EP2676748A2 - Régénération de sable à moulage rotatif mécanique et procédé de fabrication des moulages à partir de sable de fonderie régénéré - Google Patents

Régénération de sable à moulage rotatif mécanique et procédé de fabrication des moulages à partir de sable de fonderie régénéré Download PDF

Info

Publication number: EP2676748A2
Authority: EP; European Patent Office
Prior art keywords: ring; dedusting; abrasive; rotor; casting sand
Prior art date: 2012-06-19
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.): Withdrawn

Application number

EP12181760.5A

Other languages

German (de)

English (en)

Other versions

EP2676748A3 (fr

Inventor

Jozef Danko

Rafal Danko

Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)

SKB DRIVE TECH SPOLKA AKCYJNA

Original Assignee

Fabryka Osi Napedowych - Skb Spz Oo Spkomandytowa

Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)

2012-06-19

Filing date

2012-08-24

Publication date

2013-12-25

2012-08-24 Application filed by Fabryka Osi Napedowych - Skb Spz Oo Spkomandytowa filed Critical Fabryka Osi Napedowych - Skb Spz Oo Spkomandytowa

2013-12-25 Publication of EP2676748A2 publication Critical patent/EP2676748A2/fr

2017-10-25 Publication of EP2676748A3 publication Critical patent/EP2676748A3/fr

Status Withdrawn legal-status Critical Current

Images

Classifications

- B—PERFORMING OPERATIONS; TRANSPORTING
- B22—CASTING; POWDER METALLURGY
- B22C—FOUNDRY MOULDING
- B22C5/00—Machines or devices specially designed for dressing or handling the mould material so far as specially adapted for that purpose
- B22C5/02—Dressing by centrifuging essentially or additionally
- B—PERFORMING OPERATIONS; TRANSPORTING
- B22—CASTING; POWDER METALLURGY
- B22C—FOUNDRY MOULDING
- B22C5/00—Machines or devices specially designed for dressing or handling the mould material so far as specially adapted for that purpose
- B22C5/18—Plants for preparing mould materials

Definitions

This invention relates to a mechanical rotary casting sand reclaimer and a method for manufacturing castings from reclaimed casting sand.
Casting technology encompasses filling of prepared moulds with liquid metal, which, during solidifying, forms a casting in the shape determined by the shape of the form.
This invention concerns the technology of casting, which uses disposable sand moulds, that is moulds made of moulding sand, whose main component is quartz sand.
Such a mould may contain a core made of core sand, with higher resistance than moulding sand.
waste casting sand that is moulding sand and core sand
reclamation for its reuse in the production of moulds for further castings.
the parameters of reclaimed sand are of high importance for the quality of castings, as unequal sand parameters may lead to deficiencies in produced castings as well as dimensional inaccuracies.
waste casting sand is submitted to preliminary reclamation involving separating mechanical pollution, fragmentation of lumps, sieving the casting sand and determining the scale for the size grade of reclaimed material and re-separating of mechanical pollution.
the casting sand undergoes secondary reclamation, under which the sand grains are released from the residue of waste binding material, after which the sand grains are cleaned of undesirable reclamation products by dedusting and finally, sand grains of specified size and uniformity of grain are produced.
mechanical dry reclamation especially for sodium silicate hardened with esters, self-hardened sand with synthetic resin as well as casting sand wit bentonite, providing that the obtained reclaim is used for casting sand of the same type.
Mechanical dry reclamation is also applied in combination with pneumatic method for waste casting sand with high level of the utilisation of sand grains which is usually hard to reclaim, including burned casting sand with bentonite, with sodium silicate, hardened with CO 2 , casting sand with cement and casting sand with phosphate binder.
Rotary reclaimers for mechanical reclamation of casting sand are used as auxiliary equipment for sand reclamation plants in advanced dry reclamation systems, or as self-dependent reclamation slot units for small casting plants. In both cases their application is most efficient for the secondary reclamation of uniform casting sand.
a German patent DE4212097 features a rotary system of mechanical reclamation produced by Vogel-Schemmann.
This device provides variable rotational speed of the rotor and is used for the reclamation of casting sand with bentonite as well as reclamation of bentonite.
the reclaimer operates casting sand dedusting and abrading the shells of waste binding material in a tank with cylinder walls, using a rotor with abrasive discs with vertical rotation axis, driven by a motor fixed on the bottom off the tank connected by a coupling with the rotor axle and operating in fluidised layer of casting sand.
the lower part of the tank is connected with circumferential air supply, which develops air overpressure under the casting sand layer and brings it into a state of fluidisation.
the upper part of the reclaimer has a dedusting duct on which a photo optic system for measuring the dusting of drained air is installed.
the control system changes the rotational speed and separates reclamation cycles into several phases of various intensity of their impact on the casting sand.
first phase of reclamation which involves combining the blowing of air through the casting sand at relatively low rotational speed of the rotor with abrasive discs, both dust additives to moulding sand (bentonite, coal dust) are recovered.
the intensive reclamation phase may include two different levels of intensity, which are achieved based on relevant signal value settings, controlling the rotational speed of the rotor.
the final phase of reclamation involves abrading the residues of binding material shells and dedusting the reclaim at low abrading intensity (slower rotation of the rotor).
the control system concerns the duration of control, yet it is not known what forces the change of rotor's rotational speed between phases. It may be the other way round, that arbitrary speed selection forces the amplitude of dust signals.
An American patent US5439044 presents a rotor device for mechanical reclamation operating periodically, with variable rotational speed of the rotor, which is used for the reclamation of casting sand with bentonite as well as for bentonite reclamation.
casting sand dedusting and waste binding material shell abrading is realised in a cylindrical casting sand tank with walls smooth on the inside and external coat with three separated ring air chambers, of which the lower chamber is closed with the drain hole bottom, whilst the upper chamber is closed with a ring shaped lid adjacent to the wall of the tank where casting sand undergoes reclamation.
the chambers supply air to the cylindrical tank by first providing air from the lower chamber, through a gap on the perimeter of the cylinder, to the casting sand in the bottom area of the tank; the middle chamber provides air through nozzles made of porous material into the central area of the cylinder filled with casting sand; whilst the upper chamber provides compressed air through nozzles located on the perimeter of the cylinder above the casting sand level.
the reclamation is operated by setting casting sand into circulation using a rotor with abrasive blades and vertical rotation axis, driven by a motor attached to the lid of cylindrical tank , supporting the circulation with air provided from the lower and middle chamber, inducing the effect of aerial fluidisation.
the motor on the tank lid has a spindle installed on the extension of the propeller shaft; the spindle has a rotor mounted on its top, which moves in the fluidised layer of casting sand.
the upper part of the reclaimer has a casting sand batch hole and a dedusting duct on the lid in which a photo optic system for measuring the dusting of drained air is installed.
the control system changes the rotational speed and separates reclamation cycles into several phases of various intensity of their impact on the casting sand.
the aim of the invention is improving the method of casting production, whereby the casting sand grains are recovered during the phase of waste casting mass (casting sand) reclamation; the properties of the sand grains give better quality of the castings formed in casting moulds made from reclaimed sand, particularly from cores.
the object of the invention is a mechanical rotary casting sand reclaimer, having a base with a grain hole and a lock, wherein the base contains a rotor supported by a vertical bearing, coupled with a driving motor by means of a belt transmission, and an abrasive ring installed on the base and enclosed within a cylindrical casing oriented concentrically to the rotor.
the reclamation unit comprises an abrasive ring with a profiled internal surface and a cylindrical external surface with lugs on its perimeter and on the bottom of the ring located within the cylindrical casing.
the rotor is connected with a driving motor by means of the belt transmission.
the casing is equipped with a casting sand batch hole and a side revision window.
a telescopic dedusting duct ending On the top surface of the abrasive ring there is further installed, coaxially with the axis of the chamber, a telescopic dedusting duct ending, the dedusting duct being connected with a dedusting cyclone and a suction fan.
the dedusting duct has sensors for measuring air velocity and a triboelectric dust counter; the sensors being connected with a triboelectric sensor signal converter and a controller of the rotational speed of the driving motor.
the abrasive elements of the rotor have a shape of rods or blades and are located horizontally on each of the vertical walls of the head with a square cross-section, in at least 2 rows with spaces between the rows equal to the double height of the rods or blades.
the height of the abrasive ring is 2 to 3 times higher than the vertical distance between the upper row of the abrasive rods or blades of the rotor and the bottom of the bowl, and the cross-section of the inner ring has a shape of a logarithmic spiral recoiling down from the ring top to its base.
the telescopic ending of the dedusting duct situated coaxially with the axis of the dedusting chamber has a telescopically adjustable extension length.
the walls of the dedusting duct have sensors measuring air velocity and a triboelectric dust counter, wherein outside the dedusting duct there is positioned a triboelectric sensor signal converter and a controller of the rotational speed of the driving motor.
Another object of the invention is a method for manufacturing castings from reclaimed casting sand, in which the casting sand moulds and cores are submitted to a two-phase reclamation, including a preliminary and a secondary reclamation, after which the reclaimed casting mass is used for manufacturing further sand moulds.
the reclaimed casting mass is additionally submitted to a third phase, which makes use of a mechanical rotary casting sand reclaimer.
the reclaimer comprises an abrasive ring with a profiled internal surface and a cylindrical external surface with lugs on its perimeter and on the bottom of the ring located within the cylindrical casing and a rotor supported by a vertical bearing, the rotor having abrasive blades or rods and located in the base concentrically to the abrasive ring.
the rotor is connected with a driving motor by means of the belt transmission.
the reclaimer further comprises a ring air blade installed on the top surface of the abrasive ring, the ring air blade having a dedusting chamber casing attached to it.
the casing is equipped with a casting sand batch hole and a side revision window.
a telescopic dedusting duct ending On the top surface of the abrasive ring there is further installed, coaxially with the axis of the chamber, a telescopic dedusting duct ending, the dedusting duct being connected with a dedusting cyclone and a suction fan.
the dedusting duct has sensors for measuring air velocity and a triboelectric dust counter; the sensors being connected with a triboelectric sensor signal converter and a controller of the rotational speed of the driving motor.
the rotary speed of the driving motor is controlled depending on the readings of the air velocity sensor and the triboelectric sensor readings.
the sand moulds and cores are manufactured from the casting mass obtained after the third phase of reclamation.
Fig. 1 presents the diagram of the casting technological line for operating the subject invention processing.
the melting plant 101 includes an induction furnace for melting rough casting and a system transporting liquid metal to the moulding station 102.
the moulding station 102 may serve as manual moulding station, equipped with moulding sand mixer-sprinklers and tipping grates.
the moulding station 102 can also serve as an automatic moulding station, equipped with a rotary caster, automated mixer-sprinkler, mould production line and table vibrator.
the moulding sand used to produce moulds at the moulding station 102 is a mixture of new sand, second level reclaim from the station 105 and third level reclaim from the station 106, serving as facing sand for castings where particular precision in retaining the external shapes of castings is required.
Cores and casting moulds requiring higher precision are prepared in the core department 103. They are formed from third level reclaim supplied from the station 106, i.e. sand of the highest purity and no thermal expansion.
the cores obtained from this sand are dimensionally stable and no resin content minimises the potential of its gassiness, which prevents many casting flaws.
Castings moulded at the station 102 are taken to the casting storage 107, whilst flat moulds and cores go to the first level reclamation station 104, where standard preliminary reclamation process is performed, that is separating mechanical pollution, fragmentation of lumps, sieving the casting sand and determining the scale for the size grade of reclaimed material and another separation of mechanical pollution.
Part of the reclaimed sand is reused as a component of moulding sand, and part goes to the second level reclamation station 105, where standard secondary reclamation process is performed, whereby the sand grains are released from the residue of waste binding material, after which they are cleaned of undesirable reclamation products by dedusting and finally, sand grains of specified size and uniformity of grain are produced.
Part of the reclaimed sand is added as raw material to moulding sand at the moulding station 102, and part goes to the third level reclamation station 106, which is the mechanical rotary casting sand reclaimer described in detail in Fig. 2-4 , in which sand purified from resin residues and resistant to thermal expansion is obtained.
the third level reclamation station 106 is the mechanical rotary casting sand reclaimer described in detail in Fig. 2-4 , in which sand purified from resin residues and resistant to thermal expansion is obtained.
sand is given as raw material for the production of cores at the station 103 and moulds for castings requiring higher precision workmanship.
Fig. 2-4 present the third level reclaimer operated at the station 106, with round base 1, grain hole 2 and grain hole lock 3, connected with cylindrical casing 4 of the abrasive ring 5 with profiled internal surface and cylindrical external surface and a rotor with abrasive elements 6 located concentrically to the abrasive ring in the base, and connected with a driving motor 7 by means of belt transmission 8 installed in the base of the device 1.
a ring air blade 9 is installed, connected with dedusting chamber casing 10 equipped with a waste casting sand batch hole 11, side revision window 12 and the ending 13 of telescopic dedusting duct 14, located in the chamber axis.
the dedusting duct 14 has sensors measuring air velocity, and a triboelectric dust counter 15. Beyond the duct 14, a triboelectric sensor (15) signal converter 16 is installed.
the dedusting unit contains also: dedusting cyclone 17 and suction fan 18.
Casting sand for the reclamation is supplied through the waste casting sand batch hole 11 into the dedusting chamber 10, then it falls into the abrasive ring 5, where it undergoes reclamation processing using the rotor with abrasive elements 6 located on the side walls of a two-piece head with square cross-section, driven by driving motor 7 through belt transmission 8, at a rotational speed controlled by the motor rotational speed controller 19 according to processed signals in electronic system 16 with sensors 15 located in the duct 14.
the waste casting sand is subject to dynamic impact of abrasive elements 6 of the rotor unit, installed horizontally in vertical walls of the two-piece square head in at least 2 rows. At least two rotor arms are installed (with screws) in each row on the opposite, external walls of the head, one above the other. At the end of each arm, at the side of the abrasive ring, one vertical abrasive disc is installed; the external profile edge of the disc is located 5-10 mm from the shaped surface of the abrasive ring (at this altitude) and tilted reversely to the direction of its movement by approx. 15-20 degrees in relation to the plane crossing both arms of a given rotor row.
the rotor arms in the upper part of the square head are situated analogically to the above, with arm units and the head turned by 90 degrees in relation to those in the bottom row.
Spaces between arms in a given pair and between the arm rows are the same and their length and similar to the height of elements comprising a given pair of rotor arms (blades, round or square rods).
the spaces between the rows may be of double length of the rods or blades.
Waste casting sand poured into the device is set in motion using rotary arms of the rotor unit and the portion which has not been pushed through the spaces between the arms and rows of the rotor is radially forced to the external surface of the abrasive ring, where it is dropped at high perimeter speed to the internal surface of the abrasive ring 5 with a profile of logarithmic spiral recoiling from the top.
Intensive movement of casting sand facilitates purifying the sand grains by wiping and abrading of the shells of waste binding material.
the stream of processed sand is wound by a curvature on the top surface of the abrasive ring 5 in the direction of the rotor axis and pours down to the bottom where it is again processed by the rotor with abrasive elements. 6.
the preferable height of the abrasive ring with profiled recess equals 0.3 - 0.4 of the diameter designated by the outer cover of the ring, 2-3 times bigger than the distance between the upper arms of the rotor unit's uppermost abrasive elements and the bottom of the bowl.
the purified sand grains is removed from the reclaimer through the grain hole to one of the receivers.
Dusty air is sucked out through the dedusting duct 14 with sensors measuring air velocity and a triboelectric dust counter to the dedusting cyclone 17 with dust reception system and then to the suction fan 18.
the electronic system measuring dust generated in the reclamation process and gas flow velocity in the dedusting unit has two, independent measuring tracks.
Measure converters use the method of measuring the volume and speed of dust by converting electric current generated from colliding and rubbing of measuring probes on the particles of dust transported in the dedusting duct.
Fig. 5 presents a change of TrueRMS value during a sample monitoring of dust concentration in the reclaimer dedusting unit, using triboelectric dust counter.
Signal value decrease is a result of dust volume decrease in the dedusting chamber, from which it was collected. It is clearly visible that at the beginning of the measuring process a large volume of dust substance is transported, its value is decreased at the final stage of the process, when the volume of binding material is reduced due to its abrading off of the grain surface.
the measurement is performed at single air speed for the dust flowing in the dedusting duct.
Monitoring of speed also helps to determine useful data, such as dust concentration in the gas during transport, which constitute the basis of automatically initiated change of the driving motor rotational speed when a reduction of the growing volume of dust, generated in a given sand grain processing cycle, contained within the air stream is indicated by the measuring system of the triboelectric dust counter. Tracking the dynamics of changes in the volume of liquids in the air stream and comparing them with the set course of the process by the measuring system facilitates the differentiation of the intensity of impact on the reclaimed sand grains in a given cycle, through automatic change of the driving motor's rotary speed.
the device and method according to this invention allow to generate castings with improved functionality.
Fig. 6A presenting test casting of a wedge according to norm ASTM A 536-84 in a mould made of moulding sand from a second level reclaim
Fig. 6B presenting test casting of a wedge produced according to the invention method.
the application of the invention method allows to obtain castings of CT 7 tolerance grade, according to norm PN -58M-04251 (for which the tolerance equals 0,78mm).
Products obtained using the invention method have low surface coarseness, with Ra parameter measured according to norm PN-EN ISO 1302:2002 at a level below 25.
the ignition loss of the moulding sand after third level reclamation is below 0.6%, which allows to obtain moulds with high durability, low friability, high level of sand grains uniformity and low gas excretion.
the gas excretion of the moulding sand after third level reclamation is above 20cm 3 /g, which allows for significant reduction of faulty castings, to approx. 1% of their total number.

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Engineering & Computer Science (AREA)
Mechanical Engineering (AREA)
Mold Materials And Core Materials (AREA)
Molds, Cores, And Manufacturing Methods Thereof (AREA)

EP12181760.5A 2012-06-19 2012-08-24 Régénération de sable à moulage rotatif mécanique et procédé de fabrication des moulages à partir de sable de fonderie régénéré Withdrawn EP2676748A3 (fr)

Applications Claiming Priority (1)

Application Number	Priority Date	Filing Date	Title
PL399560A PL223318B1 (pl)	2012-06-19	2012-06-19	Mechaniczny regenerator wirnikowy zużytej masy odlewniczej

Publications (2)

Publication Number	Publication Date
EP2676748A2 true EP2676748A2 (fr)	2013-12-25
EP2676748A3 EP2676748A3 (fr)	2017-10-25

Family

ID=46940257

Family Applications (1)

Application Number	Title	Priority Date	Filing Date
EP12181760.5A Withdrawn EP2676748A3 (fr)	2012-06-19	2012-08-24	Régénération de sable à moulage rotatif mécanique et procédé de fabrication des moulages à partir de sable de fonderie régénéré

Country Status (2)

Country	Link
EP (1)	EP2676748A3 (fr)
PL (1)	PL223318B1 (fr)

Cited By (4)

* Cited by examiner, † Cited by third party
Publication number	Priority date	Publication date	Assignee	Title
CN106077507A (zh) *	2016-08-31	2016-11-09	山东泰开精密铸造有限公司	一种汽车水冷电机壳铸件的铸造模及铸造工艺
CN106891262A (zh) *	2017-04-27	2017-06-27	河南工程学院	一种除尘式圆管外壁喷砂除锈装置
CN113042677A (zh) *	2021-03-03	2021-06-29	王小平	一种铸造混砂机吸尘用自动添加剂注入装置
CN119702951A (zh) *	2025-02-27	2025-03-28	河南省金太阳精密铸业股份有限公司	一种铸造用呋喃树脂再生砂回收装置

Citations (1)

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DE4212097A1 (de)	1992-04-10	1993-10-14	Boenisch Dietmar	Verfahren und Vorrichtung zum Regenerieren von Giessereisand

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JPH06170486A (ja) *	1992-11-30	1994-06-21	Hitachi Metals Ltd	鋳物砂の再生装置及びその再生方法
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2012
- 2012-06-19 PL PL399560A patent/PL223318B1/pl unknown
- 2012-08-24 EP EP12181760.5A patent/EP2676748A3/fr not_active Withdrawn

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US5439044A (en)	1992-04-10	1995-08-08	Boenisch; Dietmar	Method of regenerating foundry sand

Cited By (5)

* Cited by examiner, † Cited by third party
Publication number	Priority date	Publication date	Assignee	Title
CN106077507A (zh) *	2016-08-31	2016-11-09	山东泰开精密铸造有限公司	一种汽车水冷电机壳铸件的铸造模及铸造工艺
CN106891262A (zh) *	2017-04-27	2017-06-27	河南工程学院	一种除尘式圆管外壁喷砂除锈装置
CN106891262B (zh) *	2017-04-27	2023-02-28	河南工程学院	一种除尘式圆管外壁喷砂除锈装置
CN113042677A (zh) *	2021-03-03	2021-06-29	王小平	一种铸造混砂机吸尘用自动添加剂注入装置
CN119702951A (zh) *	2025-02-27	2025-03-28	河南省金太阳精密铸业股份有限公司	一种铸造用呋喃树脂再生砂回收装置

Also Published As

Publication number	Publication date
PL223318B1 (pl)	2016-10-31
PL399560A1 (pl)	2013-12-23
EP2676748A3 (fr)	2017-10-25

Publication	Publication Date	Title
EP2676748A2 (fr)	2013-12-25	Régénération de sable à moulage rotatif mécanique et procédé de fabrication des moulages à partir de sable de fonderie régénéré
US20180133719A1 (en)	2018-05-17	Molding sand reclamation method and reclamation equipment
CN108163581B (zh)	2020-06-12	一种自动输送系统
EP3363558A1 (fr)	2018-08-22	Procédé de régénération de sable de moulage et système de régénération
US6572262B1 (en)	2003-06-03	Densifying of a bulk particulate material
SU841573A3 (ru)	1981-06-23	Установка дл центробежного лить ТРубНыХ издЕлий
JP6079729B2 (ja)	2017-02-15	焼結原料造粒物の製造方法および製造設備
TWI643700B (zh)	2018-12-11	Cartridge grinding medium and manufacturing method thereof
US4267866A (en)	1981-05-19	Method and machine for filling a capsule with powder
EP3164234B1 (fr)	2019-09-11	Procédé de récupération de sable de fonderie utilisé et équipement pour sa mise en uvre
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JP2015188788A (ja)	2015-11-02	造粒物の粒度・標準偏差の推定方法及び造粒プロセスの制御方法
JP2011092991A (ja)	2011-05-12	鋳物砂、及びその製造方法、並びにその鋳物砂を使用した鋳型
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CN217166399U (zh)	2022-08-12	一种盘体铸件内芯制作装置
JP2010000521A (ja)	2010-01-07	精密鋳造用鋳型製造のためのバックアップスタッコ材及びその製造方法並びにそれを用いて得られた精密鋳造用鋳型
CN112278622A (zh)	2021-01-29	称砂料斗
Dereń et al.	2017	Influence of reclamation process on the ecological quality of reclaim sand
US3082737A (en)	1963-03-26	Dusting apparatus
US12042801B2 (en)	2024-07-23	Recycling waste refractory material
JPH08216146A (ja)	1996-08-27	セラミックススラリーの真空脱泡装置

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