CN102962457A - Method for manufacturing rotating shuttle through warm flow compaction forming method - Google Patents
Method for manufacturing rotating shuttle through warm flow compaction forming method Download PDFInfo
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- CN102962457A CN102962457A CN2012104917434A CN201210491743A CN102962457A CN 102962457 A CN102962457 A CN 102962457A CN 2012104917434 A CN2012104917434 A CN 2012104917434A CN 201210491743 A CN201210491743 A CN 201210491743A CN 102962457 A CN102962457 A CN 102962457A
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Abstract
The invention discloses a method for manufacturing a rotating shuttle through a warm flow compaction forming method. The rotating shuttle adopts the following alloy material: Fe2NiMo, FeCrMo or FeCr; and the manufacturing method of the rotating shuttle comprises the following steps: firstly, adopting an atomization method to produce raw material alloy powder, secondly, adding raw material alloy nanometer fine powder and adhesive containing surface active agent and plasticizer into the raw material alloy powder to perform mixed refining pelletizing, thirdly, adopting the warm flow compaction forming method to perform rotating shuttle compression molding, fourthly, performing degreasing and sintering in a sintering furnace, and fifthly, performing surface shaping treatment, so as to achieve the required size. The method has the advantages that Fe2NiMo, FeCrMo or FeCr is adopted as raw material, so that composition segregation and unnecessary internal impurities are eliminated, and the sintering and shrinkage uniformity of the product is good.
Description
Technical field
The present invention relates to the sewing machine accessory, relate in particular to the rotating shuttle in the sewing machine.
Background technology
Rotating shuttle is one of critical component in the sewing device equipment, complex structure.The processing method of outer shuttle adopts mechanical processing method production usually.Patent 201110132497.9 adopts powder metallurgic method processing.
Mechanical processing method can't be realized on a large scale, low-cost production, and mechanical processing method metal material utilization rate is low, adopt injection moulding production because raw material granularity is tiny, price is high, product cost is high, and the injection moulding processing technology is owing to adopt additive many, and product size precision supportability is poor.
Summary of the invention
Technical problem to be solved by this invention just provides a kind of method of utilizing the warm flow compaction method of forming to make rotating shuttle, and technique is simple, and production efficiency is high, and the metal material utilization rate is high.
For solving the problems of the technologies described above, the present invention adopts following technical scheme: a kind of method of utilizing the warm flow compaction method of forming to make rotating shuttle, it is characterized in that: the alloy material that described rotating shuttle adopts is Fe2Ni Mo, FeCrMo or FeCr, and the manufacture method of this rotating shuttle comprises the steps:
(1) adopts atomization raw materials for production alloy powder;
(2) bonding agent that add raw alloy nanometer fine powder in raw material alloy powder, contains surfactant and plasticizer carries out mixing granulation; This raw alloy nanometer fine powder refers to the alloy powder that is comprised of the associated alloys material of alloying.
(3) adopt the warm flow compaction moulding process to carry out the rotating shuttle compression molding;
(4) degreasing sintered in sintering furnace;
(5) surperficial Shape correction reaches required size.
As preferably, it is carbonyl iron dust that the raw material alloy powder of described Fe2Ni Mo contains 0.2~0.3%Mo powder, 1.5~2.5% carbonyl nickel powders, surplus by weight.
As preferably, it is carbonyl iron dust that the raw material alloy powder of described FeCrMo contains 0.2~0.3%Mo powder, 1.5~2.5%Cr powder, surplus by weight.
As preferably, the raw material alloy powder of described FeCr contains 0.5~1.5%Cr powder by weight, surplus is carbonyl iron dust.
As preferably, the granularity of described raw material alloy powder is between 10 nanometers to 200 micron, and the granularity of raw alloy nanometer fine powder is less than 1 micron, its account for raw material alloy powder weight 1 ~ 2%.
As preferably, described bonding agent adopts polyethylene glycol, polyacetals and stearic mixture, perhaps adopts Tissuemat E, paraffin, polyamide, stearic mixture, perhaps adopts Tissuemat E, palm wax, stearic mixture; The addition of described bonding agent accounts for 1 ~ 5% of raw material alloy powder weight.
As preferably, described rotating shuttle carries out the warm flow compaction moulding in 60 ~ 180 ℃ of scopes of temperature, 40 ~ 160 ℃ of mold temperatures.
As preferably, the condition of sintering furnace sintering is under vacuum or restitutive protection's atmosphere, and 800 ~ 1300 ℃ are carried out degreasing sintered.
As preferably, sintering adopts continuous sintering furnace, this sintering furnace comprises a combined type body of heater, the burner of described body of heater is provided with liftable fire door and charging aperture, the stove tail is provided with liftable fire door and discharging opening, described body of heater is disposed with the degreasing section from burner to the stove tail, sintering stage, the slow cooling section, cooling section, described degreasing section is provided with at least one inert gas pipeline, the gas outlet subsection setup of described inert gas pipeline is in degreasing section burner hearth, simultaneously degreasing section is provided with at least one control carbon gas pipeline, and the gas outlet subsection setup of described control carbon gas pipeline is in degreasing section burner hearth.
As preferably, described inert gas pipeline enters burner hearth from degreasing section left end, and described control carbon gas pipeline enters burner hearth from degreasing section right-hand member, and described inert gas pipeline and control carbon gas pipeline are provided with flow control valve.
It is raw material that the present invention adopts Fe2Ni Mo, FeCrMo or FeCr, has eliminated component segregation and unnecessary intrinsic contaminants, product sintering shrinkage high conformity; Raw material powder particle size carries out proportioning as required between nanometer to 80 micron regulates, and cost of material is significantly reduced, and product density, performance are satisfied the demand.
In addition, the present invention sets up the shaping step, eliminates the product rejection that causes because of micro-deformation, improves product percent of pass, reduces product rejection rate.
Thereby technique of the present invention is simple, and production efficiency is high, and the metal material utilization rate is high.
Description of drawings
The invention will be further described below in conjunction with the drawings and specific embodiments:
Fig. 1 is the used sintering furnace structural representation of sintering;
Fig. 2 is degreasing section inert gas pipeline structural representation;
Fig. 3 is degreasing section cooling vent hole structure schematic diagram;
Fig. 4 is the long-pending wax jar structure schematic diagram of degreasing section;
Fig. 5 is the slow cooling section structural representation;
Fig. 6 is the cooling section structural representation;
Fig. 7 is cooling section admission line structural representation;
Fig. 8 is gas distribution pipe structural representation in the cooling section admission line;
Fig. 9 is the temperature alarming device structural representation;
Figure 10 is temperature alarming device control principle schematic diagram.
The specific embodiment
The below specifies a kind of embodiment that utilizes the warm flow compaction method of forming to make the method for rotating shuttle of the present invention.
Example 1,
1, adopt polyethylene glycol (PEG), polyacetals and stearic acid as bonding agent, addition 1 ~ 5%.Add the nanometer attritive powder as the activated sintering agent, 2 ~ 80 microns of powder size scopes, through mixing, granulate after, as the warm flow compaction shaping raw material.
2, in 60 ~ 200 ℃ of scopes of temperature, carry out the warm flow compaction moulding, 40 ~ 120 ℃ of mould temperature, mould is the combined type collapsible mold, inner chamber has the final products external form.
3, with warm flow compaction powder for molding embryo spare under vacuum or restitutive protection's atmosphere, 800 ~ 1300 ℃ are carried out sintering, namely obtain profiled piece embryo spare of the present invention.
4, carry out necessary inspection, shaping is carried out in fine distortion place.
5, according to specific needs shaping piece is carried out micro-machined, to adapt to the differential demand of different groups.
Example 2
1, adopt Tissuemat E, paraffin, polyamide, stearic acid as bonding agent, addition 1 ~ 5%.Add the nanometer attritive powder as the activated sintering agent, 2 ~ 80 microns of powder size scopes, through mixing, granulate after, as the warm flow compaction shaping raw material.
2, in 60 ~ 200 ℃ of scopes of temperature, carry out the warm flow compaction moulding, 40 ~ 100 ℃ of mold temperatures.Adopt the combined type collapsible mold, inner chamber has the final products external form.
3, with warm flow compaction powder for molding embryo spare under vacuum or restitutive protection's atmosphere, 800 ~ 1300 ℃ are carried out sintering, namely obtain profiled piece embryo spare of the present invention.
4, carry out necessary inspection, shaping is carried out in fine distortion place.
According to specific needs shaping piece is carried out micro-machined, to adapt to the differential demand of different groups.
Example 3,
1, use Tissuemat E, palm wax, stearic acid as bonding agent, addition 1 ~ 5%.Add the nanometer attritive powder as the activated sintering agent, 2 ~ 80 microns of powder size scopes, through mixing, granulate after, as the warm flow compaction shaping raw material.
2, in 60 ~ 180 ℃ of scopes of temperature, carry out the warm flow compaction moulding, 40 ~ 160 ℃ of mold temperatures.Adopt the combined type collapsible mold, inner chamber has the final products external form.
3, with warm flow compaction powder for molding embryo spare under vacuum or restitutive protection's atmosphere, 800 ~ 1300 ℃ are carried out sintering, namely obtain profiled piece embryo spare of the present invention.
4, carry out necessary inspection, shaping is carried out in fine distortion place.
5, according to specific needs shaping piece is carried out micro-machined, to adapt to the differential demand of different groups.
The below carries out the used sintering furnace of sintering to rotating shuttle and makes and specifying.
As shown in Figure 1, continuous sintering furnace for the present invention's employing, it comprises a combined type body of heater, the burner of described body of heater is provided with the liftable fire door and charging aperture 6, stove tail are provided with liftable fire door and discharging opening 60, and described body of heater is disposed with degreasing section 1, sintering stage 2, slow cooling section 3, cooling section 4 from burner to the stove tail.Described furnace binding is meshbeltfurnace or stepping beam type continuous oven; When employing pushed away boat structure sintering furnace, material boat size and fire box temperature were the integral multiple relation.
Adopt external cycling mechanism between described charging aperture 6 and the discharging opening 60.This outer circulation mechanism adopts sprocket wheel, belt or gear drive to realize.
Described body of heater is provided with sample tap 150 at the linkage section 15 of degreasing section and sintering stage, and described sample tap adopts upper shed or side opening mode.This sample tap adopts mechanical pull bar or bolted mode to open or close sample tap.
Such as Fig. 2 to the concrete structure that Figure 4 shows that the degreasing section, described degreasing section is provided with at least one inert gas pipeline 11, the gas outlet subsection setup of described inert gas pipeline is in degreasing section burner hearth 13, simultaneously degreasing section is provided with at least one control carbon gas pipeline 12, and the gas outlet subsection setup of described control carbon gas pipeline is in degreasing section burner hearth 13.Inert gas pipeline 11 and control carbon gas pipeline 12 can arrange a row or multi-row gas outlet vertically.Inert gas pipeline 11 is provided with three among Fig. 2, is respectively the first inert gas pipeline 110, the second inert gas pipeline 111, the 3rd inert gas pipeline 112, and its length that stretches into burner hearth 13 inside is different.Control carbon gas pipeline 12 also can adopt the structure identical with inert gas pipeline 11.The adjusting of control carbon gas flow direction can be undertaken by rotating control carbon gas pipeline 12, control carbon gas pipeline two ends are rotatably connected on the tuning movable joint, specifically can adopt thread connection, control carbon gas pipeline is provided with handle, turning handle, then the gas outlet direction is rotated with control carbon gas pipeline 12 and is changed, certainly, for the adjusting of the gas outlet direction that realizes inert gas pipeline 11, it also can adopt the tuning movable joint structure.
Described degreasing section is provided with at least two cooling passages 131 that are communicated with flue and body of heater outer air, and this cooling passage is for closing and regulate the adjustable passage of throughput.This cooling passage 131 passes heat-insulation layer 130 and is communicated with degreasing section flue.Passage 131 adopts the natural ventilation mode.When needs are regulated zone temperatures, can realize that by the openings of sizes of opening this section upper shed can cover opening with a rotating baffle plate, flap shutter can be regulated openings of sizes.
Control carbon gas in the described control carbon gas pipeline adopts decarburization atmosphere, and this decarburization atmosphere is H
2Perhaps H
2O or decomposed ammonia body or CO
2Perhaps O
2Also or the combination of above-mentioned gas.
Described degreasing section front end below arranges long-pending wax tank 14, and described long-pending wax tank is provided with grafting wax mouth 140, inert gas entrance 141 and exhaust-valve 142.
Be illustrated in figure 5 as the concrete structure of slow cooling section, described slow cooling section 3 arranges air-cooled jacket structured, be about to the slow cooling section and be set to the jacket pipe structure, outer tube sleeve on inner pipe, have certain space to form air-cooled chuck inner chamber 30 between outer tube and the inner tube, described air-cooled chuck inner chamber 30 is inwardly dried by an air blast 31.
Such as Fig. 6 to Figure 8 shows that the cooling section concrete structure, described cooling section arranges a liftable separated door 40 cooling section is separated, described cooling section in liftable separated door front side and rear side be respectively equipped with admission line 41, the admission line of described separated door front side is used for carrying reducibility gas, and the admission line of described separated door rear side is used for carrying inert gas.
Wherein, described admission line 41 comprises that one extends transversely into the gas distribution pipe 411 of cooling section, and these gas distribution pipe two ends are slip-knot 413, and gas distribution pipe is provided with several gas outlets 412.Slip-knot and gas distribution pipe adopt spiral marking connection, when needs are adjusted airflow direction, realize by rotating the gas distribution pipe angle.
As shown in Figure 9 and Figure 10, temperature alarming device on the degreasing section describes as example, degreasing section burner hearth 13 outer heat-insulation layers 130 are provided with a main temperature thermocouple 51 and a tracking and temperature testing thermocouple 50, described main temperature thermocouple and tracking and temperature testing thermocouple are connected with switch board 5, and switch board is provided with one and follows the tracks of overtemperature alarm 52.Switch board 5 internal controller judge whether overtemperature according to the data that main temperature thermocouple 51 and a tracking and temperature testing thermocouple 50 record, if overtemperature, then control is followed the tracks of overtemperature alarm 52 and reported to the police.
Temperature alarming device on the sintering stage is identical with temperature alarming device structure on the above-mentioned degreasing section.
In addition, the heater of described degreasing section and sintering stage adopts silicon carbide heater, and described sintering furnace arranges the sintered dimensions image acquistion system at degreasing section, sintering stage.This system has photoelectric coupling mechanism, has optical system, signal processing system, sintering shrinkage curve setting program and pushes away the compositions such as boat time setting program.
The slow cooling section is provided with protective gas admission line 32, and as the usefulness that passes into sintering gas shield gas, the slow cooling section arranges thermocouple temperature measuring apparatus, is used for the temperature of monitoring slow cooling section, is convenient in time adjust cooling velocity, reduces deformation of products.Beneficial effect of the present invention is:
1, set up the inert gas pipeline in the segmentation of degreasing section, pipeline can carry out flow and airflow direction adjusting at different warm areas as required;
2, for avoiding the uniformity in airflow influence temperature field, establish the cooling passage in the degreasing section flue outside, avoid the burner hearth internal temperature uncontrollable;
3, in the degreasing section control carbon gas pipeline is set, control carbon gas can be adjusted at different sections as required, and airflow direction was adjustable after control carbon gas entered burner hearth inside;
4, control carbon gas adopts decarburization atmosphere, and these atmosphere comprise H
2, H
2O, decomposed ammonia body, CO
2, O
2And their combination, to adapt to control carbon needs.Contain O
2The mist gas ratio is controlled at non-explosive range.
5, for guaranteeing size uniform, adopt meshbeltfurnace, stepping beam type continuous oven; When pushing away boat structure sintering furnace, material boat size and fire box temperature are the integral multiple relation.
6, (sintering stage and cooling section) air inlet arranges the temperature control means in the slow cooling section, and the control cooling velocity reduces deformation of products;
7, at cooling section separated door is set, separated door leading portion configuration reducibility gas pipeline, the current potential during with the cooling of assurance product;
8, for guaranteeing to separate sneaking into of oxidizing gas when door opened, the inert gas seal measure is set, oxidation when causing the product cooling to avoid oxidizing atmosphere to enter the separated door leading portion separating the fire door back segment.
9, be the inhomogeneous deformation of products that causes in the temperature field of avoiding product degreasing and sintering process, in the preferred high-quality Temperature Control Measures, the control accuracy section temperature difference of temperature ± 5 ℃.These measures comprise that high-quality carborundum heater, symmetrically arranged TEMP detect the tracking measure;
10, be to realize that effectively the sintering process size is controlled, at degreasing section, sintering stage the sintered dimensions image acquistion system be set, from motion tracking product sintered dimensions situation of change, to adjust degreasing, sintering process system;
11, for avoiding burner to amass wax, long-pending wax tank body is set under burner; On the long-pending wax tank body inert gas pipeline is set, does not need the blowing out operation to guarantee the de-waxing process, nonoxidizing gas destroys system balancing;
12, be the implementation procedure continuous production, adopt external cycling mechanism, guarantee system's continuous circulation operation.
13, at the follow-up sample tap that arranges of degreasing section, be convenient to sample analysis skimming processes situation and adjust.
The present invention is applicable to the continuous degreasing sintering of cerul, plasticity system, and sintering process can realize that carbon is controlled, and atmosphere is controlled, temperature is controlled, and product size is controlled, and Product Precision is high, can match in excellence or beauty with the vacuum drying oven sintered products.
Claims (10)
1. method of utilizing the warm flow compaction method of forming to make rotating shuttle, it is characterized in that: the alloy material that described rotating shuttle adopts is Fe2Ni Mo, FeCrMo or FeCr, and the manufacture method of this rotating shuttle comprises the steps:
(1) adopts atomization raw materials for production alloy powder;
(2) bonding agent that add raw alloy nanometer fine powder in raw material alloy powder, contains surfactant and plasticizer carries out mixing granulation;
(3) adopt the warm flow compaction moulding process to carry out the rotating shuttle compression molding;
(4) degreasing sintered in sintering furnace;
(5) surperficial Shape correction reaches required size.
2. a kind of method of utilizing the warm flow compaction method of forming to make rotating shuttle according to claim 1 is characterized in that: it is carbonyl iron dust that the raw material alloy powder of described Fe2Ni Mo contains 0.2~0.3%Mo powder, 1.5~2.5% carbonyl nickel powders, surplus by weight.
3. a kind of method of utilizing the warm flow compaction method of forming to make rotating shuttle according to claim 1 is characterized in that: it is carbonyl iron dust that the raw material alloy powder of described FeCrMo contains 0.2~0.3%Mo powder, 1.5~2.5%Cr powder, surplus by weight.
4. a kind of method of utilizing the warm flow compaction method of forming to make rotating shuttle according to claim 1, it is characterized in that: the raw material alloy powder of described FeCr contains 0.5~1.5%Cr powder by weight, surplus is carbonyl iron dust.
5. according to claim 2 to the described a kind of method of utilizing the warm flow compaction method of forming to make rotating shuttle of 4 any one, it is characterized in that: the granularity of described raw material alloy powder is between 10 nanometers to 200 micron.
6. a kind of method of utilizing the warm flow compaction method of forming to make rotating shuttle according to claim 5, it is characterized in that: described bonding agent adopts polyethylene glycol, polyacetals and stearic mixture, perhaps adopt Tissuemat E, paraffin, polyamide, stearic mixture, perhaps adopt Tissuemat E, palm wax, stearic mixture; The addition of described bonding agent accounts for 1 ~ 5% of raw material alloy powder weight.
7. a kind of method of utilizing the warm flow compaction method of forming to make rotating shuttle according to claim 5, it is characterized in that: described rotating shuttle carries out the warm flow compaction moulding in 60 ~ 180 ℃ of scopes of temperature, 40 ~ 160 ℃ of mold temperatures.
8. a kind of method of utilizing the warm flow compaction method of forming to make rotating shuttle according to claim 5, it is characterized in that: the condition of sintering furnace sintering is under vacuum or restitutive protection's atmosphere, and 800 ~ 1300 ℃ are carried out degreasing sintered.
9. the method for utilizing the warm flow compaction method of forming to make rotating shuttle according to claim 1, it is characterized in that: sintering adopts continuous sintering furnace, this sintering furnace comprises a combined type body of heater, the burner of described body of heater is provided with liftable fire door and charging aperture, the stove tail is provided with liftable fire door and discharging opening, described body of heater is disposed with the degreasing section from burner to the stove tail, sintering stage, the slow cooling section, cooling section, described degreasing section is provided with at least one inert gas pipeline, the gas outlet subsection setup of described inert gas pipeline is in degreasing section burner hearth, simultaneously degreasing section is provided with at least one control carbon gas pipeline, and the gas outlet subsection setup of described control carbon gas pipeline is in degreasing section burner hearth.
10. the method for utilizing the warm flow compaction method of forming to make rotating shuttle according to claim 9, it is characterized in that: described inert gas pipeline enters burner hearth from degreasing section left end, described control carbon gas pipeline enters burner hearth from degreasing section right-hand member, and described inert gas pipeline and control carbon gas pipeline are provided with flow control valve.
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|---|---|---|---|
| CN201210491743.4A CN102962457B (en) | 2012-11-27 | 2012-11-27 | Method for manufacturing rotating shuttle through warm flow compaction forming method |
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|---|---|---|---|
| CN201210491743.4A CN102962457B (en) | 2012-11-27 | 2012-11-27 | Method for manufacturing rotating shuttle through warm flow compaction forming method |
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Cited By (1)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN104338928A (en) * | 2014-01-10 | 2015-02-11 | 宁波市睿科金属粉末注射成型有限公司 | Cutter bit of glass cutter and machining method thereof |
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| JPH0456707A (en) * | 1990-06-26 | 1992-02-24 | Daido Steel Co Ltd | Continuous type vacuum furnace |
| JP2003328006A (en) * | 2002-05-13 | 2003-11-19 | Ishikawajima Harima Heavy Ind Co Ltd | Continuous baking unit for porous body sheet of heat- resistant alloy, and method for manufacturing the same |
| CN102011276A (en) * | 2010-10-28 | 2011-04-13 | 宁波市鄞州勇耀缝制机械有限公司 | Process for manufacturing rotating shuttle inner shuttle bottom supporting structure |
| CN102500757A (en) * | 2011-11-09 | 2012-06-20 | 崔敏娟 | Method for manufacturing inner shuttle of rotating shuttle |
-
2012
- 2012-11-27 CN CN201210491743.4A patent/CN102962457B/en not_active Expired - Fee Related
Patent Citations (4)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| JPH0456707A (en) * | 1990-06-26 | 1992-02-24 | Daido Steel Co Ltd | Continuous type vacuum furnace |
| JP2003328006A (en) * | 2002-05-13 | 2003-11-19 | Ishikawajima Harima Heavy Ind Co Ltd | Continuous baking unit for porous body sheet of heat- resistant alloy, and method for manufacturing the same |
| CN102011276A (en) * | 2010-10-28 | 2011-04-13 | 宁波市鄞州勇耀缝制机械有限公司 | Process for manufacturing rotating shuttle inner shuttle bottom supporting structure |
| CN102500757A (en) * | 2011-11-09 | 2012-06-20 | 崔敏娟 | Method for manufacturing inner shuttle of rotating shuttle |
Cited By (1)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN104338928A (en) * | 2014-01-10 | 2015-02-11 | 宁波市睿科金属粉末注射成型有限公司 | Cutter bit of glass cutter and machining method thereof |
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Address after: 321001 Zhejiang Province, Jinhua city Wucheng District Youth Industrial Zone Patentee after: ZHEJIANG YIHUO TECHNOLOGY CO.,LTD. Address before: 321001 Zhejiang Province, Jinhua city Wucheng District Youth Industrial Zone Patentee before: ZHEJIANG YIHUO TECH CO.,LTD. |
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Granted publication date: 20141008 Termination date: 20211127 |