CN115270722A - Naming method, device, equipment and storage medium for middle assembly parts - Google Patents

Abstract

The invention discloses a naming method, a device, equipment and a storage medium of middle assembly parts, wherein a first code of each middle assembly is generated by acquiring a middle assembly number of each middle assembly; all small assemblies in each middle assembly are obtained, and all small assemblies are subjected to assembly structure classification; obtaining a second code of each small component based on the constructed component structure category data set; acquiring the component position of each small component, and acquiring a third code of each small component based on the constructed component position data set; acquiring all parts in each small assembly, and acquiring a fourth code of each part based on the constructed part type data set; and sequencing the first code, the second code, the third code and the fourth code according to a preset part name naming rule to obtain the name of the assembled part. Compared with the prior art, the naming mode of the invention can express the relevant information such as the installation position of the part, the type of the part and the like, and improves the management efficiency of the centering and assembling parts.

Description

Naming method, device, equipment and storage medium for middle assembly parts

Technical Field

The invention relates to the technical field of ships, in particular to a naming method, a naming device, naming equipment and a naming storage medium for a middle assembly part.

Background

The middle assembly robot is a robot special for welding assembly welding seams in ship sections, can realize automatic welding of the robot according to a data file of the middle assembly welding seams provided by design, and because a plurality of small assemblies are arranged in one section, the small assemblies and the small assemblies are combined into one middle assembly, if the small assemblies are named independently, rules are not uniform, which small assemblies are arranged below the middle assembly and cannot be judged finally, manual secondary judgment is needed for checking, the efficiency is low, and omission is easy.

In addition, in order to realize efficient use of the robot, the small assemblies on the middle assembly are better in slow assembly, and the condition that automatic welding cannot be realized due to the fact that part of the small assemblies block the welding robot is avoided.

Disclosure of Invention

The technical problem to be solved by the invention is as follows: a method, an apparatus, a device and a storage medium for naming an intermediate component are provided, which can improve the management efficiency of the intermediate component.

In order to solve the above technical problem, the present invention provides a naming method for a medium-sized component, comprising:

acquiring a middle component number corresponding to each middle component, and generating a first code corresponding to each middle component according to the middle component number;

constructing a component structure category data set with component structure category attributes, wherein each component structure category attribute comprises a corresponding second code, acquiring all small components in each middle component, performing assembly structure classification on all small components to obtain an assembly structure category corresponding to each small assembly, and acquiring a second code corresponding to each small component based on the component structure category data set;

constructing a component position data set with component position attributes, wherein each component position attribute comprises a corresponding third code, acquiring the component position of each small component, and obtaining the third code corresponding to each small assembly based on the component position data set;

constructing a part type data set with part type attributes, wherein each part type attribute comprises a corresponding fourth code, acquiring all parts in each small assembly, and acquiring the fourth code corresponding to each part based on the part type data set;

and sequencing the first code, the second code, the third code and the fourth code according to a preset part name naming rule to obtain the name of the assembled part.

In a possible implementation manner, before performing assembly structure classification on all the small assemblies to obtain an assembly structure category corresponding to each small assembly, the method further includes:

acquiring all first set of vertical structure types of the small assemblies, wherein the first set of vertical structure types comprise main members, watertight bulkheads and rib plates, common longitudinal and transverse plates, T rows and other types;

reclassifying each first clustering structure category to obtain a second clustering structure category corresponding to each first clustering structure category;

the second assemblage structure category corresponding to the main component comprises a deck, a platform, an inner bottom plate, an outer bottom plate, a side outer plate, a stern sealing plate, a top side cabin inclined plate and a bottom side cabin inclined plate;

the second assembly structure type corresponding to the watertight bulkhead and the ribbed plates comprises a watertight longitudinal bulkhead, a watertight transverse bulkhead, ribbed plates and a groove wall;

the second assembling structure category corresponding to the common longitudinal and transverse plates comprises nonwatertight longitudinal bulkheads, longitudinal partition plates, transverse walls, transverse frames, rib plates and inclined rib positions;

the second assemblage structure category corresponding to the T row category comprises a longitudinal girder, a strong cross beam, a horizontal girder, a vertical girder and a combined T-shaped section;

the second assemblage structure types corresponding to other types comprise bulwarks, toggle plates, various air channels, box bodies, bilge keels, hatch coamings, cylinder bodies and the like.

In a possible implementation manner, the grouping structure classification is performed on all the minor assemblies to obtain a grouping structure category corresponding to each minor assembly, and the method specifically includes:

performing first assembly structure classification on all the small assemblies to obtain a first assembly structure class corresponding to each small assembly;

and performing second assemblage structure classification on all the small assemblies according to the first assemblage structure category corresponding to each small assemblage to obtain a second assemblage structure category corresponding to each small assemblage, and taking the second assemblage structure category corresponding to each small assemblage as the assemblage structure category corresponding to each small assemblage.

In one possible implementation, all parts in each small component are obtained, wherein all the parts comprise small plates, boxes, box body single plates, toggle plates with grooves, patch plates, backing plates, large plates for mounting the plate on the plate mounting station, groove-shaped wall plate assemblies, longitudinal ribs, curved outer plates, curved plates, pillars, reinforcing ribs, panels and deck fitting-out reinforcements.

The invention also provides a naming device of the middle assembly part, which comprises: the system comprises a first code acquisition module, a second code acquisition module, a third code acquisition module, a fourth code acquisition module and a part naming module;

the first code obtaining module is configured to obtain a middle component number corresponding to each middle component, and generate a first code corresponding to each middle component according to the middle component number;

the second code acquisition module is used for constructing a component structure category data set with component structure category attributes, wherein each component structure category attribute comprises a corresponding second code, acquiring all small components in each middle component, performing assembly structure classification on all the small components to obtain an assembly structure category corresponding to each small assembly, and obtaining the second code corresponding to each small component based on the component structure category data set;

the third code acquisition module is configured to construct a component position data set having component position attributes, where each component position attribute includes a corresponding third code, acquire a component position of each minor component, and obtain a third code corresponding to each minor assembly based on the component position data set;

the fourth code obtaining module is configured to construct a part type data set having part type attributes, where each part type attribute includes a corresponding fourth code, obtain all parts in each small component, and obtain the fourth code corresponding to each part based on the part type data set;

the part naming module is used for sequencing the first code, the second code, the third code and the fourth code according to a preset part name naming rule to obtain the name of the assembled part.

In a possible implementation manner, the second code obtaining module is configured to classify the assembly structures of all the small assemblies, and further includes the following steps before obtaining the assembly structure category corresponding to each small assembly;

acquiring all first assemblage structure types of the small assemblies, wherein the first assemblage structure types comprise main components, watertight bulkheads and ribbed plates, common longitudinal and transverse plates, T rows and other types;

reclassifying each first discrete structure category to obtain a second discrete structure category corresponding to each first discrete structure category;

the second assembling structure category corresponding to the main component comprises a deck, a platform, an inner bottom plate, an outer bottom plate, a side outer plate, a stern sealing plate, a top side cabin inclined plate and a bottom side cabin inclined plate;

the second assembly structure type corresponding to the watertight bulkhead and the ribbed plates comprises a watertight longitudinal bulkhead, a watertight transverse bulkhead, ribbed plates and a groove wall;

the second assembling structure category corresponding to the common longitudinal and transverse plates comprises nonwatertight longitudinal bulkheads, longitudinal partition plates, transverse walls, transverse frames, rib plates and inclined rib positions;

the second assemblage structure category corresponding to the T row category comprises longitudinal girders, strong beams, horizontal girders, vertical girders and combined T-shaped sections;

the second assemblage structure types corresponding to other types comprise bulwarks, toggle plates, various air channels, box bodies, bilge keels, hatch coamings, cylinder bodies and the like.

In a possible implementation manner, the second code obtaining module is configured to perform group structure classification on all the minor assemblies to obtain a group structure category corresponding to each minor assembly, and specifically includes:

performing first assembly structure classification on all the small assemblies to obtain a first assembly structure class corresponding to each small assembly;

and performing second assemblage structure classification on all the small assemblies according to the first assemblage structure category corresponding to each small assemblage to obtain a second assemblage structure category corresponding to each small assemblage, and taking the second assemblage structure category corresponding to each small assemblage as the assemblage structure category corresponding to each small assemblage.

In a possible implementation manner, the fourth code acquisition module is used for acquiring all parts in each small component, wherein all the parts comprise small plates, a box body, box body single plates, toggle plates with grooves, supplementing plates, base plates, large plates, groove-shaped wall jointed plates, longitudinal bones, curved surface outer plates, curved surface plates, pillars, reinforcing ribs, panels and deck fitting-out reinforcing materials which are not arranged on a jointed plate station.

The invention also provides a terminal device, which comprises a processor, a memory and a computer program stored in the memory and configured to be executed by the processor, wherein the processor implements the naming method of the intermediate components as described in any one of the above items when executing the computer program.

The invention also provides a computer-readable storage medium, which includes a stored computer program, wherein when the computer program runs, the apparatus in which the computer-readable storage medium is located is controlled to execute the naming method of the intermediate component as described in any one of the above items.

Compared with the prior art, the naming method, the naming device, the naming equipment and the naming storage medium of the middle assembly part have the following beneficial effects that:

generating a first code of each middle component by acquiring the middle component number of each middle component; acquiring all small assemblies in each middle assembly, and performing assembly structure classification on all small assemblies; obtaining a second code of each small component based on the constructed component structure category data set; acquiring the component position of each small component, and acquiring a third code of each small component based on the constructed component position data set; acquiring all parts in each small assembly, and acquiring a fourth code of each part based on the constructed part type data set; and sequencing the first code, the second code, the third code and the fourth code according to a preset part name naming rule to obtain the name of the assembled part. Compared with the prior art, the method has the advantages that a certain rule is set for naming all the intermediate assembly parts, and from part names to intermediate assembly names, each level of expression can include attribute information related to the parts, so that the parts can be combed on site conveniently, and the management efficiency of the intermediate assembly parts is improved.

Drawings

FIG. 1 is a schematic flow chart diagram illustrating an embodiment of a method for naming a medium component according to the present invention;

FIG. 2 is a schematic structural diagram of an embodiment of a naming device for middle assembly components provided by the present invention;

FIG. 3 is a diagram of a component structure category dataset according to an embodiment of the present invention;

FIG. 4 is a schematic diagram of a first component position data set according to an embodiment of the present invention;

FIG. 5 is a second component position data set diagram of an embodiment provided by the present invention;

FIG. 6 is a schematic illustration of a part type data set according to an embodiment of the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the present application, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example 1

Referring to fig. 1, fig. 1 is a schematic flow chart of an embodiment of a naming method for a medium-sized component according to the present invention, as shown in fig. 1, the method includes steps 101 to 105, specifically as follows:

step 101: and acquiring a middle component number corresponding to each middle component, and generating a first code corresponding to each middle component according to the middle component number.

In one embodiment, because welding of a plurality of middle assemblies is involved in ship section welding, and each middle assembly has a corresponding middle assembly number for distinguishing, the middle assembly number corresponding to each middle assembly is obtained by acquiring middle assembly welding data.

In one embodiment, a middle component name of each middle component is obtained according to a preset middle component naming rule based on a middle component number corresponding to each middle component, and the middle component name is used as a first code corresponding to the middle component.

In an embodiment, the preset middle component naming rule is: total component number + single english letter; preferably, the single letter may be a capital letter L or a capital letter a. The preset middle component naming rule is illustrated as follows: if the acquired middle component number is 1, the component name is 1L, wherein 1L represents the first middle component.

Step 102: and constructing a component structure category data set with component structure category attributes, wherein each component structure category attribute comprises a corresponding second code, acquiring all small components in each middle component, performing assembly structure classification on all small components to obtain an assembly structure category corresponding to each small assembly, and acquiring the second code corresponding to each small component based on the component structure category data set.

In one embodiment, all first set of riser structural categories of the gadget are obtained, wherein the first set of riser structural categories comprises primary members, watertight bulkheads and ribs, ordinary stringers, T-rows and others.

In one embodiment, each first clustering structure category is reclassified to obtain a second clustering structure category corresponding to each first clustering structure category; the second assembling structure category corresponding to the main component comprises a deck, a platform, an inner bottom plate, an outer bottom plate, a side outer plate, a stern sealing plate, a top side cabin inclined plate and a bottom side cabin inclined plate; the second assembly structure type corresponding to the watertight bulkhead and the ribbed plates comprises a watertight longitudinal bulkhead, a watertight transverse bulkhead, ribbed plates and a groove wall; the second assembling structure category corresponding to the common longitudinal and transverse plates comprises nonwatertight longitudinal bulkheads, longitudinal partition plates, transverse walls, transverse frames, rib plates and inclined rib positions; the second assemblage structure category corresponding to the T row category comprises longitudinal girders, strong beams, horizontal girders, vertical girders and combined T-shaped sections; the second assemblage structure types corresponding to other types comprise bulwarks, toggle plates, various air channels, box bodies, bilge keels, hatch coamings, cylinder bodies and the like.

In an embodiment, the combined T-section in the second set of three-dimensional structure category corresponding to the T-row category further includes a combined T-section (outer plate), a combined T-section (inner base plate), a combined T-section (deck plate), and a combined T-section (inclined plate).

In an embodiment, the other of the second stereo structure categories corresponding to the other categories refers to categories that do not appear in all the second stereo structure categories.

In one embodiment, the first assemblage structure classification is carried out on all the small assemblies to obtain a first assemblage structure category corresponding to each small assemblage; and performing second assemblage structure classification on all the small assemblies according to the first assemblage structure category corresponding to each small assemblage to obtain a second assemblage structure category corresponding to each small assemblage, and taking the second assemblage structure category corresponding to each small assemblage as the assemblage structure category corresponding to each small assemblage.

In an embodiment, a component structure category dataset with component structure category attributes is constructed in a server, specifically, a first assembly structure category of all small components and a second assembly structure category corresponding to the first assembly structure category are obtained, the component structure category attributes are set for the second assembly structure category, and a component structure category dataset with the component structure category attributes is constructed based on the first assembly structure category, the second assembly structure category and the component structure category attributes.

In an embodiment, each component structure category attribute includes a corresponding second code, where the second code is in the form of a code composed by letters, as shown in fig. 3, and fig. 3 is a schematic diagram of a component structure category data set.

Preferably, for a second set of three-dimensional structural classifications in the primary component, setting a second code for the deck corresponding to the component structural class attribute as DK; setting a second code of the corresponding component structure type attribute to the flat plate as PF; setting a second code of the corresponding component structure type attribute to the inland edition as IB; setting a second code of the corresponding component structure type attribute as a BS for the outer bottom plate; setting a second code of the corresponding component structure type attribute to be SS for the shipboard outer plate and the stern sealing plate; setting a second code of the corresponding component structure type attribute to be TT for the top plate cabin inclined plate; and setting a second code of the corresponding component structure type attribute to the bottom side cabin inclined plate as HT.

Preferably, for a second discrete structural classification in the watertight bulkhead and the rib plate, a second code of the corresponding component structural class attribute is set to LB for the watertight longitudinal bulkhead; setting a second code of the corresponding component structure type attribute to TB for the watertight transverse bulkhead and the ribbed plate; and setting the second code of the corresponding component structure type attribute on the slot wall as CB.

Preferably, for the second assemblage structure classification in the common longitudinal transverse plate, the corresponding second code of the assemblage structure classification attribute is set for the nonwatertight longitudinal bulkhead and the longitudinal partition plate to be LN; setting a second code for the component structural category attribute corresponding to the rail wall, the rail frame (including frames with faceplates, but not T-row frames), and the rib plate as FR; and setting a second code of the corresponding component structure type attribute to the inclined rib position as CF.

Preferably, for a second three-dimensional structure classification in the T rows, a second code corresponding to the component structure class attribute is set to GR for the stringer; setting a corresponding second code of the component structure category attribute to the strong beam as BM; setting a second code of the corresponding component structure category attribute to be SR for the horizontal truss; setting a second code of the corresponding component structure category attribute as VR for the vertical truss; setting a second code of the corresponding component structure type attribute to be SL for the combined T-shaped section (outer plate); setting a second code of the corresponding component structure type attribute to be BL for the combined T-shaped material (inner bottom plate); setting a second code DL of the corresponding component structure type attribute for the combined T-shaped section (deck); and setting a second code of the corresponding component structure category attribute to be WL for the combined T-shaped bar (inclined plate).

Preferably, for the second group structure classification in the other classes, the bulwark is provided with a second code of the corresponding component structure class attribute as BU; setting a second code of the corresponding component structure category attribute as BK for the toggle plate; setting a second code of the corresponding component structure type attribute to be BX for the air duct and the box body, and setting a second code of the corresponding component structure type attribute to be BG for the bilge keel; setting a second code of the corresponding component structure class attribute as CM to the hatch coaming; and setting a second code of the corresponding component structure type attribute to the barrel as TU, and setting a second code of the corresponding component structure type attribute to other classes which do not belong to any class as ET.

In an embodiment, the component structure category data set with the component structure category attribute is traversed based on the assembly structure category corresponding to each small component to obtain the component structure category attribute corresponding to the assembly structure category corresponding to each small component, and the second code corresponding to each small component is obtained according to the second code corresponding to the component structure category attribute.

As an illustration in the present embodiment, for the case that the small component is a rib, the corresponding second code is set to be FR.

Step 103: and constructing a component position data set with component position attributes, wherein each component position attribute comprises a corresponding third code, acquiring the component position of each small component, and obtaining the third code corresponding to each small group based on the component position data set.

In one embodiment, a first component location data set having first component location attributes is constructed in a server, specifically, corresponding first component location attributes are set for all first component locations, and the first component location data set is constructed based on all first component locations and their corresponding first component location attributes.

In one embodiment, the all first component positions include cross-member positions and down-member positions, each cross-member position containing a corresponding first component position attribute, and each down-member position (including the horizontal direction) containing a corresponding first component position attribute.

Preferably, the cross-member locations include assembly at the FR-2 location, assembly at the FR-1 location, assembly at the FR0 location, assembly at the FR1 location, and assembly at the FR999 location; the longitudinal members (including the horizontal direction) include assemblage at the position of the neutral line, assemblage at the L1 port and starboard position, assemblage at the L2 port and starboard position, and assemblage at the L99 port and starboard position.

In an embodiment, each first component location attribute includes a corresponding first location code, where the first location code is in the form of a code composed of numbers, as shown in fig. 4, and fig. 4 is a schematic diagram of a first component location data set.

Preferably, for the cross-member position, the first position code for setting the corresponding part type attribute at the FR-2 position for assembly is 02; setting the first position code of the corresponding part type attribute on the FR-1 position in an assembling way to be 01; setting the first position code of the attribute of the corresponding part type on the FR0 position as 0; setting a first position code of a corresponding part type attribute on the FR1 position in an assembling way as 1; the first position code for setting the corresponding part type attribute on the FR999 position assembly is 999.

Preferably, for the longitudinal member, the first position code of the part type attribute corresponding to the assembly setting on the position of the middle line is 0; setting a first position code of a corresponding part type attribute on the L1 port and starboard position in an assembling way to be 1; setting the first position code of the corresponding part type attribute on the L2 port and starboard position in an assembling way to be 2; and the first position code 99 for setting the corresponding part type attribute on the L99 port and starboard position in an assembling way.

In one embodiment, each of the gadgets is divided into a cross member and a longitudinal member, and a first component position of each gadget is obtained, and the first component position data set is traversed based on the first component position of each gadget, resulting in a first position code for each gadget.

In an embodiment, a second component location data set having second component location attributes is constructed in the server, specifically, corresponding second component location attributes are set for all second component locations, and the second component location data set is constructed based on all second component locations and their corresponding second component location attributes.

In one embodiment, the all second component positions include left member positions and right member positions, each left member position containing a corresponding second component position attribute, and each right member position (including the horizontal direction) containing a corresponding second ear component position attribute.

In an embodiment, each second component location attribute includes a corresponding second location code, where the second location code is in the form of a code formed by letters, as shown in fig. 5, and fig. 5 is a schematic diagram of a second component location data set.

Preferably, the second position codes for setting the corresponding component structure type attributes to the left component position are a, B, C, E, F, G, H, J, K; and setting the second position code of the corresponding component structure type attribute to the right component position as Q, R, T, U, V, W, X, Y and Z.

In one embodiment, each small component is divided into a left component and a right component, a second component position of each small component is obtained, and the second position code of each small component is obtained by traversing the second component position data set based on the second component position of each small component.

In one embodiment, the first component position data set and the second component position data set constitute a component position data set.

In one embodiment, the first position code and the second position code of each small component are combined to obtain a third position code corresponding to each small component, and the third position code is used as a group name of the small component; wherein the structure of the third position code is first position code-second position code.

In one embodiment, small components affecting robot welding are also obtained, and a preset caching code is added to the obtained small component names.

Preferably, a preset caching code H is added in front of the name of the small component, for example, 01L-HBK01A indicates that a BK01A small component below a 01L middle component is cached, robot welding is not used, and the condition that the cache cannot be welded due to the fact that the cache is installed in advance is ensured.

Step 104: and constructing a part type data set with part type attributes, wherein each part type attribute comprises a corresponding fourth code, acquiring all parts in each small assembly, and obtaining the fourth code corresponding to each part based on the part type data set.

In one embodiment, because the gadget is made up of one or more parts, each part in the gadget is named at the same time as the gadget.

In one embodiment, all parts that may be present in the small component are obtained, wherein the parts include small plates without upper board splicing station, boxes, box body individual plates, brackets with grooves, patch plates, backing plates, large plates with upper board splicing station, groove wall boards, longitudinal ribs, curved outer plates, curved plates, pillars, reinforcing ribs, panels and deck outfitting reinforcements.

In one embodiment, the panel component of all the components can be further divided into a panel without machining, a panel with R-shaped machining and a panel with folded corners.

In one embodiment, a part type data set having part type attributes is constructed in a server, specifically, corresponding part type attributes are set for all part types, and the part type data set is constructed based on all part types and the corresponding part type attributes thereof.

In one embodiment, each part type attribute includes a corresponding fourth code, where the fourth code is in the form of a code composed of letters, as shown in fig. 6, and fig. 6 is a schematic diagram of a part type data set.

Preferably, a fourth code of the corresponding part type attribute is set to be A for the small plate of the position where the jointed boards are not put on, the box body and the box body single plate; setting a fourth code of the corresponding part type attribute as B for the toggle plate; setting a fourth code of the corresponding part type attribute to be BV for the toggle plate with the groove; setting a fourth code of the corresponding part type attribute as C for the patch; setting a fourth code of the corresponding part type attribute to be D for the base plate; setting a fourth code K of corresponding part type attributes on the large plate of the upper jointed plate station and the groove-shaped wall jointed plate; setting a fourth code of the corresponding part type attribute to be L for the longitudinal bone; setting a fourth code of the corresponding part type attribute to be P for the curved surface outer plate and the curved surface plate; setting a fourth code of a corresponding part type attribute to the strut (profile) as PL; setting a fourth code of the corresponding part type attribute on the reinforcing rib as S; setting a fourth code W of the corresponding part type attribute for the panel which does not need to be processed; setting a fourth code of the corresponding part type attribute to be WR for the panel needing R-type machining; setting a fourth code of the corresponding part type attribute to be WK for the panel needing corner folding processing; and setting a fourth code of the corresponding part type attribute to the deck outfitting reinforcement material as X.

In an embodiment, when all parts in each small component are acquired, the number of each part is also acquired, a part type data set with part type attributes is traversed to obtain a part type attribute corresponding to each part, a fourth code corresponding to the part type attribute is added to the part number to serve as a fourth code corresponding to each part, and the fourth code is used as the part name.

As an example in the present embodiment, when the part is a plate part and the number of the plate parts is 1, the corresponding fourth code is set as A1.

In one embodiment, each code corresponds to a part name, and each part is named according to requirements, so that part searching and management are facilitated.

In one embodiment, parts affecting robot welding are also obtained, and a preset caching code is added to the obtained part names.

Preferably, a preset caching code H is added in front of the part, if 01L-HA1 indicates that the part A1 below the component in 01L is cached, robot welding is not used, and the fact that the caching device is installed in advance to cause the robot to be incapable of welding is ensured.

Step 105: and sequencing the first code, the second code, the third code and the fourth code according to a preset part name naming rule to obtain the name of the assembled part.

In one embodiment, the preset part name naming rule is as follows: medium group name-part name.

In one embodiment, the first code is named as the middle group, the second code and the third code are added to form the part name, and the fourth code is formed as the part name.

In one embodiment, the first code, the second code, the third code and the fourth code are ordered according to the group name, the part name and the part name, so as to obtain the name of the group part.

As an illustration of this embodiment: the designation 1L-FR26A-A1 for the middle assembly parts, where 1L denotes the first middle assembly, and so on, FR26A denotes the rib position rib plate framing member (small assembly) No. 26, a denotes the rib position rib plate on the left, and A1 denotes the plate part on the rib plate frame not on the splice plate station.

Preferably, the name of the small component below the middle component must be carried with the name of the middle component, and in addition, the name of the single part below the middle component, which does not need to be assembled by the small component, also needs to be carried with the name of the middle component, namely, the name of the middle component needs to be carried with the name of the small component or the part below the middle component.

In conclusion, the naming method of the middle assembly parts can combine the part characteristics of the ship structure, set a certain rule for naming all the middle assembly parts, and each level of expression can include the attribute information related to the parts from the part names to the middle assembly names, so that each level of small assemblies below the middle assembly can be directly connected with the middle assembly names, have great association, facilitate the on-site carding of the parts and distribute the parts to corresponding stations, and facilitate the design and on-site whole-process management of the parts; in addition, for assemblies or parts which affect the welding of the robot, the buffering code is set and added into the parts or parts, so that the buffering part is prevented from being installed in advance to prevent the robot from being incapable of welding.

Example 2

Referring to fig. 2, fig. 2 is a schematic structural diagram of an embodiment of a naming apparatus for a medium-sized component according to the present invention, as shown in fig. 2, the apparatus includes a first code obtaining module 201, a second code obtaining module 202, a third code obtaining module 203, a fourth code obtaining module 204, and a part naming module 205, which are specifically as follows:

the first code obtaining module 201 is configured to obtain a middle component number corresponding to each middle component, and generate a first code corresponding to each middle component according to the middle component number.

The second code obtaining module 202 is configured to construct a component structure category dataset having component structure category attributes, where each component structure category attribute includes a corresponding second code, obtain all small components in each middle component, perform group structure classification on all small components, obtain a group structure category corresponding to each small group, and obtain a second code corresponding to each small component based on the component structure category dataset.

The third code obtaining module 203 is configured to construct a component position data set having component position attributes, where each component position attribute includes a corresponding third code, obtain a component position of each minor component, and obtain the third code corresponding to each minor assembly based on the component position data set.

The fourth code obtaining module 204 is configured to construct a part type dataset having part type attributes, where each part type attribute includes a corresponding fourth code, obtain all parts in each small component, and obtain the fourth code corresponding to each part based on the part type dataset.

The part naming module 205 is configured to sort the first code, the second code, the third code, and the fourth code according to a preset part name naming rule to obtain a name of the assembled part.

In an embodiment, the second code obtaining module 202 is configured to perform assembly structure classification on all the small assemblies, and before obtaining the assembly structure category corresponding to each small assembly, the method further includes: acquiring all first assemblage structure types of the small assemblies, wherein the first assemblage structure types comprise main components, watertight bulkheads and ribbed plates, common longitudinal and transverse plates, T rows and other types; and reclassifying each first clustering structure class to obtain a second clustering structure class corresponding to each first clustering structure class.

The second assemblage structure category corresponding to the main component comprises a deck, a platform, an inner bottom plate, an outer bottom plate, a side outer plate, a stern sealing plate, a top side cabin inclined plate and a bottom side cabin inclined plate;

the second assembly structure type corresponding to the watertight bulkhead and the ribbed plates comprises a watertight longitudinal bulkhead, a watertight transverse bulkhead, ribbed plates and a groove wall;

the second assembly structure type corresponding to the common longitudinal and transverse plates comprises a nonwatertight longitudinal bulkhead, a longitudinal clapboard, a transverse wall, a transverse frame, a ribbed plate and an inclined rib position;

the second assemblage structure category corresponding to the T row category comprises longitudinal girders, strong beams, horizontal girders, vertical girders and combined T-shaped sections;

the second assemblage structure types corresponding to other types comprise bulwarks, toggle plates, various air channels, box bodies, bilge keels, hatch coamings, cylinder bodies and the like.

In an embodiment, the second code obtaining module 202 is configured to perform assembly structure classification on all the small assemblies to obtain an assembly structure category corresponding to each small assembly; specifically, performing first assemblage structure classification on all small assemblies to obtain a first assemblage structure category corresponding to each small assemblage; and performing second assemblage structure classification on all the small assemblies according to the first assemblage structure category corresponding to each small assemblage to obtain a second assemblage structure category corresponding to each small assemblage, and taking the second assemblage structure category corresponding to each small assemblage as the assemblage structure category corresponding to each small assemblage.

In an embodiment, the fourth code obtaining module 204 is configured to obtain all parts in each small component, where all the parts include small plates, boxes, box individual plates, brackets, beveled brackets, shims, backing plates, large plates on the upper jointed plate stations, grooved wall jointed plates, longitudinal ribs, curved outer plates, curved plates, pillars, reinforcing ribs, panels, and deck outfitting reinforcements.

It can be clearly understood by those skilled in the art that, for convenience and simplicity of description, the specific working process of the apparatus described above may refer to the corresponding process in the foregoing method embodiment, and details are not described herein.

It should be noted that the above embodiments of the naming device of the assembled components are merely illustrative, wherein the modules described as separate components may or may not be physically separate, and the components displayed as modules may or may not be physical units, may be located in one place, or may be distributed on multiple network units. Some or all of the modules may be selected according to actual needs to achieve the purpose of the solution of this embodiment.

On the basis of the above embodiment of the naming method for the middle assembly components, another embodiment of the present invention provides a naming terminal device for the middle assembly components, which includes a processor, a memory, and a computer program stored in the memory and configured to be executed by the processor, and when the processor executes the computer program, the naming method for the middle assembly components according to any one of the embodiments of the present invention is implemented.

Illustratively, the computer program may be partitioned in this embodiment into one or more modules that are stored in the memory and executed by the processor to implement the invention. The one or more modules may be a series of computer program instruction segments capable of performing specific functions, the instruction segments being used to describe the execution of the computer program in the named terminal device of the assembled component.

The named terminal device of the middle assembly part can be a desktop computer, a notebook, a palm computer, a cloud server and other computing devices. The named terminal device of the said assembly part can include, but not limited to, processor, memory.

The Processor may be a Central Processing Unit (CPU), other general purpose Processor, a Digital Signal Processor (DSP), an Application Specific Integrated Circuit (ASIC), an off-the-shelf Programmable Gate Array (FPGA) or other Programmable logic device, discrete Gate or transistor logic, discrete hardware components, etc. The general-purpose processor may be a microprocessor or the processor may be any conventional processor or the like, the processor being the control center of the named terminal device of the intermediate assembly, and various interfaces and lines connecting the various parts of the named terminal device of the entire intermediate assembly.

The memory may be configured to store the computer program and/or module, and the processor may implement various functions of the named terminal device of the middle assembly by executing or executing the computer program and/or module stored in the memory and calling data stored in the memory. The memory may mainly include a storage program area and a storage data area, wherein the storage program area may store an operating system, an application program required for at least one function, and the like; the storage data area may store data created according to the use of the mobile phone, and the like. In addition, the memory may include high speed random access memory, and may also include non-volatile memory, such as a hard disk, a memory, a plug-in hard disk, a Smart Media Card (SMC), a Secure Digital (SD) Card, a Flash memory Card (Flash Card), at least one magnetic disk storage device, a Flash memory device, or other volatile solid state storage device.

On the basis of the above embodiment of the naming method for the assembled components, another embodiment of the present invention provides a storage medium, where the storage medium includes a stored computer program, and when the computer program runs, a device in which the storage medium is located is controlled to execute the naming method for the assembled components according to any one of the embodiments of the present invention.

In this embodiment, the storage medium is a computer-readable storage medium, and the computer program includes computer program code, which may be in source code form, object code form, executable file or some intermediate form, and so on. The computer-readable medium may include: any entity or device capable of carrying the computer program code, recording medium, U.S. disk, removable hard disk, magnetic diskette, optical disk, computer Memory, read-Only Memory (ROM), random Access Memory (RAM), electrical carrier wave signal, telecommunications signal, and software distribution medium, etc. It should be noted that the computer readable medium may contain content that is subject to appropriate increase or decrease as required by legislation and patent practice in jurisdictions, for example, in some jurisdictions, computer readable media does not include electrical carrier signals and telecommunications signals as is required by legislation and patent practice.

In summary, according to the naming method, apparatus, device and storage medium for the middle assembly components provided by the present invention, the first code of each middle component is generated by obtaining the middle component number of each middle component; acquiring all small assemblies in each middle assembly, and performing assembly structure classification on all small assemblies; obtaining a second code of each small component based on the constructed component structure category data set; acquiring the component position of each small component, and acquiring a third code of each small component based on the constructed component position data set; acquiring all parts in each small assembly, and acquiring a fourth code of each part based on the constructed part type data set; and sequencing the first code, the second code, the third code and the fourth code according to a preset part name naming rule to obtain the name of the assembled part. Compared with the prior art, the naming mode of the invention can express the relevant information such as the installation position of the part, the type of the part and the like, and improves the management efficiency of the centering and assembling parts.

The above description is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, various modifications and substitutions can be made without departing from the technical principle of the present invention, and these modifications and substitutions should also be regarded as the protection scope of the present invention.

Claims (10)

1. A naming method of a middle assembly part is characterized by comprising the following steps:

acquiring a middle component number corresponding to each middle component, and generating a first code corresponding to each middle component according to the middle component number;

constructing a component structure category data set with component structure category attributes, wherein each component structure category attribute comprises a corresponding second code, acquiring all small components in each middle component, performing assembly structure classification on all small components to obtain an assembly structure category corresponding to each small assembly, and acquiring a second code corresponding to each small component based on the component structure category data set;

constructing a component position data set with component position attributes, wherein each component position attribute comprises a corresponding third code, acquiring the component position of each small component, and obtaining the third code corresponding to each small assembly based on the component position data set;

constructing a part type data set with part type attributes, wherein each part type attribute comprises a corresponding fourth code, acquiring all parts in each small assembly, and acquiring the fourth code corresponding to each part based on the part type data set;

and sequencing the first code, the second code, the third code and the fourth code according to a preset part name naming rule to obtain the name of the assembled part.

2. The method for naming a medium-sized component as claimed in claim 1, wherein before classifying the assembly structure of all small assemblies and obtaining the assembly structure category corresponding to each small assembly, further comprising:

acquiring all first set of vertical structure types of the small assemblies, wherein the first set of vertical structure types comprise main members, watertight bulkheads and rib plates, common longitudinal and transverse plates, T rows and other types;

reclassifying each first clustering structure category to obtain a second clustering structure category corresponding to each first clustering structure category;

the second assembling structure category corresponding to the main component comprises a deck, a platform, an inner bottom plate, an outer bottom plate, a side outer plate, a stern sealing plate, a top side cabin inclined plate and a bottom side cabin inclined plate;

the second assemblage structure category corresponding to the watertight bulkhead and the ribbed plate comprises a watertight longitudinal bulkhead, a watertight transverse bulkhead, a ribbed plate and a groove wall;

the second assembling structure category corresponding to the common longitudinal and transverse plates comprises nonwatertight longitudinal bulkheads, longitudinal partition plates, transverse walls, transverse frames, rib plates and inclined rib positions;

the second assemblage structure category corresponding to the T row category comprises a longitudinal girder, a strong cross beam, a horizontal girder, a vertical girder and a combined T-shaped section;

the second assemblage structure types corresponding to other types comprise bulwarks, toggle plates, various air channels, box bodies, bilge keels, hatch coamings, cylinder bodies and the like.

3. The method for naming a medium-sized component as claimed in claim 2, wherein the step of classifying the assembly structure of all the small assemblies to obtain the assembly structure category corresponding to each small assembly specifically comprises:

performing first assembly structure classification on all the small assemblies to obtain a first assembly structure class corresponding to each small assembly;

and performing second assemblage structure classification on all the small assemblies according to the first assemblage structure category corresponding to each small assemblage to obtain a second assemblage structure category corresponding to each small assemblage, and taking the second assemblage structure category corresponding to each small assemblage as the assemblage structure category corresponding to each small assemblage.

4. The method for naming a medium-sized component as claimed in claim 1, wherein all parts in each small component are obtained, wherein the parts include small plates not attached to the board-joining station, boxes, individual plates of boxes, elbows with grooves, patches, backing plates, large plates attached to the board-joining station, wall-joining panels with grooves, longitudinals, outer curved plates, pillars, reinforcing ribs, panels, and deck-fitting stiffeners.

5. A naming device for assembling parts, comprising: the system comprises a first code acquisition module, a second code acquisition module, a third code acquisition module, a fourth code acquisition module and a part naming module;

the first code obtaining module is configured to obtain a middle component number corresponding to each middle component, and generate a first code corresponding to each middle component according to the middle component number;

the second code acquisition module is used for constructing a component structure category data set with component structure category attributes, wherein each component structure category attribute comprises a corresponding second code, acquiring all small components in each middle component, performing assembly structure classification on all the small components to obtain an assembly structure category corresponding to each small assembly, and obtaining the second code corresponding to each small component based on the component structure category data set;

the third code acquisition module is configured to construct a component position data set having component position attributes, where each component position attribute includes a corresponding third code, acquire a component position of each minor component, and obtain a third code corresponding to each minor assembly based on the component position data set;

the fourth code obtaining module is configured to construct a part type data set having part type attributes, where each part type attribute includes a corresponding fourth code, obtain all parts in each small component, and obtain the fourth code corresponding to each part based on the part type data set;

the part naming module is used for sequencing the first code, the second code, the third code and the fourth code according to a preset part name naming rule to obtain the name of the assembled part.

6. The apparatus for naming an intermediate component as claimed in claim 5, wherein said second code obtaining module is configured to classify the assembly structure of all the minor components, and further comprises;

acquiring all first assemblage structure types of the small assemblies, wherein the first assemblage structure types comprise main components, watertight bulkheads and ribbed plates, common longitudinal and transverse plates, T rows and other types;

reclassifying each first clustering structure category to obtain a second clustering structure category corresponding to each first clustering structure category;

the second assembling structure category corresponding to the main component comprises a deck, a platform, an inner bottom plate, an outer bottom plate, a side outer plate, a stern sealing plate, a top side cabin inclined plate and a bottom side cabin inclined plate;

the second assembly structure type corresponding to the watertight bulkhead and the ribbed plates comprises a watertight longitudinal bulkhead, a watertight transverse bulkhead, ribbed plates and a groove wall;

the second assembling structure category corresponding to the common longitudinal and transverse plates comprises nonwatertight longitudinal bulkheads, longitudinal partition plates, transverse walls, transverse frames, rib plates and inclined rib positions;

the second assemblage structure category corresponding to the T row category comprises a longitudinal girder, a strong cross beam, a horizontal girder, a vertical girder and a combined T-shaped section;

the second assemblage structure types corresponding to other types comprise bulwarks, toggle plates, various air channels, box bodies, bilge keels, hatch coamings, cylinder bodies and the like.

7. The apparatus for naming a medium-sized component as claimed in claim 6, wherein the second code obtaining module is configured to perform assembly structure classification on all small assemblies to obtain an assembly structure category corresponding to each small assembly, and specifically includes:

performing first assembly structure classification on all the small assemblies to obtain a first assembly structure class corresponding to each small assembly;

and performing second assemblage structure classification on all the small assemblies according to the first assemblage structure category corresponding to each small assemblage to obtain a second assemblage structure category corresponding to each small assemblage, and taking the second assemblage structure category corresponding to each small assemblage as the assemblage structure category corresponding to each small assemblage.

8. The device for naming a medium-sized component as claimed in claim 5, wherein the fourth code acquisition module is used to acquire all the parts in each small component, wherein the parts include small plates not attached to the panel station, boxes, individual plates of boxes, toggle plates with grooves, complementary plates, backing plates, large plates attached to the panel station, wall panels with grooves, longitudinals, curved outer plates, curved plates, pillars, reinforcing ribs, panels, and deck-fitting reinforcements.

9. A terminal device comprising a processor, a memory, and a computer program stored in the memory and configured to be executed by the processor, the processor implementing the method of naming an assembly of components as claimed in any one of claims 1 to 4 when executing the computer program.

10. A computer-readable storage medium, comprising a stored computer program, wherein the computer program, when executed, controls an apparatus in which the computer-readable storage medium is located to perform the method for naming an assembly of components as claimed in any one of claims 1 to 4.

Images