CN115130013B - Multi-enterprise value chain super-chain fusion coordination method - Google Patents
Multi-enterprise value chain super-chain fusion coordination method Download PDFInfo
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Abstract
The invention relates to the technical field of data collaborative management, in particular to a multi-enterprise value chain super-chain fusion collaborative method, which comprises a super-chain fusion business collaborative system T, wherein the super-chain fusion business collaborative system T comprises a core manufacturing enterprise, a third party cloud service platform and a collaborative enterprise group, the third party cloud service platform comprises a data exchange module, a component library module and a collaborative system module, and business data from the core manufacturing enterprise and the collaborative enterprise are interacted through a data adaptation interface of the data exchange module; storing the business data in a data exchange module, and classifying and integrating the data to form a theme database; carrying out mapping rule processing on a theme database to form a platform component and a service component, wherein the platform component and the service component form a component library module, and different component library modules form the cooperative system module based on super-chain fusion; and the cooperative system module based on the super-link fusion serves the core enterprise through the cooperative service interface to assist the service activity.
Description
Technical Field
The invention relates to the technical field of data collaborative management, in particular to a multi-enterprise value chain super-chain fusion collaborative method.
Background
In the big data age, enterprises pay more and more attention to data storage, cost can be saved for enterprises through analysis of a large amount of data, but at present, in the production process of traditional manufacturing industry, enterprise business data are limited to basic functions such as daily inquiry and the like in the enterprises, the information synchronization degree among the enterprises is low, a large amount of data resources generated in the production process cannot be fully utilized, serious information barriers exist among the enterprises, and the business cooperation efficiency among the enterprises is low, so that a super-link fusion business cooperation mechanism is formed, and based on the super-link fusion business cooperation mechanism, the information flow channels among the upstream and downstream cooperation enterprises are further opened, so that the production efficiency and the cooperation level among the enterprises in the production link are improved, the enterprise cost is reduced, the product quality is improved, and the problems and pain points which are urgent to be solved by the enterprises at present are really solved.
Disclosure of Invention
The invention aims at: aiming at the problem that the information synchronization degree among enterprises is lower in the conventional manufacturing process at present, the multi-enterprise value chain super-chain fusion cooperative method is provided, super-chain information fusion is formed, beneficial information for the enterprises is mined, the product quality of the enterprises is improved, and the cost of the enterprises is reduced.
In order to achieve the above object, the present invention provides the following technical solutions:
a multi-enterprise value chain super-chain fusion coordination method comprises the following steps:
s1, a data interaction layer in a third-party cloud platform receives business activity data from a core enterprise and a collaborative enterprise, wherein the core enterprise is connected with a collaborative enterprise group at the upstream and the downstream to construct a value chain;
s2, storing the business activity data in the step S1 in a database, classifying according to the types of the business activity data, wherein the business activity data comprises production data, marketing data, quality data, accessory data and service data, and forming a theme database of each classification;
s3, forming a component layer based on at least one different topic database, wherein a functional component for searching activity data in the topic database forming the component layer is arranged in the component layer, the component layer is used for forming a service system based on super-chain fusion, the service system comprises a plurality of value chains, super-chain fusion coordination of the plurality of value chains is realized under the support of a third party cloud platform, and the super-chain fusion coordination is a business coordination relationship existing between an upstream enterprise of a core enterprise and a downstream enterprise of the core enterprise on the value chains;
s4, the super-link fusion coordination among all the value chains of the system layer forms a super-link fusion service coordination system T, the super-link fusion service coordination system T is a finite set, T= { E, P, A }, E represents an enterprise set, P represents a third party platform, A represents service activities, service coordination of the coordination enterprise to the core enterprise is completed through the super-link fusion service coordination system T, and service is carried out to the core enterprise and the coordination enterprise through the data interaction layer.
Further, the value chains and the synergistic relations form a multi-core value network, and the synergistic relations are R= { R L ,R MC ,R AC ,R HC -said R L For the coordination of upstream and downstreamIn the same relationship, R is MC Is in a multi-chain linkage cooperative relationship, R is as follows AC For cross-chain interactive synergistic relationship, the R HC Is a super-chain fusion cooperative relationship;
further, the linear upstream-downstream cooperative relationship is a linear upstream-downstream cooperative relationship between an enterprise on one value chain and another enterprise adjacent to the enterprise on the same chain; the multi-chain linkage cooperative relationship is a cooperative relationship existing among a plurality of enterprises from at least 3 chain value chains; the inter-chain interaction cooperation relationship is that when an enterprise on one value chain and an enterprise on the other chain have the inter-chain cooperation relationship, core factories on the two value chains are not the same enterprise; the super-chain fusion cooperative relationship is a business cooperative relationship existing between an upstream enterprise of a core manufacturer and a downstream enterprise of the core manufacturer on the same value chain.
The value chain in the super-chain fusion service cooperative system T is C= { C n N is a positive integer, where n represents the number of value chains, each value chain is made up of multiple enterprises, whenThere is->
The C is j The expression is:
represented as core manufacturing enterprise E c-m At least one, co-operating enterprise E co At least one enterprise belongs to at least one value chain in the whole super-chain fusion collaboration system T.
Further, the enterprise set E is set e= { E a I a is a positive integer }, where a is the number of enterprises, the enterprise set includes core enterprise E c Business activity initiating enterprise E s And collaborative enterprise E co The method comprises the steps of carrying out a first treatment on the surface of the For a pair ofi.e {1,2,3,, n }, there is E i ∈E c ∪E s ∪E co Wherein->Represented as a core enterprise in a multi-core value network collaborative network, which can be used as a business activity initiating enterprise, the core enterprise E c Including core manufacturing enterprise E c-m And other core enterprises E c-o The core manufacturing enterprise E c-m Comprises Z= { Z of the whole vehicle manufacturing plant n I n is a positive integer }, parts manufacturing plant l= { L n I n is a positive integer }, the other core enterprises E c-o Including parts suppliers G= { G n I n is a positive integer }, dealer j= { J n I n is a positive integer }, fitting agent p= { P n I n is a positive integer }, the service provider f= { F n And n is a positive integer }, the collaborative enterprise E co Including enterprise types and the other core enterprises E c-o The type of enterprise involved is the same.
Further, for any one of the value chains C i Business on the upperWith another enterprise on the same value chainThe expression of the linear upstream-downstream cooperative relationship is +.>In the upstream-downstream cooperative relationship, the ∈>For upstream enterprises, said->For downstream enterprises, then->And->In the value chain C i The above relation is:
the value chain C i Upstream enterprises withinAnd downstream enterprises->There is a linear up-down cooperative relation R between n L A communication path constructed by connecting n adjacent enterprise nodes in turn, the +.>Is->Is connected downstream of the n-level of the enterprise, said +.>Is->The expression of the n-level upstream enterprise is: />
For a certain value chain C i Two enterprises E in p And E is q There are positive integers n.epsilon.2, +.]So that Sub n (E p )=E q Or Pre n (E q )=E p And there is a positive integer mε (0, n) such that Sub m (E p )∈E C Or Pre m (E q )∈E C Then E p And E is q The upper and lower super-link cooperative relationship is that
Further, the hyper-link fusion service active set a= { a b B is a positive integer, b is the number of activities, and a collaborative activity set a= (D, E, C, R), wherein D is a hyper-link fusion business activity type set, E is a hyper-link fusion business activity enterprise set, C is a hyper-link fusion business activity value chain set, and R is a hyper-link fusion collaborative relationship;
the D is a super-chain fusion service activity type set, and comprises quality tracing, old part management and control and accessory distribution of super-chain fusion cooperative service activities; when (when)Presence of E i ∈E s 、/>The method comprises the following steps:
C i the number of value chain sets related to the current activity is equal to 1; d (D) i The number of the service types in the current service activity is 1; e (E) i The number of enterprises is 1, which are implementation subject enterprises of activities; e (E) j Is movableThe number of the collaborative enterprise sets is more than or equal to 2; r is R i Is a cooperative relationship in the activity, fixed as a super-chain fused cooperative relationship R HC 。
Further, the multi-enterprise value chain super-chain fusion collaboration method is defined as H= (C, A) by the collaboration enterprise set, the value chain set, the collaboration relationship and the business activity set
Further develop h= (C, a) to:
the m is a positive integer, is the number of business active sets existing on the industrial value chain, and the multi-enterprise value chain super-chain fusion collaboration method H consists of two parts: conventional value chain and value chain C comprising linear upstream-downstream cooperative relationship in chain type value chain k The upper hyper-link traffic co-acts.
Further, the business data comprises whole vehicle sales data, quality analysis data, old part processing data, accessory transaction data, inventory management data and maintenance service data, the data subject library comprises a purchasing subject library, a selling subject library, a service subject library and an accessory subject library, the platform component comprises a data processing component, a permission management component and a message processing component, and the business component comprises a multi-core value network business cooperative supporting component and a multi-core value network business analysis reasoning component.
The multi-enterprise value chain super-chain fusion collaboration system comprises a super-chain fusion business collaboration system T, wherein the super-chain fusion business collaboration system T comprises a core manufacturing enterprise, a third party cloud service platform and a collaboration enterprise group, the third party cloud service platform comprises a data exchange module, a component library module and a collaboration system module, the third party cloud service platform comprises a multi-core value network supporting multi-value chain collaboration, and the multi-value chain collaboration is the mutual connection collaboration between a plurality of upstream and downstream collaboration value chains formed by a plurality of core manufacturing enterprises and the collaboration enterprise group; the collaboration enterprise group comprises a provider group, a dealer group, an agent group and a service business group, and the super-link fusion business collaboration system T is based on an inter-enterprise data cross-link interaction method, the collaboration enterprise set serves the core enterprise through the business interaction layer of the third-party cloud service platform, and data super-link interaction among enterprises is completed.
Compared with the prior art, the invention has the beneficial effects that:
in the scheme of the application, the proposed ultra-chain business collaboration theory based on the multi-core value network is oriented to the actual demand of information collaboration among enterprises in a manufacturing industry chain, and the purposes of improving the collaboration efficiency among enterprises, reducing the production cost of the enterprises and improving the product quality are achieved by deeply fusing, excavating and analyzing business interaction information among the enterprises on the industry chain.
Description of the drawings:
FIG. 1 is a schematic diagram of a cooperative structure of a super-link fusion service;
figure 2 is a schematic diagram of a synergistic approach to hyper-link fusion,
Detailed Description
In order to make the objects, technical solutions and advantages of the embodiments of the present invention more clear, the technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings. It will be apparent that the described embodiments are some, but not all, embodiments of the invention.
Thus, the following detailed description of the embodiments of the invention is not intended to limit the scope of the invention, as claimed, but is merely representative of some embodiments of the invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.
It should be noted that, under the condition of no conflict, the embodiments of the present invention and the features and technical solutions in the embodiments may be combined with each other.
It should be noted that: like reference numerals and letters denote like items in the following figures, and thus once an item is defined in one figure, no further definition or explanation thereof is necessary in the following figures.
In the description of the present invention, it should be noted that, the terms "upper", "lower", and the like indicate an azimuth or a positional relationship based on the azimuth or the positional relationship shown in the drawings, or an azimuth or a positional relationship conventionally put in use of the inventive product, or an azimuth or a positional relationship conventionally understood by those skilled in the art, such terms are merely for convenience of describing the present invention and simplifying the description, and do not indicate or imply that the apparatus or element to be referred must have a specific azimuth, be constructed and operated in a specific azimuth, and thus should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and the like, are used merely to distinguish between descriptions and should not be construed as indicating or implying relative importance.
Embodiment one: as can be seen in figures 1 and 2,
the multi-enterprise value chain super-chain fusion collaboration method provided by the embodiment comprises the following steps:
s1, a data interaction layer in a third-party cloud platform receives business activity data from a core enterprise and a collaborative enterprise, wherein the core enterprise is connected with a collaborative enterprise group at the upstream and the downstream to construct a value chain;
s2, storing the business activity data in the step S1 in a database, classifying according to the types of the business activity data, wherein the business activity data comprises production data, marketing data, quality data, accessory data and service data, and forming a theme database of each classification;
s3, forming a component layer based on at least one different topic database, wherein a functional component for searching activity data in the topic database forming the component layer is arranged in the component layer, the component layer is used for forming a service system based on super-chain fusion, the service system comprises a plurality of value chains, super-chain fusion coordination of the plurality of value chains is realized under the support of a third party cloud platform, and the super-chain fusion coordination is a business coordination relationship existing between an upstream enterprise of a core enterprise and a downstream enterprise of the core enterprise on the value chains;
s4, the super-link fusion coordination among all the value chains of the system layer forms a super-link fusion service coordination system T, the super-link fusion service coordination system T is a finite set, T= { E, P, A }, E represents an enterprise set, P represents a third party platform, A represents service activities, service coordination of the coordination enterprise to the core enterprise is completed through the super-link fusion service coordination system T, and service is carried out to the core enterprise and the coordination enterprise through the data interaction layer.
Further, the value chains and the synergistic relations form a multi-core value network, and the synergistic relations are R= { R L ,R MC ,R AC ,R HC -said R L The R is in a cooperative relationship of upstream and downstream MC Is in a multi-chain linkage cooperative relationship, R is as follows AC For cross-chain interactive synergistic relationship, the R HC Is a super-chain fusion cooperative relationship;
further, the linear upstream-downstream cooperative relationship is a linear upstream-downstream cooperative relationship between an enterprise on one value chain and another enterprise adjacent to the enterprise on the same chain; the multi-chain linkage cooperative relationship is a cooperative relationship existing among a plurality of enterprises from at least 3 chain value chains; the inter-chain interaction cooperation relationship is that when an enterprise on one value chain and an enterprise on the other chain have the inter-chain cooperation relationship, core factories on the two value chains are not the same enterprise; the super-chain fusion cooperative relationship is a business cooperative relationship existing between an upstream enterprise of a core manufacturer and a downstream enterprise of the core manufacturer on the same value chain.
The value chain in the super-chain fusion service cooperative system T is C= { C n N is a positive integer, where n represents the number of value chains, each value chain is made up of multiple enterprises, whenThere is->
The C is j The expression is:
represented as core manufacturing enterprise E c-m At least one, co-operating enterprise E co At least one enterprise belongs to at least one value chain in the whole super-chain fusion collaboration system T.
Further, the enterprise set E is set e= { E a I a is a positive integer }, where a is the number of enterprises, the enterprise set includes core enterprise E c Business activity initiating enterprise E s And collaborative enterprise E co The method comprises the steps of carrying out a first treatment on the surface of the For a pair ofi.e {1,2,3,, n }, there is E i ∈E c ∪E s ∪E co Wherein->Represented as a core enterprise in a multi-core value network collaborative network, which can be used as a business activity initiating enterprise, the core enterprise E c Including core manufacturing enterprise E c-m And other core enterprises E c-o The core manufacturing enterprise E c-m Comprises Z= { Z of the whole vehicle manufacturing plant n I n is a positive integer }, parts manufacturing plant l= { L n I n is a positive integer }, the other core enterprises E c-o Including parts suppliers G= { G n I n is a positive integer }, dealer j= { J n I n is a positive integer }, fitting agent p= { P n I n is a positive integer }, the service provider f= { F n And n is a positive integer }, the collaborative enterprise E co Including enterprise types and the other core enterprises E c-o The type of enterprise involved is the same.
Further, for any one of the value chains C i Business on the upperWith another enterprise on the same value chainThe expression of the linear upstream-downstream cooperative relationship is +.>In the upstream-downstream cooperative relationship, the ∈>For upstream enterprises, said->For downstream enterprises, then->And->In the value chain C i The above relation is:
the value chain C i Upstream enterprises withinAnd downstream enterprises->There is a linear up-down cooperative relation R between n L A communication path constructed by connecting n adjacent enterprise nodes in turn, the +.>Is->Is connected downstream of the n-level of the enterprise, said +.>Is->The expression of the n-level upstream enterprise is:
for a certain value chain C i Two enterprises E in p And E is q There are positive integers n.epsilon.2, +.]So that Sub n (E p )=E q Or Pre n (E q )=E p And there is a positive integer mε (0, n) such that Sub m (E p )∈E C Or Pre m (E q )∈E C Then E p And E is q The upper and lower super-link cooperative relationship is that
Further, the hyper-link fusion service active set a= { a b B is a positive integer, b is the number of activities, and a collaborative activity set a= (D, E, C, R), wherein D is a hyper-link fusion business activity type set, E is a hyper-link fusion business activity enterprise set, C is a hyper-link fusion business activity value chain set, and R is a hyper-link fusion collaborative relationship;
the D is a super-chain fusion service activity type set, and comprises quality tracing, old part management and control and accessory distribution of super-chain fusion cooperative service activities; when (when)Presence of E i ∈E s 、/>The method comprises the following steps:
C i the number of value chain sets related to the current activity is equal to 1; d (D) i The number of the service types in the current service activity is 1; e (E) i The number of enterprises is 1, which are implementation subject enterprises of activities; e (E) j The number of the collaborative enterprises is greater than or equal to 2; r is R i Is a cooperative relationship in the activity, fixed as a super-chain fused cooperative relationship R HC 。
Further, the multi-enterprise value chain super-chain fusion collaboration method is defined as H= (C, A) by the collaboration enterprise set, the value chain set, the collaboration relationship and the business activity set
Further develop h= (C, a) to:
the m is a positive integer, is the number of business active sets existing on the industrial value chain, and the multi-enterprise value chain super-chain fusion collaboration method H consists of two parts: conventional value chain and value chain C comprising linear upstream-downstream cooperative relationship in chain type value chain k The upper hyper-link traffic co-acts.
Further, the business data comprises whole vehicle sales data, quality analysis data, old part processing data, accessory transaction data, inventory management data and maintenance service data, the data subject library comprises a purchasing subject library, a selling subject library, a service subject library and an accessory subject library, the platform component comprises a data processing component, a permission management component and a message processing component, and the business component comprises a multi-core value network business cooperative supporting component and a multi-core value network business analysis reasoning component.
The multi-enterprise value chain super-chain fusion collaboration system comprises a super-chain fusion business collaboration system T, wherein the super-chain fusion business collaboration system T comprises a core manufacturing enterprise, a third party cloud service platform and a collaboration enterprise group, the third party cloud service platform comprises a data exchange module, a component library module and a collaboration system module, the third party cloud service platform comprises a multi-core value network supporting multi-value chain collaboration, and the multi-value chain collaboration is the mutual connection collaboration between a plurality of upstream and downstream collaboration value chains formed by a plurality of core manufacturing enterprises and the collaboration enterprise group; the collaboration enterprise group comprises a provider group, a dealer group, an agent group and a service business group, and the super-link fusion business collaboration system T is based on an inter-enterprise data cross-link interaction method, the collaboration enterprise set serves the core enterprise through the business interaction layer of the third-party cloud service platform, and data super-link interaction among enterprises is completed.
Taking the cooperative business of the automobile manufacturing industry as an example, as shown in fig. 2, the super-chain fusion cooperative mode is that the supplier 1 and the part manufacturing plant 1 are respectively upstream enterprises on two different industrial value chains with the whole manufacturing plant 1 and the whole manufacturing plant 2 as core enterprises, the service provider 1 and the accessory agent 2 and the service provider 6 and the accessory agent 3 are respectively downstream enterprises on two industrial value chains, and the cooperative advantage of a third-party cloud service platform based on a multi-core value network is utilized between the upstream enterprises and the downstream enterprises in the figure, so that the super-chain fusion business cooperation between the upstream enterprises and the downstream enterprises is realized. Under the cooperative network system, various information such as old piece management and control, quality tracing and the like of the hyper-link are generated, and agents, service providers and the like are used as nodes for the information to communicate with each node enterprise to form the hyper-link fusion service cooperative system based on information service.
Further, the business data comprises whole vehicle sales data, quality analysis data, old part processing data, accessory transaction data, inventory management data and maintenance service data, the data subject library comprises a purchasing subject library, a selling subject library, a service subject library and an accessory subject library, the platform component comprises a data processing component, a permission management component and a message processing component, and the business component comprises a multi-core value network business cooperative supporting component and a multi-core value network business analysis reasoning component.
A third-party platform-based ultra-chain fusion service collaboration system is shown in fig. 1, old piece management and control collaboration service is taken as an example, a bottom data layer in the collaboration system firstly carries out data adaptation and integration on production data of an in-chain upstream supplier, a core whole vehicle manufacturer, a downstream accessory agent and a server to form a theme base corresponding to data theme and a bottom platform base component in the system, meanwhile, old piece management and control actual collaboration requirements of the downstream supplier and the upstream supplier are based on the old piece management and control actual collaboration system component, an upper-layer old piece management and control actual service collaboration system component is formed, an upstream enterprise and a downstream enterprise in an industrial value chain are based on the collaboration system component, and a multi-core value network-based third-party cloud service platform-based ultra-chain fusion information circulation channel is relied on to realize efficient collaboration of old piece management and control service between the downstream server and the upstream supplier.
The multi-enterprise value chain ultra-chain fusion collaboration method is shown in fig. 2, taking quality tracing as an example, the subsystem utilizes an ultra-chain collaboration mechanism constructed in a third-party cloud platform, and guides the whole process tracing of accessory quality information around the actual demands of upstream and downstream related enterprises in a manufacturing industry chain on quality tracing services, and achieves end-to-end quality tracing ultra-chain information collaboration between upstream suppliers and downstream service providers in the industry value chain across multi-enterprise nodes by integrating the whole chain of data generated in the process of service interaction between the upstream suppliers, the middle-stream core manufacturer and downstream agents and the service providers in different enterprises in the industry value chain.
In the environment supporting the multi-value chain cooperative third party cloud platform, a plurality of upstream and downstream cooperative enterprise groups taking manufacturing enterprises as cores are formed around automobile service, all enterprises are closely cooperated by taking customer service demands as driving forces, a whole function and value chain is formed, and value activities are closely related through information flows, entity flows and value flows. In terms of old part management and control, an end-to-end data interaction channel is established between an upstream provider and a downstream provider in an industrial value chain based on a hyper-link information collaboration mechanism, dynamic acquisition of different old part maintenance service information in the industrial chain is achieved, meanwhile, full life cycle basic information of parts is obtained by utilizing data sharing advantages of a third-party cloud service platform, and finally, end-to-end intelligent decision of management and control attributes such as flow direction, conveying mode and the like of different parts in the industrial chain is achieved through comprehensive analysis of the obtained multi-dimensional information of the parts. In terms of quality tracing, after the business of the production link corresponding to the self node is completed by each enterprise at the upstream and downstream in the manufacturing industry value chain, the multi-process information such as the production, distribution, service maintenance and the like of different parts in the production link is stored to the cloud service platform data space in a lasting manner by depending on the cooperative advantages of the third-party cloud service platform, meanwhile, the multi-process data of the part value chain is subjected to deep fusion analysis, and the end-to-end data channel between the upstream enterprise and the downstream enterprise is established based on the super-chain information cooperative mechanism, so that the efficient whole-process tracing of the quality information of the parts between the upstream provider and the downstream server in the manufacturing industry value chain is realized.
The above embodiments are only for illustrating the present invention and not for limiting the technical solutions described in the present invention, and although the present invention has been described in detail in the present specification with reference to the above embodiments, the present invention is not limited to the above specific embodiments, and thus any modifications or equivalent substitutions are made to the present invention; all technical solutions and modifications thereof that do not depart from the spirit and scope of the invention are intended to be included in the scope of the appended claims.
Claims (3)
1. A multi-enterprise value chain super-chain fusion coordination method is characterized in that: the method comprises the following steps:
s1, a data interaction layer in a third-party cloud platform receives business activity data from a core enterprise and a collaborative enterprise, wherein the core enterprise is connected with a collaborative enterprise group at the upstream and the downstream to construct a value chain;
s2, storing the business activity data in the step S1 in a database, classifying according to the types of the business activity data, wherein the business activity data comprises production data, marketing data, quality data, accessory data and service data, and forming a theme database of each classification;
s3, forming a component layer based on at least one different topic database, wherein a functional component for searching activity data in the topic database forming the component layer is arranged in the component layer, the component layer is used for forming a service system based on super-chain fusion, the service system comprises a plurality of value chains, super-chain fusion coordination of the plurality of value chains is realized under the support of a third party cloud platform, and the super-chain fusion coordination is a business coordination relationship existing between an upstream enterprise of a core enterprise and a downstream enterprise of the core enterprise on the value chains;
s4, performing super-link fusion coordination among all value chains of a system layer to form a super-link fusion service coordination system T, wherein the super-link fusion service coordination system T is a finite set, T= { E, P, A }, E represents an enterprise set, P represents a third party platform, A represents service activity, service coordination of the coordination enterprise to the core enterprise is completed through the super-link fusion service coordination system T, and service is performed to the core enterprise and the coordination enterprise through the data interaction layer;
the value chains form a plurality of synergistic relations, wherein the synergistic relations comprise R= { R L ,R MC ,R AC ,R HC -said R L The R is in a cooperative relationship of upstream and downstream MC Is in a multi-chain linkage cooperative relationship, R is as follows AC For cross-chain interactive synergistic relationship, the R HC Is a super-chain fusion cooperative relationship;
the value chain in the super-chain fusion service cooperative system T is C= { C n N is a positive integer, where n represents the number of value chains, each value chain is made up of multiple enterprises, whenThere is->
The C is j The expression is:
represented as core manufacturing enterprise E c-m At least one, co-operating enterprise E co At least one enterprise belongs to at least one value chain in the whole super-chain fusion collaboration system T;
the enterprise set E is set e= { E a I a is a positive integer }, where a is the number of enterprises, the enterprise set includes core enterprise E c Business activity initiating enterprise E s And collaborative enterprise E co The method comprises the steps of carrying out a first treatment on the surface of the For a pair of With E i ∈E c ∪E s ∪E co Wherein->The core enterprise E c Including core manufacturing enterprise E c-m And other core enterprises E c-o The core manufacturing enterprise E c-m Comprises Z= { Z of the whole vehicle manufacturing plant n I n is a positive integer }, parts manufacturing plant l= { L n I n is a positive integer }, the other core enterprises E c-o Including parts suppliers G= { G n I n is a positive integer }, dealer j= { J n I n is a positive integer }, fitting agent p= { P n I n is a positive integer }, the service provider f= { F n And n is a positive integer }, the collaborative enterprise E co Including enterprise types and the other core enterprises E c-o The included enterprise types are the same;
for any one of the value chains C i Business on the upperAnother on the same value chainAn enterprise->The expression of the linear upstream-downstream cooperative relationship is +.>In the upstream-downstream cooperative relationship, the ∈>For upstream enterprises, said->For downstream enterprises, then->And->In the value chain C i The above relation is:
the value chain C i Upstream enterprises withinAnd downstream enterprises->There is a linear up-down cooperative relation R between n L A communication path constructed by connecting n adjacent enterprise nodes in turn, the E jn-1 Is->N-level inter-connection of (2)Downstream enterprises, said->Is->The expression of the n-level upstream enterprise is:
for a certain value chain C i Two enterprises E in p And E is q There are positive integers n.epsilon.2, +.]So that Sub n (E p )=E q Or Pre n (E q )=E p And there is a positive integer mε (0, n) such that Eub m (E q )∈E c Or Pre m (E q )∈E c Then E p And E is q The upper and lower super-link cooperative relationship is that
The hyper-link fusion service active set A= { A b B is a positive integer, b is the number of activities, and a collaborative activity set a= (D, E, C, R), wherein D is a hyper-link fusion business activity type set, E is an enterprise set, C is a hyper-link fusion business activity value chain set, and R is a hyper-link fusion collaborative relationship;
the D is a super-chain fusion service activity type set, and comprises quality tracing, old part management and control and accessory distribution of super-chain fusion cooperative service activities; when (when)Presence of E i ∈E s 、/>The expression is:
C i the number of value chain sets related to the current activity is equal to 1; d (D) i The number of the service types in the current service activity is 1; e (E) i The number of enterprises is 1, which are implementation subject enterprises of activities; e (E) j The number of the collaborative enterprises is greater than or equal to 2; r is R i Is a cooperative relationship in the activity, fixed as a super-chain fused cooperative relationship R HC ;
Defining the multi-enterprise value chain super-chain fusion collaboration method as H= (C, A) through the collaboration enterprise set, the value chain set, the collaboration relationship and the business activity set
Further develop h= (C, a) to:
the m is a positive integer, is the number of business active sets existing on the industrial value chain, and the multi-enterprise value chain super-chain fusion collaboration method H consists of two parts: conventional value chain and value chain C comprising linear upstream-downstream cooperative relationship in chain type value chain k The upper hyper-link traffic co-acts.
2. The multi-enterprise value chain super-chain fusion collaboration method of claim 1, wherein the method comprises the following steps: the business data comprises whole car sales data, quality analysis data, old piece processing data, accessory transaction data, inventory management data and maintenance service data, the data subject library comprises a purchasing subject library, a selling subject library, a service subject library and an accessory subject library, the platform component comprises a data processing component, a permission management component and a message processing component, and the business component comprises a multi-core value network business cooperation supporting component and a multi-core value network business analysis reasoning component.
3. A multi-enterprise value chain super-chain fusion cooperative system is characterized in that: the system comprises a hyperchain fusion service collaboration system T, wherein the hyperchain fusion service collaboration system T comprises a core manufacturing enterprise, a third-party cloud service platform and a collaboration enterprise group, the third-party cloud service platform comprises a data exchange module, a component library module and a collaboration system module, the third-party cloud service platform comprises a multi-core value network supporting multi-value chain collaboration, and the multi-value chain collaboration is the mutual connection collaboration between a plurality of core manufacturing enterprises and a plurality of upstream and downstream collaboration value chains formed by the collaboration enterprise group; the collaboration enterprise group comprises a provider group, a dealer group, an agent group and a service business group, and the super-chain fusion business collaboration system T is based on the multi-enterprise value chain super-chain fusion collaboration method according to any one of claims 1-2, and the collaboration enterprise set serves the core enterprise through the business interaction layer of the third-party cloud service platform to complete data super-chain interaction among enterprises.
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