CN111906292A

CN111906292A - Alloy bush production line

Info

Publication number: CN111906292A
Application number: CN201910378545.9A
Authority: CN
Inventors: 张加和
Original assignee: Qianshan County Kaichuang Rubber Machinery Manufacturing Co ltd
Current assignee: Qianshan County Kaichuang Rubber Machinery Manufacturing Co ltd
Priority date: 2019-05-08
Filing date: 2019-05-08
Publication date: 2020-11-10

Abstract

The invention discloses an alloy bushing production line, which comprises a frame, wherein a sand mold conveying belt, a pouring mechanism, a sand mold crushing mechanism, a heat treatment mechanism and a processing mechanism are arranged on the frame, the pouring mechanism comprises a pouring bin, a smelting furnace is arranged at the top of the pouring bin, a pouring port at the bottom end of the smelting furnace extends into the top of the pouring bin, a pouring conveying belt transversely penetrates through the pouring bin, a sand mold is fixed on the pouring conveying belt, the sand mold crushing mechanism comprises a vibrating screen, the vibrating screen is obliquely arranged on the frame through a vibrating screen support, a vibrator is fixedly arranged at the bottom of the top end of the vibrating screen, the heat treatment mechanism comprises a tempering furnace, and a tempering conveying belt penetrating through the tempering furnace is arranged on the frame; in the casting and tempering processes, protective gas is used for protection, so that the casting quality and the surface quality in the tempering process are ensured.

Description

Alloy bush production line

Technical Field

The invention belongs to the technical field of alloy bushing production, and particularly relates to an alloy bushing production line.

Background

The liner refers to a collar that functions as a liner. In the field of valve application, the bushing is arranged in the valve cover, and is generally made of corrosion-resistant materials such as polytetrafluoroethylene or graphite and the like for sealing;

alloy bushings are now used more and more widely, such as tungsten steel bushings, which are mainly used in stamping and drawing. The hard alloy is widely used as a cutter material, such as a turning tool, a milling cutter, a planer tool, a drill bit, a boring cutter and the like, is used for cutting cast iron, nonferrous metals, plastics, chemical fibers, graphite, glass, stone materials and common steel materials, and can also be used for cutting refractory steel, stainless steel, high manganese steel, tool steel and other materials which are difficult to process. The cutting speed of the existing novel hard alloy cutter is hundreds times of that of carbon steel.

However, the existing alloy bushing is single in production mode, mainly adopts a machining mode for production, and is low in production efficiency and high in machining cost.

Disclosure of Invention

The invention aims to: in order to solve the technical problems of single production mode, low production efficiency and high processing cost of the alloy bushing, the alloy bushing production line is provided.

The technical scheme adopted by the invention is as follows:

the utility model provides an alloy bush production line, includes the frame, be equipped with sand mould transport band in the frame, pour mechanism, broken mechanism of sand mould, heat treatment mechanism and processing agency, pour the mechanism including pouring the storehouse, it is equipped with the smelting furnace to pour the storehouse top, and the smelting furnace bottom is pour the mouth and is stretched into and pour the storehouse in the top, and it has the conveyer belt of pouring to transversely run through in the storehouse, and the sand mould is fixed on pouring the conveyer belt, and broken mechanism of sand mould includes the shale shaker, the shale shaker passes through the shale shaker support slope and sets up in the frame, and the fixed vibrator that is equipped with in shale shaker top bottom, heat treatment mechanism includes the tempering furnace, is equipped with the tempering conveyer belt that runs through the tempering furnace in the.

The machine frame is provided with a pouring air storage tank corresponding to the pouring bin, pouring protective gas is stored in the pouring air storage tank, the pouring air storage tank is communicated with the pouring bin through a first guide pipe, and a first air pump is arranged on the first guide pipe.

The frame is provided with a tempering gas storage tank corresponding to the tempering furnace, tempering protective gas is stored in the tempering gas storage tank, the tempering gas storage tank is communicated with the tempering furnace through a second conduit, and a second air pump is arranged on the second conduit.

The sand mold conveying belt is fixed on the frame through a sand mold conveying support, and a partition plate for separating sand molds is arranged on the sand mold conveying belt.

The automatic feeding device also comprises a discharging conveyer belt, wherein the discharging conveyer belt is fixed at the outlet end of the processing mechanism on the frame through a discharging conveyer support.

The sand mold crushing mechanism further comprises a hammer crusher, the hammer crusher comprises a crusher bin, the top of the crusher bin is provided with an arc-shaped crushing bin, the top of the arc-shaped crushing bin is provided with a feeding hopper, the top of the arc-shaped crushing bin is provided with a feeding port, the feeding hopper is communicated with the top of the arc-shaped crushing bin through a guide cylinder, the middle of the inside of the arc-shaped crushing bin is provided with a crushing roller, the crushing roller is evenly provided with a crushing hammer, the crushing hammer is fixed on the crushing roller through a hammer support, the inner wall of the top of the inside of the arc-shaped crushing bin is provided with crushing teeth, the bottom of the arc-shaped crushing bin is provided with an arc-shaped sieve plate, the arc-shaped sieve plate is evenly provided with sieve pores, the middle of the bottom of the.

Wherein, the feeder hopper bottom is fixed on the machine storehouse through the feeding support, and bilateral symmetry is equipped with unhurried current mechanism in the feeder hopper.

Wherein, it includes the board that slowly flows to flow the mechanism, slowly flow the board top and articulate on feeder hopper top inner wall, slowly flow board middle part downside and pass through buffer spring and fix on the feeder hopper inner wall.

And vibration reduction supports are uniformly arranged at the bottom of the rack.

In summary, due to the adoption of the technical scheme, the invention has the beneficial effects that:

1. the invention provides an alloy bushing production line, which is used for producing an alloy bushing by a fusion casting and machining matching method, has high production efficiency and ensures the quality of the alloy bushing.

2. In the casting and tempering processes, protective gas is used for protection, so that the casting quality and the surface quality in the tempering process are ensured.

3. The invention skillfully utilizes the hammer type crushing mechanism to realize sand mold crushing and sand filtering, improves the sand mold crushing efficiency and the sand removing efficiency, and further greatly improves the demolding efficiency.

4. According to the invention, the hammer type crushing mechanism is skillfully arranged to ensure that the workpiece is crushed and demoulded in order, so that incomplete demould or extrusion injury of the workpiece is avoided.

Drawings

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

FIG. 2 is a schematic diagram of the structure of the sand mold crushing mechanism according to the present invention;

FIG. 3 is a schematic diagram showing a partial structure of a sand mold crushing mechanism according to the present invention;

FIG. 4 is a schematic view of a flow retarding mechanism in a feed hopper according to the present invention;

the labels in the figure are: 1. a frame; 1-1, a sand mould conveying bracket, 2, a sand mould conveying belt; 3. pouring a conveying belt; 4. a first conduit; 5. a pouring mechanism; 6. a furnace support; 7. a smelting furnace; 8. pouring a mouth; 9. vibrating screen; 10. a bushing; 11. a second conduit; 12. tempering furnace; 13. (ii) a 14. A discharge conveyer belt; 15. a discharge conveying support; 16. tempering the conveyer belt; 17. tempering the gas storage tank; 18. a second air pump; 19. a sand storage bin; 20. a vibrator; 21. a shaker support; 22. sand molding; 23. a storehouse is poured; 24. pouring an air storage tank; 25. a first air pump; 26. and a vibration reduction bracket.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc., indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention; the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance; furthermore, unless expressly stated or limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, as they may be fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Embodiment one, referring to fig. 1, an alloy bushing production line comprises a frame 1, wherein a sand mold conveyor belt 2, a pouring mechanism 5, a sand mold crushing mechanism, a heat treatment mechanism and a processing mechanism are arranged on the frame 1, the pouring mechanism 5 comprises a pouring bin 23, a smelting furnace 7 is arranged at the top of the pouring bin 23, the smelting furnace 7 is fixed on the frame through a furnace-smelting bracket 6, a pouring port 8 at the bottom end of the smelting furnace 7 extends into the inner top of the pouring bin 23, a pouring conveyor belt 3 transversely penetrates through the pouring bin 23, a sand mold is fixed on the pouring conveyor belt 3, the sand mold crushing mechanism comprises a vibrating screen 9, the vibrating screen 9 is obliquely arranged on the frame 1 through a vibrating screen bracket 21, a vibrator 20 is fixedly arranged at the bottom of the top end of the vibrating screen 9, the heat treatment mechanism comprises a tempering furnace 12, a tempering conveyer belt 16 penetrating through the tempering furnace 12 is arranged on the frame 1, and the processing mechanism is a numerical control processing machine tool.

In the second embodiment, referring to fig. 1, an alloy bushing production line comprises a frame 1, wherein a sand mold conveyor belt 2, a pouring mechanism 5, a sand mold crushing mechanism, a heat treatment mechanism and a processing mechanism are arranged on the frame 1, the pouring mechanism 5 comprises a pouring bin 23, a smelting furnace 7 is arranged at the top of the pouring bin 23, the smelting furnace 7 is fixed on the frame through a furnace-smelting bracket 6, a pouring port 8 at the bottom end of the smelting furnace 7 extends into the inner top of the pouring bin 23, a pouring conveyor belt 3 transversely penetrates through the pouring bin 23, a sand mold is fixed on the pouring conveyor belt 3, the sand mold crushing mechanism comprises a vibrating screen 9, the vibrating screen 9 is obliquely arranged on the frame 1 through a vibrating screen bracket 21, a vibrator 20 is fixedly arranged at the bottom of the top end of the vibrating screen 9, the heat treatment mechanism comprises a tempering furnace 12, a tempering conveyer belt 16 penetrating through the tempering furnace 12 is arranged on the frame 1, and the processing mechanism is a numerical control processing machine tool.

A pouring air storage tank 24 is arranged on the frame 1 corresponding to the pouring bin 23, pouring protective gas is stored in the pouring air storage tank 24, the pouring air storage tank 24 is communicated with the pouring bin 23 through a first guide pipe 4, and a first air pump is arranged on the first guide pipe 4.

The frame 1 is provided with a tempering gas storage tank 17 corresponding to the tempering furnace 12, tempering protective gas is stored in the tempering gas storage tank, the tempering gas storage tank is communicated with the tempering furnace 12 through a second conduit 11, and the second conduit 11 is provided with a second air pump 18.

In the third embodiment, referring to fig. 1, an alloy bushing production line comprises a frame 1, wherein a sand mold conveying belt 2, a pouring mechanism 5, a sand mold crushing mechanism, a heat treatment mechanism and a processing mechanism are arranged on the frame 1, the pouring mechanism 5 comprises a pouring bin 23, a smelting furnace 7 is arranged at the top of the pouring bin 23, the smelting furnace 7 is fixed on the frame through a furnace-smelting bracket 6, a pouring port 8 at the bottom end of the smelting furnace 7 extends into the inner top of the pouring bin 23, a pouring conveyor belt 3 transversely penetrates through the pouring bin 23, a sand mold is fixed on the pouring conveyor belt 3, the sand mold crushing mechanism comprises a vibrating screen 9, the vibrating screen 9 is obliquely arranged on the frame 1 through a vibrating screen bracket 21, a vibrator 20 is fixedly arranged at the bottom of the top end of the vibrating screen 9, the heat treatment mechanism comprises a tempering furnace 12, a tempering conveyer belt 16 penetrating through the tempering furnace 12 is arranged on the frame 1, and the processing mechanism is a numerical control processing machine tool.

The embodiment adds the following technical features on the basis of the first embodiment: the sand mould conveying belt 2 is fixed on the frame 1 through a sand mould conveying bracket 1-1, and a partition plate for separating sand moulds is arranged on the sand mould conveying belt 2.

The automatic feeding device also comprises a discharging conveying belt 14, wherein the discharging conveying belt 14 is fixed at the outlet end of the processing mechanism on the rack 1 through a discharging conveying support 15.

Example four, refer to FIGS. 1 to 3; the utility model provides an alloy bush production line, includes frame 1, be equipped with sand mould conveyer belt 2 in frame 1, pour mechanism 5, the broken mechanism of sand mould, heat treatment mechanism and processing agency, pour mechanism 5 including pouring storehouse 23, it is equipped with smelting furnace 7 to pour storehouse 23 top, and smelting furnace 7 is fixed in the frame through smelting furnace support 6, and 7 bottom pouring mouths 8 of smelting furnace stretch into and pour storehouse 23 interior top, and it has pouring conveyer belt 3 to transversely run through in pouring storehouse 23, and the sand mould is fixed on pouring conveyer belt 3, and the broken mechanism of sand mould includes shale shaker 9, shale shaker 9 passes through shale shaker support 21 slope setting in frame 1, and shale shaker 9 top bottom is fixed and is equipped with vibrator 20, heat treatment mechanism includes tempering furnace 12, is equipped with tempering conveyer belt 16 that runs through tempering furnace 12 in frame 1, processing agency is numerical control machine tool.

The embodiment adds the following technical features on the basis of the first embodiment: the sand mold crushing mechanism also comprises a hammer crusher, the hammer crusher comprises a machine bin 901, the top of the machine bin 901 is provided with an arc crushing bin 913, the top end of the arc crushing bin 913 is provided with a feed hopper 911, the top end of the arc crushing bin 913 is provided with a feed inlet, the feed hopper 911 is communicated with the top end of the arc crushing bin 913 through a guide cylinder 912, a crushing roller 914 is arranged in the middle of the arc-shaped crushing bin 913, crushing hammers 916 are uniformly arranged on the crushing roller 914, the crushing hammers 916 are fixed on the crushing roller 914 through hammer supports 917, the inner wall of the top of the arc crushing bin 913 is provided with crushing teeth 915, the bottom of the arc crushing bin 913 is provided with an arc sieve plate 922, sieve holes 923 are uniformly arranged on the arc sieve plate 922, the middle part of the bottom end of the arc sieve plate 922 is provided with a material collecting hole 918, the bottom of the arc crushing bin 913 is correspondingly provided with a feed opening 921, an inclined filter screen 920 is arranged in the machine bin 901, and a discharge hole 919 is formed in the machine bin 901 corresponding to the bottom end of the filter screen 920.

Example V, refer to FIGS. 1 to 4; the utility model provides an alloy bush production line, includes frame 1, be equipped with sand mould conveyer belt 2 in frame 1, pour mechanism 5, the broken mechanism of sand mould, heat treatment mechanism and processing agency, pour mechanism 5 including pouring storehouse 23, it is equipped with smelting furnace 7 to pour storehouse 23 top, and smelting furnace 7 is fixed in the frame through smelting furnace support 6, and 7 bottom pouring mouths 8 of smelting furnace stretch into and pour storehouse 23 interior top, and it has pouring conveyer belt 3 to transversely run through in pouring storehouse 23, and the sand mould is fixed on pouring conveyer belt 3, and the broken mechanism of sand mould includes shale shaker 9, shale shaker 9 passes through shale shaker support 21 slope setting in frame 1, and shale shaker 9 top bottom is fixed and is equipped with vibrator 20, heat treatment mechanism includes tempering furnace 12, is equipped with tempering conveyer belt 16 that runs through tempering furnace 12 in frame 1, processing agency is numerical control machine tool.

The sand mold crushing mechanism also comprises a hammer crusher, the hammer crusher comprises a machine bin 901, the top of the machine bin 901 is provided with an arc crushing bin 913, the top end of the arc crushing bin 913 is provided with a feed hopper 911, the top end of the arc crushing bin 913 is provided with a feed inlet, the feed hopper 911 is communicated with the top end of the arc crushing bin 913 through a guide cylinder 912, a crushing roller 914 is arranged in the middle of the arc-shaped crushing bin 913, crushing hammers 916 are uniformly arranged on the crushing roller 914, the crushing hammers 916 are fixed on the crushing roller 914 through hammer supports 917, the inner wall of the top of the arc crushing bin 913 is provided with crushing teeth 915, the bottom of the arc crushing bin 913 is provided with an arc sieve plate 922, sieve holes 923 are uniformly arranged on the arc sieve plate 922, the middle part of the bottom end of the arc sieve plate 922 is provided with a material collecting hole 918, the bottom of the arc crushing bin 913 is correspondingly provided with a feed opening 921, an inclined filter screen 920 is arranged in the machine bin 901, and a discharge hole 919 is formed in the machine bin 901 corresponding to the bottom end of the filter screen 920.

The bottom of the feed hopper 911 is fixed on the machine bin 901 through a feed support, and flow retarding mechanisms are symmetrically arranged in the feed hopper 911 left and right.

Wherein, unhurried current mechanism includes unhurried current board 9112, unhurried current board 9112 top articulates on feeder hopper 911 top inner wall, and unhurried current board 9112 middle part downside passes through buffer spring 9111 to be fixed on feeder hopper 911 inner wall.

Vibration reduction supports 26 are uniformly arranged at the bottom of the machine frame 1, and a sand storage bin 19 is arranged at the bottom of the machine frame 1 corresponding to the vibrating screen.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents and improvements made within the spirit and principle of the present invention are intended to be included within the scope of the present invention.

Claims

1. The utility model provides an alloy bush production line, includes frame (1), its characterized in that: the sand mold crushing machine is characterized in that a sand mold conveying belt (2), a pouring mechanism (5), a sand mold crushing mechanism, a heat treatment mechanism and a processing mechanism are arranged on the rack (1), the pouring mechanism (5) comprises a pouring bin (23), a smelting furnace (7) is arranged at the top of the pouring bin (23), the smelting furnace (7) is fixed on the rack through a smelting furnace support (6), a pouring opening (8) at the bottom end of the smelting furnace (7) extends into the inner top of the pouring bin (23), a pouring conveying belt (3) transversely penetrates through the pouring bin (23), a sand mold is fixed on the pouring conveying belt (3), the sand mold crushing mechanism comprises a vibrating screen (9), the vibrating screen (9) is obliquely arranged on the rack (1) through a vibrating screen support (21), a vibrator (20) is fixedly arranged at the bottom of the top end of the vibrating screen (9), the heat treatment mechanism comprises a tempering conveying belt (16) which penetrates through the tempering furnace (12) is arranged on the, the processing mechanism is a numerical control processing machine tool.

2. An alloy bushing production line according to claim 1, wherein: the casting machine is characterized in that a casting air storage tank (24) is arranged on the machine frame (1) corresponding to the casting bin (23), casting protective gas is stored in the casting air storage tank (24), the casting air storage tank (24) is communicated with the casting bin (23) through a first guide pipe (4), and a first air pump is arranged on the first guide pipe (4).

3. An alloy bushing production line according to claim 1, wherein: a tempering gas storage tank (17) is arranged on the rack (1) corresponding to the tempering furnace (12), tempering protective gas is stored in the tempering gas storage tank, the tempering gas storage tank is communicated with the tempering furnace (12) through a second conduit (11), and a second air pump (18) is arranged on the second conduit (11).

4. An alloy bushing production line according to claim 1, wherein: the sand mold conveying belt (2) is fixed on the rack (1) through a sand mold conveying support (1-1), and a partition plate for separating sand molds is arranged on the sand mold conveying belt (2).

5. An alloy bushing production line according to claim 1, wherein: the automatic feeding device is characterized by further comprising a discharging conveying belt (14), wherein the discharging conveying belt (14) is fixed at the outlet end of the processing mechanism on the rack (1) through a discharging conveying support (15).

6. An alloy bushing production line according to any one of claims 1 to 5, wherein: the sand mold crushing mechanism further comprises a hammer crusher, the hammer crusher comprises a crusher bin (901), an arc crushing bin (913) is arranged at the top of the crusher bin (901), a feeding hopper (911) is arranged at the top end of the arc crushing bin (913), a feeding port is arranged at the top end of the arc crushing bin (913), the feeding hopper (911) is communicated with the top end of the arc crushing bin (913) through a feeding cylinder (912), a crushing roller (914) is arranged at the middle inside the arc crushing bin (913), crushing hammers are uniformly arranged on the crushing roller (914), the crushing hammers are fixed on the crushing roller (914) through a hammer support, crushing teeth (915) are arranged on the inner wall of the top inside the arc crushing bin (913), an arc sieve plate (922) is arranged at the bottom of the arc crushing bin (913), sieve holes (923) are uniformly arranged on the arc sieve plate (922), a material collecting hole (918) is arranged at the middle of the bottom end of the arc sieve plate (922), an inclined filter screen (920) is arranged in the machine bin (901), and a discharge hole (919) is formed in the machine bin (901) corresponding to the bottom end of the filter screen (920).

7. An alloy liner production line as set forth in claim 6, wherein: the bottom of the feed hopper (911) is fixed on the machine bin (901) through a feed support, and flow retarding mechanisms are symmetrically arranged in the feed hopper (911) in the left and right direction.

8. An alloy liner production line as set forth in claim 6, wherein: unhurried current mechanism includes unhurried current board (9112), unhurried current board (9112) top articulates on feeder hopper (911) top inner wall, and unhurried current board (9112) middle part downside is fixed on feeder hopper (911) inner wall through buffer spring (9111).

9. An alloy liner production line as set forth in claim 6, wherein: the vibrating screen is characterized in that vibration damping supports (26) are uniformly arranged at the bottom of the rack (1), and sand storage bins (19) are arranged at the bottom of the rack (1) corresponding to the vibrating screen.