanation will be given on a design support system according to a first embodiment of the present invention.
The database unit 40 is formed by an assembly difficulty coefficient database 41, an assembling time improvement guideline database 43, and an assembling time actual guideline building database 45. It should be noted that a defective assembly coefficient database 42, a defective assembly improvement guideline database 44, and a defective assembly actual guideline building database 46 are used in the second embodiment and after and not used in the first embodiment.
Firstly, explanation will be given on the assembly difficulty coefficient database 41, the assembling time improvement guideline database 43, and the assembling time actual guideline building database 45. These databases are formed in advance by using the actual product assembling results in the past.
1-1 Assembly Difficulty Coefficient Database 41
As shown in
In step S311 of
(1) Move the case 51 downward and place it on a assembling table.
(2) As shown by 1) in
(3) As shown by 2) in
(4) As shown by 3) in
(5) As shown by 4) in
As shown in
(1) Part name: Describe the part name directly in the part/name column 611. Moreover, describe the number of parts into the quantity column 612.
(2) Assembling operation: Select an assembling operation of each part from the assembling operation terms prepared in advance and describe it in the appearance order in the assembling operation/name column 613. Moreover, describe the number of repetitions of each assembling operations in the repetition quantity column 614.
(3) Attribute: Select an attribute accompanying each assembling operation from the attribute terms prepared in advance and describe it in the attribute/name column 615. Moreover, describe the number of repetitions of each assembling operation in the repetition quantity column 616.
It should be noted that each part, assembling operation, attribute used in the assembling operation analysis will be called generically assembling elements.
Next, in step S312 of
Next, in step S313 of
The assembling time of an assembled product is calculated by adding the assembling time of each part. The assembling time of each part can be calculated by adding the assembling time of respective assembling operations of the part. The assembling time of each assembling operation is decided by the assembling operation and attribute. Accordingly, the assembling time tx of the assembling operation x is defined by the expression as follows.
[Assembling time tx][toperation x]×[βattribute y1]×[βattribute y2]× . . . (Expression 1)
wherein toperation x represents the assembling operation time when no attribute exists and βattribute y represents the ratio of the affect given to the assembling operation time by the attribute accompanying the assembling operation (assembly difficulty coefficient (attribute)).
Furthermore, in order to make the assembling operation time toperation x dimension-less, the value of the assembling operation time toperation x divided by [downward]tDownward 0 which is the shortest assembling time is defined as the assembly difficulty coefficient αoperation x of the assembling operation.
[assembling operation assembly difficulty coefficient: αoperation x]=[toperation x]/[tDownward 0] (Expression 2)
As shown in
Firstly, the downward operation time tDownward 0 serving as the reference for estimating the assembling time is calculated as follows.
tDownward 0=(ΣtDownward i)/n (Expression 3)
Next, the assembly difficulty coefficient αoperation x of each assembling operation is calculated. Firstly, the deforming operation time tDeforming 0 is calculated as follows.
tDeforming 0=(ΣtDeforming i)/n (Expression 4)
Accordingly, the assembly difficulty coefficient αDeforming can be obtained by the following expression.
αDeforming=tDeforming 0/tDownward 0 (Expression 5)
Next, the assembly difficulty coefficient βattribute y of the attribute y is calculated according to the assembling time ration depending on presence/absence of the attribute y. For example, the assembly difficulty coefficient βAesthetic surface of the attribute “aesthetic surface” is expressed as follows.
βAesthetic surface=(tDownward Aesthetic surface 1/tDownward 0+tRotational Aesthetic surface 2/tRotational 0+ . . . )/n (Expression 6)
By using the aforementioned expressions, it is possible to calculate the assembly difficulty coefficient of the assembling operation and the attribute from the inputted assembling operation analysis results and actual measurement data on the assembling operations. These are stored in the assembly difficulty coefficient database of
By storing assembly difficulty coefficients concerning a plenty of general products prepared in advance in the assembly difficulty coefficient database 41 of
Moreover, by continuously executing the assembling operation analysis and the assembling operation time measurement and inputting the obtained data into the design support system 1 so as to increase the number of samples, it is possible to set a more reliable assembly difficulty coefficient.
Furthermore, when the product size and the assembling work environment are greatly changed such as in a case that products of completely different size should be produced in an oversea factory, by inputting the assembling operation actual measurement data on the factory and on the product, it is possible to easily set an assembly difficulty coefficient appropriate for the factory.
1-2 Assembling Time Improvement Guideline Database 43
As shown in
Firstly, in step S331 of
In step S332 of
Next, in step S333 of
(1) The design support system 1 extracts the last element of the inputted assembling operation analysis data in
(2) As shown in
(3) In step S334 of
Next, the designer decides the a generalized improvement guideline and a specific improvement plan according to the grouped improvement examples.
The improvement guideline is decided without specifying a technical field so that it can be used in another technical field. In
As shown in
1-3 Assembling Time Concrete Guideline Building Database 45
The improvement guidelines stored in the assembling time improvement guideline database 43 are generalized by the aforementioned algorithm and even if they are extracted by an algorithm which will be detailed later, no concrete image cannot be obtained and it is difficult to judge whether good or bad. To cope with this, an associated element is extracted from the inputted assembling elements and a necessary word or phrase is added so as to build a concrete improvement guideline. These algorithms are stored in the assembling time concrete guideline building database 45.
For example, as an improvement guideline for the rotational operation of the switching lever in
By using these, a concrete improvement guideline is built as follows.
In order to reduce the rotational operation time of the “switching lever”, the “switching lever” is assembled by rectilinear movement.
1) widen the engagement portion tip end
2) narrow the engagement portion tip end
Thus, it is possible to specify a generalized improvement guideline “Assemble by rectilinear movement, 1) widen the engagement portion tip end, and 2) narrow the engagement portion tip end”
The databases 41, 43, 45 may not be collected by the design support system 1 but collected by other design support system and transmitted to the design support system 1 via a network so as to be stored there.
Next, explanation will be given on an improvement design for reducing the assembling time in the design support system 1 according to the first embodiment of the present invention.
Moreover,
2-1 Assembling Operation Analysis Data Input
In step S101 of
In step S102 of
2-2 Assembling Time Affect Degree Index Calculation
In step S103 of
(1) An assembling time difference caused by presence and absence of one part can be considered to be the time required for the part. The time difference is divided by the total assembling time and multiplied by 100 to obtain a value which is defined as the part index of the assembling time affect degree index.
(2) An assembling time difference caused by presence and absence of one assembling operation can be considered to be the time required for the assembling operation. The time difference is divided by the total assembling time and multiplied by 100 to obtain a value which is defined as the assembling operation index of the assembling time affect degree index.
(3) An assembling time difference caused by presence and absence of one attribute can be considered to be the time required for the attribute. The time difference is divided by the total assembling time and multiplied by 100 to obtain a value which is defined as the attribute index of the assembling time affect degree index.
In the case of assembling of the switching lever shown in
(1) Assembling time affecting degree index eDeforming of switching lever deforming operation
1) Switching lever deforming operation time tDeforming×2=tDownward 0×αDeforming×2=11×1.73×2=38 seconds
2) Assembling time affecting degree index eDeforming=(100−(100−38))×100/100=38
(2) Assembling time affecting degree index eRotational of switching lever rotational operation
1) Switching lever rotational operation time tRotational Aesthetic surface Hidden=tDownward 0×αRotational×βAesthetic surface×βHidden=11×2.63×1×1=29 seconds
2) Assembling time affecting degree index eRotational=(100 (100−29))×100/100=29
(3) Switching lever assembling time affecting degree index eswitching lever
1) Switching lever assembling operation time tswitching lever=tdownward 0+tDeforming+tRotational Aesthetic surface Hidden+tClinching Multiple holes=89 seconds
2) Assembling time affecting degree index eswitching lever=(100−(100−89))×100/100=89
In this example, the assembling time affecting degree index of each assembling element is shown assuming 100 as the total assembling time. It should be noted that instead of the assembling time affecting index, it is possible to use the assembling time itself.
Here, as shown in step S104 of
2-3 Extraction of Assembling Element Requiring Improvement
In step S106 of
In this example, the following three elements having high assembling time affecting degree indexes are extracted:
(1) “switching lever”
(2) “deforming” operation of the switching lever
(3) “rotational” operation of the switching lever
2-4 Generalized Improvement Plan Extraction
In step S107 of
(1) Assembling element requiring improvement (part): “switching lever”
improvement guideline: “divide the part to be assembled and change the assembling order, 1) the part whose assembling is difficult is assembled lastly”; “unify it with another part, 1) outsert molding, 2) use of elasticity of member”
(2) Assembling element requiring improvement (assembling operation): “deforming”
improvement guideline: “degrade the deforming operation, 1) directly attach to the substrate”; “use the part to be assembled as a jig 1) form a tapered portion on an engagement portion”
(3) Assembling element requiring improvement (assembling operation): “rotational”
improvement guideline: “assemble by rectilinear operation, 1) widen the engagement portion tip end 2) narrow the engagement portion tip end”
2-5 Building Concrete Improvement Guideline
In step S108 of
(1) Generalized improvement guideline: “divide the part to be assembled and change the assembling order, 1) the part whose assembling is difficult is assembled lastly”
associated phrase: “switching lever”
concrete improvement guideline: “in order to reduce the assembling time of the [switching lever], [divide the part to be assembled and change the assembling order, 1) the part whose assembling is difficult is assembled lastly]”
(2) Generalized improvement guideline: “eliminate the need of deforming operation”
associated phrase: [switching lever], [deforming]
concrete improvement guideline: “in order to reduce the [deforming] operation time of the [switching lever], [eliminate the need of deforming operation, 1) directly attach to the substrate] of the [switching lever]”
(3) Generalized improvement guideline: “assemble by rectilinear movement, 1) widen the engagement portion tip end”
associated phrase: [assemble by rectilinear movement], [rotational]
concrete improvement guideline: “in order to reduce the [rotational] operation time of the [switching lever], [assemble the [switching lever] by rectilinear movement, 1) widen the engagement portion tip end]”
In step S109 of
Moreover, the concrete improvement guideline display column 622 in
2-6 Assembling Time Reduction Improvement Configuration Creation, and Assembling Operation Analysis
As shown in
(1) By referencing the improvement guideline 1-1 “in order to reduce the switching lever assembling time, divide the part to be assembled and change the assembling order, 1) assemble the part whose assembling is difficult, lastly”, the designer can create the improvement configuration plan as follows.
“Divide the case 51 into an upper and a lower portion and change the assembling order into the case lower portion 511, the switching lever 521 and the case upper portion 511a.” The assembling operations are as follows:
1) Place the case lower portion 511 on the working table.
2) Mount the switching lever 521 on the case lower portion 511. Here, since the surface of the case lower portion 511 is a designed surface, a care should be taken in the assembling operation.
3) Assemble the case upper portion 511a to the case lower portion 511.
(2) By referencing the improvement guideline 1-2 “in order to reduce the switching lever assembling time, unify it with another part, 1) outsert molding, 2) use of elasticity of member”, the designer can create the following improvement configuration plan.
“Mold the switching button 522 replacing the switching lever 522 together with the case 512 as a unitary block”
By the elasticity of the case 512, the pressed switching button 522 is automatically restored. In this case, at the stage when the case 512 is molded, the member performing the switching lever function is molded and no assembling operation is required.
(3) By referencing the improvement guideline 3-1 “in order to reduce the switching lever rotational operation time, assemble the switching lever by rectilinear movement, 1) widen the engagement portion tip end, 2) narrow the engagement portion tip end”, the designer can create the following improvement configuration plan.
“Narrow the tip end 523a of the switching lever 523 and assemble it by rectilinear movement”
The assembling operation is as follows.
1) Place the case lower portion 513 on the working table.
2) Move the switching lever 523 downward and mount its tip end 523a on the case lower portion 513. Here, since the surface of the case 513 is a designed surface, a care should be taken in the assembling operation.
3) Clinch the switching lever 523 into the case 513. Here, a care should be taken so that the three tip ends 523a of the switching lever are simultaneously engaged with the case.
In step S112 of
2-7 Calculating the Assembling Time
In step S113 of
Thus, the designer can examine the concrete configuration in the descending order of the improvement effect and can effectively perform the improvement design.
Next, explanation will be given on the improvement design for reducing the defective assembly in the design support system 1 according to a second embodiment of the present invention.
Moreover, the database unit 40 is formed by a defective assembly coefficient database 42, a defective assembly improvement guideline database 44, and a defective assembly concrete guideline building database 46. It should be noted that the assembly difficulty coefficient database 41, the assembling time improvement guideline database 43, and the assembling time concrete guideline building database 45 are not used in this embodiment.
Firstly, explanation will be given on the defective assembly coefficient database 42, the defective assembly improvement guideline database 44, and the defective assembly concrete guideline building database 46. These databases are built from the actual occurrence of defective assembly in the past.
1-1 Defective Assembly Coefficient Database 42
As shown in
Firstly, in step S321 of
Next, in step S322 of
Next, in step S323 of
The defective assembly generation ratio of an assembled product can be calculated by adding the defective assembly generation ratio of the respective parts constituting the product. The defective assembly generation ratio of each part can be calculated by the total of the defective assembly generation ratios of the respective assembling operations of the part. The defective assembly generation ratio of each assembling operation is decided by its assembling operation and the attribute. Accordingly, the defective assembly generation ration ux of the assembling operation is defined by the following expression.
[Defective assembly generation ration ux]=[uoperation x]×[θattribute y1]×[θattribute y2]× . . . (Expression 7)
wherein uoperation x represents the defective assembly generation ratio when no attribute exists, and θattribute y represents a ratio of the affect given to the defective assembly generation ratio by the attribute accompanying the assembling operation (defective assembly coefficient (attribute)).
Furthermore, in order to make the defective assembly generation ratio uoperation x dimension-less, the value of the defective assembly generation ratio uoperation x divided by the [downward operation] uDownward 0 having the smallest defective assembly generation ration is defined as the defective assembly coefficient γoperation x of the assembling operation.
[Defective assembly coefficient of assembling operation: γoperation x]=[uoperation x]/[uDownward 0] (Expression 8)
As shown in
Firstly, the defective downward generation ratio uDownward 0 as the reference of the defective assembly generation ration is calculated from the following expression.
uDownward 0=(ΣuDownward i)/n (Expression 9)
Next, the defective assembly coefficient γoperation x of each assembling operation is calculated. For example, the defective deforming generation ration tDeforming 0 is calculated by the following expression.
uDeforming 0=(ΣuDeforming i)/n (Expression 10)
Accordingly, the defective assembly coefficient γDeforming of the deforming operation is obtained by the following expression.
γDeforming=uDeforming 0/uDownward 0 (Expression 11)
Next, the defective assembly coefficient γattribute y of the attribute y is calculated from the ratio of the defective assembly generation ratio between the presence/absence of the attribute y. For example, the defective assembly coefficient θAesthetic surface of the attribute “aesthetic surface” is obtained by the following expression.
θAesthetic surface=(uDownward Aesthetic surface 1/uDownward 0+uRotational Aesthetic surface 2/uRotational 0+ . . . )/n (Expression 12)
As has been described above, it is possible to calculate the defective assembly coefficients of the operation and the attribute from the inputted assembling operation analysis result and the defective assembly generation ratio actual result data. These are stored in the defective assembly coefficient database 42 in
By storing the defective assembly quantity associated with a plenty of general products prepared in advance, in the database 42, it is possible to use the design support system 2 without executing the steps S321, S322, S323 in
Moreover, by continuously inputting the assembling operation analysis results and the actual result data on the defective assembly generation ratio so as to increase the number of samples, it is possible to set a more reliable defective assembly coefficient.
Furthermore, when the product size and the assembling work environment are greatly changed in such a case that products of completely different size should be produced in an oversea factory, by inputting the actual result data on the defective assembly generation ratio of the product in the factory, it is possible to easily set a defective assembly coefficient appropriate for the factory.
1-2 Defective Assembly Improvement Guideline Database 44
As shown in
The improvement guideline is decided without specifying a particular technical field so that it can be used in other technical fields. In
As shown in
1-3 Defective Assembly Concrete Guideline Building Database 46
Since the improvement guideline stored in the defective assembly improvement guideline database 44 is generalized by the aforementioned algorithm, when it is extracted by an algorithm which will be detailed later, no concrete image is formed and it is difficult to decide whether good or bad. To cope with this, an element associated with the inputted assembling element is extracted and a necessary word or phrase is added so as to build a concrete improvement guideline. These algorithms are stored in the defective assembly concrete guideline building database 46.
For example, as the improvement guideline corresponding to the attribute “it is difficult to view the connection portion” accompanying the rotational operation of the switching lever in
By using them, a concrete improvement plan as follows is built up.
“In order to reduce the operation time of “rotational” accompanied by the attribute “hidden” (it is difficult to view the connection portion) of “the switching lever”, “rearrange the connection portion in the visible region.”
Thus, it is possible to specify the generalized guideline as a concrete guideline “rearrange the connection portion in the visible region”.
The databases 42, 44, 46 may not be collected by the design support system 2 but may be collected by other design support system and transmitted to the design support system 1 via the network.
Next, explanation will be given on the improvement design for reducing the defective assembly in the design support system 1 according to the second embodiment of the present invention.
2-1 Inputting Assembling Operation Analysis Data
In step S201 in
In step S202 of
2-2 Calculating Defective Assembly Affecting Degree Index
In step S203 of
(1) The difference between the defective assembly generation ratios when a part is present and absent is considered to be a defective assembly generated by the presence of the part. The difference between the defective assembly generation ratios is divided by the entire defective assembly generation ratio and multiplied by 100 to obtain a part index of the assembling time affecting degree index.
(2) The difference between the defective assembly generation ratios when an assembling operation is present and absent is considered to be a defective assembly generated by the presence of the assembling operation. The difference between the defective assembly generation ratios is divided by the entire defective assembly generation ratio and multiplied by 100 to obtain an assembling operation index of the defective assembly affecting degree index.
(3) The difference between the defective assembly generation ratios when an attribute is present and absent is considered to be a defective assembly generated by the presence of the attribute. The difference between the defective assembly generation ratios is divided by the entire defective assembly generation ratio and multiplied by 100 to obtain an attribute index of the defective assembly affecting degree index.
In the case of the switching lever shown in
(1) Defective assembly affecting degree index of the switching lever rotational operation eRotational
1) Defective assembly generation ratio in the switching lever rotational operation uRotational Aesthetic surface Hidden=uDownward 0×γRotational×θAesthetic surface×θHidden=1×11×1×5.18=57 ppm
2) Defective assembly affecting degree index eRotational=(100−(100−57))×100/100=57
(2) Defective assembly affecting degree index of the attribute that it is difficult to view the connection portion accompanying the switching lever rotational operation eHidden
1) Defective assembly generation ratio when the attribute that it is difficult to view the connection portion is absent in the switching lever rotational operation uRotational Aesthetic surface=uDownward 0×γRotational×θAesthetic surface=1×11×1=11 ppm
2) Defective assembly affecting degree index eRotational=(57−11)×100/100=46
(3) Defective assembly affecting degree index of the switching lever eswitching lever
1) Defective assembly generation ratio of the switching lever uswitching lever=uDownward 0+uDeforming+uRotational Aesthetic surface Hidden+uClinching Multiple holes=99 ppm
2) Defective assembly affecting degree index eswitching lever=(100−(100−99))×100/100=99
In this example, the defect affecting degree index of each assembling element is displayed when the entire defect generation ratio is 100. It should be noted that instead of the defect affecting degree index, it is possible to use the defect generation ratio itself.
As shown in step S204 in
2-3 Extracting Assembling Elements to be Improved
In step S206 in
In this example, as shown in
(1) “switching lever”
(2) “rotational” operation of the switching lever
(3) attribute “hidden” (it is difficult to view the connection portions) accompanying the rotational operation of the switching lever
2-4 Extracting Generalized Improvement Guideline
In step S207 in
(1) Element requiring improvement (part): “switching lever”
Improvement guideline: “Divide the part to be assembled and change the assembling order, 1) the part which is difficult to be assembled is assembled lastly”
“Unify with other part, 1) outsert molding, 2) use elasticity of member”
(2) Element requiring improvement (assembling operation): “rotational”
Improvement guideline: “assemble with rectilinear movement, 1) widen the engagement portion tip end, 2) sharpen the engagement portion tip end”
(3) Element requiring improvement (attribute): “hidden” (it is difficult to view the connection portion)
Improvement guideline: “rearrange the connection portion into a visible region”
2-5 Building Concrete Improvement Guideline
In step S208 in
(1) Generalized improvement guideline: “Divide the part to be assembled and change the assembling order, 1) the part which is difficult to be assembled is assembled lastly”
associated phrase: [switching lever]
concrete improvement guideline: “In order to reduce the defective assembly of the [switching lever], [divide the part to be assembled and change the assembling order]”
(2) Generalized improvement guideline: “unify with other part, 1) outsert molding, 2) use elasticity of member”
associated phrase: [switching lever]
concrete improvement guideline: “In order to reduce the defective assembly of the [switching lever],[divide the part to be assembled and change the assembling order]”
(3) Generalized improvement guideline: “assemble with rectilinear movement, 1) widen the engagement portion tip end, 2) sharpen the engagement portion tip end”
associated phrase: [switching lever], [rotational]
concrete improvement guideline: “In order to reduce the defective assembly of the [switching lever] in the [rotational] operation, assemble the [switching lever][with rectilinear movement, 1) widen the engagement portion tip end, 2) sharpen the engagement portion tip end]”
(4) Generalized improvement guideline: “rearrange the connection portion into a visible region”
associated phrase: [switching lever], [rotational], [it is difficult to view the connection portion]
concrete improvement guideline: “In order to reduce the defective assembly in the [rotational] operation accompanied by the attribute “it is difficult to view the connection portion] of the [switching lever], [rearrange the connection portion into a visible region]”
In step S209 in
Moreover, the concrete improvement guideline display column 622 in
2-6 Creating Plan for Reducing/Improving Defective Assembly and Analyzing Assembling Operation
As shown in
(1) By referencing the improvement guideline 1-1 “in order to reduce the defective assembly of the switching lever, divide the part to be assembled and change the assembling order, 1) the part which is difficult to be assembled is assembled lastly”. the designer can create the following improvement plan.
“Divide the case 51 into an upper and a lower portion and change the assembling order into the case lower portion 511, the switching lever 521, and the case upper portion 511a.” The assembling operations are as follows:
1) Place the case lower portion 511 on the working table.
2) Mount the switching lever 521 on the case lower portion 511. Here, since the surface of the case lower portion 511 is a designed surface, a care should be taken in the assembling operation.
3) Assemble the case upper portion 511a with the case lower portion 511.
(2) By referencing the improvement guideline 2-1 “In order to reduce the defective assembly of the switching lever in the rotational operation, assemble the switching lever with rectilinear movement, 1) widen the engagement portion tip end, 2) narrow the engagement portion tip end”, the designer can create the following improvement plan.
“narrow the tip end 523a of the switching lever 523 and assemble it by rectilinear movement”
The assembling operations are as follows.
1) Place the case lower portion 513 on the working table.
2) Move the switching lever 523 downward and place its tip end 523a on the case lower portion 513. Here, since the surface of the case 513 is a designed surface, a care should be taken in the assembling operation.
3) Insert the switching lever 523 in the case 513 with pressure. Here, a care should be take in the assembling operation so as to simultaneously insert the three tip end portions 523a of the switching lever.
(3) By referencing the improvement guideline 3-1 “In order to reduce the defective assembly of the switching lever in the rotational operation having the attribute that it is difficult to view of the connection portion of the switching lever, rearrange the connection portion of the switching lever in a visible region”, the designer can create the following improvement plan.
“extend the tip end 524a of the switching lever 524 and rearrange the connection portion in a visible region”
The assembling operations are as follows.
1) Place the case lower portion 514 on the working table.
2) Move the switching lever 524 downward. Here, since the surface of the case 514 is a designed surface, a care should be taken in the assembling operation.
3) Deform the click arm portion 524a of the switching lever 524 to the inward direction.
4) Rotate the switching lever 524 and insert the click arm portion 524a into the case 514. Here, since the case has a designed surface, a care should be taken not to scratch it. It should be noted that since the connection portion between the click arm portion 524a and the interior of the case 514 is rearranged in the visible region, no special care need be taken.
Step S212 of
Thus, the designer can examine the concrete improvement plans in the descending order of the improvement effect and can effectively design improvements.
Next, explanation will be given on the design support system according to the third embodiment of the present invention.
Next, explanation will be given on an improvement plan for reducing the overall assembling cost in the design support system 1 according to the third embodiment of the present invention.
1-1 Inputting Assembling Operation Analysis Data
In step S301 of
In step S302 of
1-2 Calculating the Overall Assembling Cost Affecting Degree Index
In step S303 of
(1) The assembly difficulty coefficients of the respective elements in the inputted assembling operation analysis data are extracted from the coefficients of the respective assembling elements stored in the assembling difficulty coefficient database 41 so as to calculate the assembling time affecting degree indexes of the part, assembling operation, and attribute.
(2) By using the calculated assembling time affecting degree index and the assembling cost per unit time, the assembling cost affecting degree is calculated for each of the assembling elements.
(3) The defective assembly coefficients of the respective elements in the inputted assembling operation analysis data are extracted from the coefficients of the respective assembling elements stored in the defective assembly coefficient database 42 so as to calculate the defective assembly affecting degree indexes of the part, assembling operation, and attribute.
(4) The assembling loss cost affecting degree is calculated for each of the assembling elements by using the calculated defective assembly affecting degree index and a loss caused when the defect has occurred.
(5) The total of the assembling costs of the respective assembling elements and the assembling loss cost is divided by the total of the entire assembling cost and the assembling loss cost and multiplied by 100 to calculate the overall assembling cost affecting degree index.
In this example, the overall assembling cost affecting degree index of each assembling element is displayed by assuming 100 for the entire assembling time. It should be noted that instead of the overall assembling cost affecting degree index, it is possible to use the overall assembling cost itself.
Moreover, as shown in step S304 of
1-3 Extracting Assembling Elements Requiring Improvements
In step S306 of
In this example, the following three elements having high overall assembling cost affecting degree indexes are extracted.
(1) “switching lever”
(2) “deforming” operation of the switching lever
(3) “rotational” operation of the switching lever
1-4 Extracting Generalized Improvement Plan and Building Concrete Improvement Guideline
In step S307 of
1-5 Creating Overall Assembling Cost Reduction/Improvement Plan and Analyzing Assembling Operations
As shown in
(1) By referencing the improvement guideline 1-1 “in order to reduce the overall assembling cost of the switching lever, divide the part to be assembled and change the assembling order, 1) assemble the part whose assembling is difficult, lastly”, the designer can create the improvement configuration plan as follows.
“Divide the case 51 into an upper and a lower portion and change the assembling order into the case lower portion 511, the switching lever 521 and the case upper portion 511a.” The assembling operations are as follows:
1) Place the case lower portion 511 on the working table.
2) Mount the switching lever 521 on the case lower portion 511. Here, since the surface of the case lower portion 511 is a designed surface, a care should be taken in the assembling operation.
3) Assemble the case upper portion 511a to the case lower portion 511.
(2) By referencing the improvement guideline 1-2 “in order to reduce the overall assembling cost of the switching lever, unify it with another part, 1) outsert molding, 2) use of elasticity of member”, the designer can create the following improvement configuration plan.
“Mold the switching button 522 replacing the switching lever 522 together with the case 512 as a unitary block”
By the elasticity of the case 512, the pressed switching button 522 is automatically restored. In this case, at the stage when the case 512 is molded, the member performing the switching lever function is molded and no assembling operation is required.
(3) By referencing the improvement guideline 3-1 “in order to reduce the overall assembling cost of the switching lever, assemble the switching lever by rectilinear movement, 1) widen the engagement portion tip end, 2) narrow the engagement portion tip end”, the designer can create the following improvement configuration plan.
“Narrow the tip end 523a of the switching lever 523 and assemble it by rectilinear movement”
The assembling operation is as follows.
1) Place the case lower portion 513 on the working table.
2) Move the switching lever 523 downward and mount its tip end 523a on the case lower portion 513. Here, since the surface of the case 513 is a designed surface, a care should be taken in the assembling operation.
3) Clinch the switching lever 523 into the case 513. Here, a care should be taken so that the three tip ends 523a of the switching lever are simultaneously engaged with the case.
In step S312 of
1-6 Calculating Overall Assembling Cost
In step S313 of
Thus, the designer can examine concrete configurations in the descending order of the improvement effects of the improvement plans and can effectively perform improvement design.
It should be further understood by those skilled in the art that although the foregoing description has been made on embodiments of the invention, the invention is not limited thereto and various changes and modifications may be made without departing from the spirit of the invention and the scope of the appended claims.
Number | Date | Country | Kind |
---|---|---|---|
2006-066906 | Mar 2006 | JP | national |