CN114536570B

CN114536570B - Graphite tower festival is with numerical control device processing lathe

Info

Publication number: CN114536570B
Application number: CN202210448857.4A
Authority: CN
Inventors: 姚松年
Original assignee: NANTONG GRAPHITE EQUIPMENT DES
Current assignee: NANTONG GRAPHITE EQUIPMENT DES
Priority date: 2022-04-27
Filing date: 2022-04-27
Publication date: 2022-07-08
Anticipated expiration: 2042-04-27
Also published as: CN114536570A

Abstract

The invention discloses a numerical control device machining lathe for a graphite tower section, which comprises a lathe top plate, wherein a machining assembly for machining the graphite tower section is installed at the top end of the lathe top plate; the invention relates to the technical field of graphite processing; this processing lathe can be through the ring cover net that the top of No. two boards was installed to and the bottom guard shield of the corresponding buckle installation of bottom and the arc board of No. two boards, via both to the isolation in gap between No. two boards and a board, when realizing the circulation of air, can effectively be outside the foreign matter separation, avoid the foreign matter admission apparatus inboard and disturb the normal function of return air fan.

Description

Graphite tower festival is with numerical control device processing lathe

Technical Field

The invention relates to the technical field of graphite processing, in particular to a numerical control device processing lathe for a graphite tower section.

Background

The graphite tower is tower equipment which is manufactured by taking a graphite material as a base material and is used for gas-liquid or liquid-liquid mass transfer; the graphite material has strong corrosion resistance, but is limited by the strength of the material, and the graphite tower generally has thicker tower wall and smaller pressure bearing capacity and inner diameter size; when the inner diameter exceeds 100mm or the inner pressure exceeds 0.2MPa, the steel plate is usually reinforced by a metal material; the graphite tower is divided into two categories, namely a packed tower and a plate tower according to the structure;

a machining lathe on the market cannot be normally used in a humid environment, the interference of water vapor and dust around the lathe on the manufacturing quality of the graphite tower section cannot be reduced, and dust particles generated in the machining process cannot be effectively collected and processed.

Disclosure of Invention

Aiming at the defects of the prior art, the invention provides a numerical control device machining lathe for a graphite tower section, which solves the problems that the machining lathe cannot be normally used in a humid environment, the interference of water vapor and dust around the lathe on the manufacturing quality of the graphite tower section cannot be reduced, and dust particles generated in the machining process cannot be effectively collected and processed.

In order to achieve the purpose, the invention is realized by the following technical scheme: a machining lathe for a graphite tower section numerical control device comprises a lathe top plate, wherein a machining assembly for machining the graphite tower section is mounted at the top end of the lathe top plate, a numerical control mechanism for controlling the lathe is mounted at the top end of the lathe top plate, a fixing table for fixing the graphite tower section is mounted in the middle of the top end of the lathe top plate, a first plate is mounted at the lower end of the lathe top plate, a second plate is mounted at the lower end of the first plate, a column base penetrates through the second plate in the middle of the lower end of the first plate and is connected with the middle of the lower end of the first plate, a guide cavity is formed in the column base, a storage body for storing dust and water vapor is connected to the lower end of the column base, a horse shoe table is mounted at the bottom end of the column base, and a cross cavity groove for expanding the contact area with air is formed in the surface of the bottom end of the horse shoe table; the top end of the second plate is provided with a ring cover net for blocking foreign matters, the upper end of the second plate and the bottom end of the first plate are provided with an air return fan in a hanging mode, the air return fan is used for gathering dust around the lathe, and the top end of the air return fan is connected with an air inlet hopper for guiding air flow; the dust chamber has been seted up to the inside of storage body, the internally mounted in dust chamber has the activated carbon post, the dust chamber is used for cooperating the activated carbon post to collect the dust granule, the steam chamber has been seted up to the offside below that the inside of storage body is located the dust chamber, the internally mounted in steam chamber has the cotton that absorbs water, the dust chamber is linked together with the steam chamber, the bottom and the dust chamber one side in guide chamber are linked together.

Preferably, through holes facilitating air circulation are uniformly formed in the surface of the ring cover net, a guide pipe is installed between the lathe top plate and the first plate, the front end of the guide pipe is communicated with the air inlet hopper, the rear end of the guide pipe is communicated with the guide cavity, an air closing ring is installed between the rear end of the guide pipe and the guide cavity, and a connector is formed in the connecting position of the air inlet hopper and the guide pipe, so that the air inlet hopper and the guide pipe can be conveniently assembled in a butt joint mode.

Preferably, the arc plate is installed to the bottom of a board, the activated carbon plate is installed to the inboard gomphosis of arc plate, the activated carbon plate is used for absorbing partial dust particle, the arc wind gap has all been seted up on the bottom surface of arc plate and activated carbon plate, the arc wind gap is used for making things convenient for lathe air current flow around to return air fan department.

Preferably, the bottom surface of the second plate and the corresponding buckle of the arc plate are provided with a bottom shield, the surface of the bottom shield is provided with pores, the periphery of the upper end surface of the second plate is provided with short insertion columns, and a support is connected between the air return fan and the air inlet hopper, so that the air inlet hopper can guide and collect collected air flow in time.

Preferably, an air guide groove is formed in the bottom end surface of the first plate and corresponds to the air inlet hopper, an inserting rod is arranged at the top end of the arc plate, an inserting hole is formed in the bottom end surface of the first plate, and the arc plate is matched with the first plate through the inserting rod and the inserting hole to be inserted and installed, so that the arc plate is convenient to disassemble and assemble.

Preferably, the column groove has all been seted up all around to the bottom surface of a board, No. two boards through short post and column groove cooperation and a board built-up mounting, the bottom surface of a board is close to the border position and has seted up the annular, the ring cover net passes through the annular and installs with a board gomphosis, effectively isolates the protection to the gap between a board and No. two boards.

Preferably, the inside of storage body is located one side in the steam chamber and has seted up the gooseneck chamber, the upper end in gooseneck chamber is linked together with the steam chamber, the whole of gooseneck chamber is the design of the font of falling several, the bottom in gooseneck chamber is linked together with cross chamber groove, utilizes the effect of detaining of the department of buckling in gooseneck chamber to steam, can effectively avoid steam to collect the weeping phenomenon that excessively causes.

Preferably, the opposite side activity hinge of memory bank has closed post, memory bank and closed post constitute complete cylinder jointly, and the diameter of cylinder equals with the external diameter of guide chamber, memory bank and closed post are sealed lid mutually, prevent that steam from revealing.

Advantageous effects

The invention provides a numerical control device machining lathe for a graphite tower section. The method has the following beneficial effects:

1. this processing lathe, the ring cover net that installs through the top of No. two boards to and the bottom guard shield of the corresponding buckle installation of bottom and the arc board of No. two boards, via both to the isolation in gap between No. two boards and a board, when realizing the circulation of air, can effectively be outside the foreign matter separation, avoid the foreign matter admission apparatus inboard and disturb the normal function of return air fan.

2. This processing lathe, through the through-hole that the ring cover net surface was seted up and the pore that the surface of end guard shield was seted up, ensure that the air current can circulate to return air fan department, start the return air fan, install it at the hanging of a board bottom with it at the support under, effectively collect the air current that contains dust and steam into the air inlet hopper, via the intercommunication guide of guide tube and guide chamber, can concentrate the collection to lathe steam and dust all around, avoid dust and steam to pile up and dip the graphite tower festival, and influence the normal use effect of graphite tower festival, ensure to work under the adaptable comparatively moist special environment of lathe.

3. This processing lathe, the arc board through the bottom installation of a board to and the activated carbon plate of arc inboard is installed to the gomphosis, can cooperate via inserted bar and jack, with the arc board together hang the establishment with activated carbon plate and install the bottom at a board, through the arc board to the encircleing parcel of air return fan, utilize the porous structure of activated carbon plate self to the adsorptivity of dust, can carry out partial absorption collection to the dust in the air current that is assembled.

4. This processing lathe through the guide of guide chamber to the air current, via the absorption and the moisture absorption effect of the activated carbon post of dust intracavity side to dust and steam, effectively collects dust and steam in the dust intracavity side, then via the cotton that absorbs water of steam intracavity side, effectively will collect in the steam guide to the cotton that absorbs water of dust chamber bottom, separates dust and steam and collects the storage, then closes the post through opening and closing, can take out the steam and the dust of collecting and in time handle.

5. This processing lathe, through the gooseneck chamber that steam chamber one side is connected, via gooseneck chamber bottom and cross chamber groove intercommunication, when guaranteeing to be flowed smoothly by filterable air current, can enlarge the effective area of contact of horse's hoof platform bottom and lathe lower part via cross chamber groove, do and carry out two-way absorption to steam through cross chamber groove, be the design of the word of falling a few font via the whole of gooseneck chamber, utilize the buckling of gooseneck chamber to the effect of detaining of steam, can effectively avoid steam to collect the weeping phenomenon that the excess caused.

Drawings

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic view of an overall half-section structure of the present invention;

FIG. 3 is a schematic top view of a second panel of the present invention;

FIG. 4 is a partial structural view of a first plate and a second plate according to the present invention;

FIG. 5 is a schematic view of a partially assembled structure of an arc plate and a first plate according to the present invention;

FIG. 6 is a schematic view of the structure of the return air fan and the air intake hopper of the present invention;

fig. 7 is a partial sectional view of the column base and the horse hoof platform of the present invention.

In the figure: 1. a lathe top plate; 2. processing the assembly; 3. a numerical control mechanism; 4. a fixed table; 5. a first board; 51. a column groove; 52. a ring groove; 6. a second plate; 61. short inserting columns; 62. a ring cover net; 63. a guide tube; 64. a bottom shield; 65. an arc plate; 66. a return air fan; 661. a support; 662. an air inlet hopper; 663. an interface; 67. an activated carbon plate; 68. a jack; 69. an air introducing groove; 7. a column shoe; 71. a guide chamber; 72. a memory bank; 721. a dust chamber; 722. a water vapor chamber; 723. a gooseneck cavity; 73. closing the column; 8. a horse hoof platform; 81. a cross cavity groove.

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 embodiments of the present invention, 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 one

Referring to fig. 1-7, the present invention provides a technical solution: a numerical control device machining lathe for graphite tower sections comprises a lathe top plate 1, a machining assembly 2 used for machining the graphite tower sections is installed at the top end of the lathe top plate 1, a numerical control mechanism 3 used for controlling the lathe is installed at the top end of the lathe top plate 1, a fixing table 4 used for fixing the graphite tower sections is installed in the middle of the top end of the lathe top plate 1, a first plate 5 is installed at the lower end of the lathe top plate 1, a second plate 6 is installed at the lower end of the first plate 5, the middle of the lower end of the first plate 5 penetrates through the second plate 6 to be connected with a column base 7, a guide cavity 71 is formed in the column base 7, the lower end of the column base 7 is connected with a storage body 72 used for storing dust and water vapor, a horse shoe 8 is installed at the bottom end of the column base 7, and a cavity cross-shaped groove 81 used for expanding the contact area with air is formed in the surface of the bottom end of the horse shoe 8; the top end of the second plate 6 is provided with a ring cover net 62 for blocking foreign matters, the upper end of the second plate 6 and the bottom end of the first plate 5 are provided with a return air fan 66 in a hanging manner, the return air fan 66 is used for gathering dust around the lathe, and the top end of the return air fan 66 is connected with an air inlet hopper 662 for guiding air flow; a dust cavity 721 is formed in the storage body 72, an activated carbon column is installed in the dust cavity 721, the dust cavity 721 is used for being matched with the activated carbon column to collect dust particles, a water vapor cavity 722 is formed in the storage body 72 and located below the opposite side of the dust cavity 721, absorbent cotton is installed in the water vapor cavity 722, the dust cavity 721 is communicated with the water vapor cavity 722, and the bottom end of the guide cavity 71 is communicated with one side of the dust cavity 721;

as shown in fig. 3-6, through holes facilitating air circulation are uniformly formed in the surface of the ring cover net 62, a guide pipe 63 is installed between the lathe top plate 1 and the first plate 5, the front end of the guide pipe 63 is communicated with an air inlet hopper 662, the rear end of the guide pipe 63 is communicated with a guide cavity 71, an air closing ring is installed between the rear end of the guide pipe 63 and the guide cavity 71, and a joint 663 is formed at the joint of the air inlet hopper 662 and the guide pipe 63; the bottom end of the first plate 5 is provided with an arc plate 65, the inner side of the arc plate 65 is embedded with an activated carbon plate 67, the activated carbon plate 67 is used for absorbing part of dust particles, the bottom end surfaces of the arc plate 65 and the activated carbon plate 67 are both provided with arc-shaped air ports, and the arc-shaped air ports are used for facilitating the air flow around the lathe to flow to the air return fan 66; a bottom shield 64 is arranged on the bottom end surface of the second plate 6 and is buckled with the arc plate 65 correspondingly, fine holes are formed in the surface of the bottom shield 64, short insertion columns 61 are arranged on the periphery of the upper end surface of the second plate 6, and a support 661 is connected between the air return fan 66 and the air inlet hopper 662; an air guide groove 69 is formed in the bottom end surface of the first plate 5 and corresponds to the air inlet hopper 662, an inserting rod is arranged at the top end of the arc plate 65, an inserting hole 68 is formed in the bottom end surface of the first plate 5, and the arc plate 65 is installed in an inserting mode with the first plate 5 through the matching of the inserting rod and the inserting hole 68; column grooves 51 are formed in the periphery of the bottom end surface of the first plate 5, the second plate 6 is installed with the first plate 5 in a combined mode through the matching of short inserting columns 61 and the column grooves 51, a ring groove 52 is formed in the position, close to the edge, of the bottom end surface of the first plate 5, and a ring cover net 62 is installed with the first plate 5 in an embedded mode through the ring groove 52.

When the air circulation fan works, the annular shield net 62 arranged at the top end of the second plate 6 and the bottom shield 64 arranged at the bottom end of the second plate 6 and correspondingly buckled with the arc plate 65 realize the air circulation and simultaneously can effectively block foreign matters outside and prevent the foreign matters from entering the inner side of the device to interfere the normal operation of the air return fan 66;

through the through holes formed in the surface of the ring cover net 62 and the fine holes formed in the surface of the bottom cover 64, the air flow is enabled to be communicated to the air return fan 66, the air return fan 66 is started, the air flow containing dust and water vapor is effectively collected into the air inlet hopper 662 under the condition that the support 661 is arranged at the bottom end of the first plate 5 in a hanging mode, the water vapor and dust around the lathe can be collected in a centralized mode through the communication and guide of the guide pipe 63 and the guide cavity 71, the dust and the water vapor are prevented from being accumulated and entering the graphite tower section, the normal use effect of the graphite tower section is prevented from being influenced, and the lathe is enabled to work in a humid special environment;

through the arc board 65 of the bottom installation of a board 5 to and the activated carbon board 67 of arc board 65 inboard is installed in the gomphosis, can cooperate via inserted bar and jack 68, hang arc board 65 together with activated carbon board 67 and establish the bottom of installing at a board 5, through the surrounding parcel of arc board 65 to return air fan 66, utilize the porous structure of activated carbon board 67 self to the adsorptivity of dust, can carry out the part to the dust in the air current that is assembled and adsorb the collection.

Example two

As shown in fig. 1 to 7, the present invention provides a technical solution: a numerical control device machining lathe for graphite tower sections comprises a lathe top plate 1, a machining assembly 2 used for machining the graphite tower sections is installed at the top end of the lathe top plate 1, a numerical control mechanism 3 used for controlling the lathe is installed at the top end of the lathe top plate 1, a fixing table 4 used for fixing the graphite tower sections is installed in the middle of the top end of the lathe top plate 1, a first plate 5 is installed at the lower end of the lathe top plate 1, a second plate 6 is installed at the lower end of the first plate 5, the middle of the lower end of the first plate 5 penetrates through the second plate 6 to be connected with a column base 7, a guide cavity 71 is formed in the column base 7, the lower end of the column base 7 is connected with a storage body 72 used for storing dust and water vapor, a horse shoe 8 is installed at the bottom end of the column base 7, and a cavity cross-shaped groove 81 used for expanding the contact area with air is formed in the surface of the bottom end of the horse shoe 8; the top end of the second plate 6 is provided with a ring cover net 62 for blocking foreign matters, the upper end of the second plate 6 and the bottom end of the first plate 5 are provided with a return air fan 66 in a hanging manner, the return air fan 66 is used for gathering dust around the lathe, and the top end of the return air fan 66 is connected with an air inlet hopper 662 for guiding air flow; a dust cavity 721 is formed in the storage body 72, an activated carbon column is installed in the dust cavity 721, the dust cavity 721 is used for being matched with the activated carbon column to collect dust particles, a water vapor cavity 722 is formed in the storage body 72 and located below the opposite side of the dust cavity 721, absorbent cotton is installed in the water vapor cavity 722, the dust cavity 721 is communicated with the water vapor cavity 722, and the bottom end of the guide cavity 71 is communicated with one side of the dust cavity 721;

as shown in fig. 7, a gooseneck cavity 723 is formed in one side of the water vapor cavity 722 in the storage body 72, the upper end of the gooseneck cavity 723 is communicated with the water vapor cavity 722, the gooseneck cavity 723 is integrally designed in an inverted-V shape, and the bottom end of the gooseneck cavity 723 is communicated with the cross cavity groove 81; the opposite side of the storage body 72 is movably hinged with a closed column 73, the storage body 72 and the closed column 73 form a complete cylinder together, the diameter of the cylinder is equal to the outer diameter of the guide cavity 71, and the storage body 72 and the closed column 73 are sealed and covered.

During operation, the guide cavity 71 guides airflow, the activated carbon columns on the inner side of the dust cavity 721 absorb dust and water vapor and absorb moisture, the dust and the water vapor are effectively collected on the inner side of the dust cavity 721, the water vapor collected at the bottom of the dust cavity 721 is effectively guided to the water absorbent cotton through the water absorbent cotton on the inner side of the water vapor cavity 722, the dust and the water vapor are separated, collected and stored, and the collected water vapor and dust can be taken out for timely treatment by opening and closing the columns 73;

through the gooseneck cavity 723 that water vapor cavity 722 one side is connected, communicate with cross chamber groove 81 through gooseneck cavity 723 bottom, when guaranteeing that the air current by the filtration flows smoothly, can enlarge the effective area of contact of horse hoof platform 8 bottom and lathe lower part through cross chamber groove 81, also can carry out two-way absorption to steam through cross chamber groove 81, the whole through gooseneck cavity 723 is the design of the style of calligraphy of falling a few, utilize the effect of detaining to steam of the department of buckling of gooseneck cavity 723, can effectively avoid the weeping phenomenon that the excessive steam collection caused.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation. The use of the phrase "comprising one of the elements does not exclude the presence of other like elements in the process, method, article, or apparatus that comprises the element.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims

1. The utility model provides a graphite tower festival is with numerical control device processing lathe, includes lathe bed board (1), the top of lathe bed board (1) is installed and is used for processing subassembly (2) of graphite tower festival processing, numerical control mechanism (3) that are used for controlling the lathe are installed on the top of lathe bed board (1), the top mid-mounting of lathe bed board (1) has fixed station (4) of fixed graphite tower festival, a board (5), its characterized in that are installed to the lower extreme of lathe bed board (1): a second plate (6) is installed at the lower end of the first plate (5), the middle of the lower end of the first plate (5) penetrates through the second plate (6) to be connected with a column base (7), a guide cavity (71) is formed inside the column base (7), the lower end of the column base (7) is connected with a storage body (72) for storing dust and water vapor, a horse hoof platform (8) is installed at the bottom end of the column base (7), and a cross cavity groove (81) for enlarging the contact area with air is formed in the surface of the bottom end of the horse hoof platform (8);

a ring cover net (62) used for blocking foreign matters is installed at the top end of the second plate (6), an air return fan (66) is installed at the upper end of the second plate (6) and located at the bottom end of the first plate (5) in a hanging mode, the air return fan (66) is used for gathering dust around the lathe, an air inlet hopper (662) used for guiding air flow is connected to the top end of the air return fan (66), through holes facilitating air circulation are evenly formed in the surface of the ring cover net (62), a guide pipe (63) is installed between the lathe top plate (1) and the first plate (5), the front end of the guide pipe (63) is communicated with the air inlet hopper (662), the rear end of the guide pipe (63) is communicated with a guide cavity (71), an air closing plug ring is installed between the rear end of the guide pipe (63) and the guide cavity (71), and an interface (663) is formed at the connection position of the air inlet hopper (662) and the guide pipe (63), an arc plate (65) is installed at the bottom end of the first plate (5), an activated carbon plate (67) is installed on the inner side of the arc plate (65) in an embedded mode, the activated carbon plate (67) is used for absorbing partial dust particles, arc-shaped air ports are formed in the bottom end surfaces of the arc plate (65) and the activated carbon plate (67) and used for facilitating air flow around the lathe to flow to an air return fan (66), a bottom protective cover (64) is installed on the bottom end surface of the second plate (6) in a buckled mode corresponding to the arc plate (65), fine holes are formed in the surface of the bottom protective cover (64), short inserting columns (61) are arranged on the periphery of the upper end surface of the second plate (6), and a support (661) is connected between the air return fan (66) and an air inlet hopper (662);

dust chamber (721) have been seted up to the inside of memory body (72), the internally mounted of dust chamber (721) has the activated carbon post, dust chamber (721) are used for cooperating the activated carbon post to collect the dust granule, steam chamber (722) have been seted up to the offside below that the inside of memory body (72) is located dust chamber (721), the internally mounted of steam chamber (722) has the cotton that absorbs water, dust chamber (721) are linked together with steam chamber (722), the bottom and dust chamber (721) one side of guide chamber (71) are linked together.

2. The numerical control device machining lathe for the graphite tower section as claimed in claim 1, characterized in that: a board (5) bottom surface just corresponds with air inlet fill (662) and has seted up air guide groove (69), the top of arc board (65) is provided with the inserted bar, jack (68) have been seted up to a board (5) bottom surface, arc board (65) are inserted through inserted bar and jack (68) cooperation and are put the installation with a board (5).

3. The numerical control device machining lathe for the graphite tower section as claimed in claim 2, characterized in that: column groove (51) have all been seted up all around to the bottom surface of a board (5), No. two board (6) are through short post (61) and column groove (51) cooperation and a board (5) built-up mounting, the bottom surface of a board (5) is close to border position and has been seted up annular (52), annular cover net (62) are installed through annular (52) and a board (5) gomphosis.

4. The numerical control device machining lathe for the graphite tower section as claimed in claim 3, characterized in that: the storage body (72) is internally provided with a gooseneck cavity (723) at one side of the water-vapor cavity (722), the upper end of the gooseneck cavity (723) is communicated with the water-vapor cavity (722), the gooseneck cavity (723) is integrally designed in an inverted-V shape, and the bottom end of the gooseneck cavity (723) is communicated with the cross cavity groove (81).

5. The numerical control device machining lathe for the graphite tower section as claimed in claim 4, characterized in that: the storage body (72) is movably hinged to the opposite side of the storage body (72) to form a closed column (73), the storage body (72) and the closed column (73) jointly form a complete cylinder, the diameter of the cylinder is equal to the outer diameter of the guide cavity (71), and the storage body (72) and the closed column (73) are hermetically covered.