CN209409268U - A kind of polymer foaming processing cooling cylinder of extruder - Google Patents
A kind of polymer foaming processing cooling cylinder of extruder Download PDFInfo
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- CN209409268U CN209409268U CN201822242085.0U CN201822242085U CN209409268U CN 209409268 U CN209409268 U CN 209409268U CN 201822242085 U CN201822242085 U CN 201822242085U CN 209409268 U CN209409268 U CN 209409268U
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Abstract
The utility model relates to a kind of cooling cylinders of polymer foaming processing extruder, the cylinder includes several cooling unit sections, the cylinder each unit section includes the inner cylinder and outer cylinder mutually to socket-connect, spiral shape coolant flow channel is equipped with along inner cylinder length direction on the inner cylinder outer surface, distance is 0.02Di-0.15Di between the coolant flow channel bottom surface and interior tube inner surface, wherein Di is the interior diameter of inner cylinder, and the outer barrel both ends are respectively equipped with the inlet pipe communicated with coolant flow channel and outlet pipe.When cooling, cooling medium is entered in coolant flow channel by inlet pipe, after coolant flow channel, is flowed out out of outlet pipe, and cooling medium walks the heat displacement of inner cylinder internal high temperature polymer melt, realizes the cooling of material.Compared to the common coolant flow channel of integral coating formula or the coolant flow channel of longitudinal aperture, material is cooled down using the spiral coolant flow channel, cooling medium and inner cylinder inner surface distance are smaller, and temperature gradient is bigger, can greatly improve cooling efficiency and greatly improve amount of cooling water.
Description
Technical field
The utility model relates to a kind of extrusion machineries, more particularly, to a kind of cooling of polymer foaming processing extruder
Cylinder.
Background technique
Extruder is widely used in plastic processing, and wherein polymer foaming processed and applied is also more and more common.Polymerization
Object foaming product is mainly used in packaging, building heat preservation, buffering etc..
It is squeezed out in processing in almost all of polymer foaming, polymer material must be melted first, be added thereafter
Foaming agent, and melt mixed and material cooling procedure are carried out, allow abscess in polymer material foaming process to remain stable.
In general, polymer-melt temperature is 160-290 degrees Celsius, and the melt temperature needed before foaming is usually 60-220 degree.This
Technological temperature is different because of polymer material difference, for example common polystyrene material, melt temperature are that 180-230 is Celsius
Degree, the temperature for the needs that foam is usually 105-120 degrees Celsius.This process wherein needs to displace a large amount of heat.How to design
The cooling extruded machine of effective melt is manufactured, it is very crucial for foaming process to improve the ring thermal efficiency.
Notification number provides a kind of screw extruder cylinder cooling device for the utility model of CN 105563794A.The reality
It is disclosed a kind of screw rod drum cooling device with novel and with the extruder of the device, is belonged to field, it is desirable to provide Yi Zhongneng
Enough uniformly to reduce the screw rod drum cooling device of temperature and the extruder with the device in barrel, its technical solution is as follows, and one
Kind of screw rod drum cooling device, the mounting flange including screw rod cylinder, screw rod cylinder both ends are set in the wall of the screw rod cylinder
Be equipped with it is several through screw rod cylinder both ends and first coolant flow channel and second coolant flow channel parallel with screw rod tubular axis, it is described
It is provided with the water channel cover board for preventing circulation medium from leaking on first circulation groove and the second circulation groove, first coolant flow channel,
Second coolant flow channel forms cooling cycle runner, the cooling cycle runner by the setting of the first circulation groove, the second circulation groove
Four groups and circumference array are set as on screw rod cylinder, is respectively arranged on the screw rod cylinder and cooling cycle runner head and the tail
The input hole and delivery outlet of connection.
Cooling structure in the utility model improves the cooling efficiency of common foaming processing extruder, but overall
Film-cooled heat is little and processing technology is complex, still remains the space of optimization efficiency.
Utility model content
The purpose of the utility model is to provide a kind of cooling cylinders of polymer foaming processing extruder, can be effective
Improve the cooling efficiency of cooling cylinder.
The above-mentioned purpose of utility model of the utility model has the technical scheme that a kind of polymer hair
The cooling cylinder of processing extruder is steeped, including several sequentially connected cooling unit sections, the cooling unit section include
Cylinder, the cylinder include the inner cylinder and outer cylinder mutually to socket-connect, are equipped with spiral shell along inner cylinder length direction on the inner cylinder outer surface
Shape coolant flow channel is revolved, the outer barrel both ends are respectively equipped with the inlet pipe communicated with coolant flow channel and outlet pipe.
By using above-mentioned technical proposal, when cooling, cooling medium is entered in coolant flow channel by inlet pipe, through supercooling stream
It behind road, is flowed out out of outlet pipe, cooling medium walks the heat displacement of inner cylinder internal high temperature polymer melt, realizes the cold of material
But.Compared to the common cooling cavity structure of integral coating formula or the cooling cavity structure of longitudinal aperture, using the coolant flow channel
Material is cooled down, cooling medium and inner cylinder inner surface distance are smaller, and temperature gradient is bigger, can greatly improve cooling effect
Rate.
The utility model is further arranged to: the inner surface of each cooling unit section coolant flow channel bottom surface and inner cylinder it
Between distance Hb range be 0.02Di-0.15Di, wherein Di be inner cylinder interior diameter.
By using above-mentioned technical proposal, coolant flow channel bottom surface and interior tube inner surface are arranged within the above range, it can
Enough guarantee heat transfer efficiencies as high as possible, while can guarantee the necessary structural strength of inner cylinder again, the pressure resistance of inner cylinder and anti-
Bending etc. mechanical properties can be guaranteed, processing and using when inner cylinder service life be unaffected.
The utility model is further arranged to: each cooling unit section coolant flow channel depth capacity Hc range is 5-
40mm, the inner cylinder internal diameter Di that the lead of the coolant flow channel is 0.1-100 times.
By using above-mentioned technical proposal, the depth of coolant flow channel determines the flow of cooling medium, by the depth of coolant flow channel
Degree is arranged in above range, can not only guarantee that the flow of cooling medium can satisfy using needs, cooling medium can be taken away
Enough heats improve cooling efficiency, while also can ensure that the structural strength of inner cylinder, guarantee reliability when using, this
Outside, the lead of coolant flow channel decides on same axis direction, the length of coolant flow channel, will be in coolant flow channel length and inner cylinder
The corresponding setting of diameter, not only facilitates processing, guarantees that the length of coolant flow channel can satisfy cooling requirement, and can reduce internally
The influence of barrel structure intensity.
The utility model is further arranged to: each cooling unit section coolant flow channel cross sectional shape is inverted isosceles
Trapezoidal or rectangle or circular curve shape, adjacent channels rib upper bottom edge width L range is 1- on the axial cross section of the inner cylinder
30mm。
By using above-mentioned technical proposal, the circulation area in the section of coolant flow channel can be increased as far as possible in this way, increased cold
But the circulation of medium, while heat exchange area is improved, improve the amount of cooling water and cooling efficiency of product in inner cylinder.
The utility model is further arranged to: each cooling unit section inner cylinder external surface coolant flow channel item number is 1-
32, each coolant flow channel is sequentially distributed along inner cylinder circumferencial direction.
By using above-mentioned technical proposal, coolant flow channel is arranged to multiple, can not only guarantee coolant flow channel in inner cylinder
On distribution density, while the length of single coolant flow channel can be reduced, facilitate processing, and can to avoid coolant flow channel because
Length is too long, leads to the increase of cooling medium flow resistance, while can also reduce what coolant flow channel occurred blocking when in use
Probability, also, even if a coolant flow channel blocks, other coolant flow channels still can be used normally, to the production in inner cylinder
Product are cooled down, and the reliability of cooling procedure is greatly improved.
The utility model is further arranged to: the inside diameter ranges of the inner cylinder of each cooling unit section are 90-600mm.
By using above-mentioned technical proposal, the inner cylinder in the inside diameter ranges can satisfy big portion with remaining parameter coordination
The extrusion output for dividing polymer foaming process to need.
The utility model is further arranged to: the cylinder is made of a cooling unit section, the cooling unit area
Inner cylinder quantity is one in section, and outer cylinder is several, and the outer cylinder is sequentially sleeved at outside inner cylinder along inner cylinder length direction.
By using above-mentioned technical proposal, successively it is sleeved on using one or several outer cylinders along inner cylinder length direction
The form of inner cylinder, forms the cooling cylinder of several units, and the formation one that is mechanically linked is complete squeezes out cylinder, in this way can be with
Realize the cooling barrel unit of big L/D ratio.It is using whole inner cylinder and is alongst successively being set with several cooling outer cylinders
Mode can improve reliability and reduce processing cost to avoid mechanical link structure is used.
The utility model is further arranged to: the cylinder is made of at least two cooling unit sections, each cooling single
Inner cylinder and outer cylinder quantity are one in first section.
By using above-mentioned technical proposal, it can be installed and be fixed by ring flange between adjacent cooling unit section, cylinder
Installation and disassembly it is very convenient.
The utility model is further arranged to: each cooling unit section length is 0.5-20 times of inner cylinder internal diameter Di,
The proportional region of cooling cylinder total length and inner cylinder internal diameter is 10-60.
By using above-mentioned technical proposal, by the control of unit cooling section in the range, it can be ensured that unit is cooling
The reasonable flow passage resistance force of waterproof of section reduces the temperature difference for entering and leaving medium so that it is guaranteed that cooling medium consumption, improves cooling efficiency, it is ensured that
Each cooling section cell temperature distributing homogeneity.Cooling cylinder total length controls within the above range, it is ensured that all coolings
Total amount of cooling water in section reaches the requirement of the total treating capacity of extruder.
The utility model is further arranged to: each cooling unit section inner cylinder and outer cylinder are by nitrated steel or medium carbon steel
It is made, the inner cylinder inner wall is equipped with bimetallic alloy layer, the inner cylinder and outer cylinder and is fixed by welding or interference fit.
By using above-mentioned technical proposal, inner cylinder and housing are made of nitrated steel or medium carbon steel, it is ensured that inner cylinder with
And the structural strength and thermal conductivity of outer cylinder, while may insure similar thermal expansion coefficient, avoid high temperature or low temperature from causing
Thermal stress-cracking.Inner cylinder and housing may insure the transmitting and cooling medium of mechanical torque using welding or interference fit connection
Sealing.The service life that double-metal layer extends inner cylinder can be set in interior tube inner surface.
In conclusion the advantageous effects of the utility model are as follows:
1. being arranged using spiral coolant flow channel and by the distance between coolant flow channel bottom surface and interior tube inner surface reasonable
In range, cooling efficiency and amount of cooling water can be effectively promoted in the case where guaranteeing sufficient mechanical strength;
2. using modular unit cooling section combining form or increase mention inner sleeve be once set with the forms of several housings can
To obtain the sufficiently long cooling cylinder needed.
Detailed description of the invention
Fig. 1 is the outer cylinder schematic cross-sectional view of the utility model.
Fig. 2 is the inner tube structure schematic diagram one of the utility model.
Fig. 3 is the outer tube structure schematic diagram of the utility model.
Fig. 4 is the inner tube structure schematic diagram two of the utility model.
Fig. 5 is the cooling cylinder schematic diagram of monoblock type.
Fig. 6 is the cooling cylinder schematic diagram of combined type.
In figure, 1, inner cylinder;2, outer cylinder;21, inlet pipe;22, outlet pipe;3, coolant flow channel.
Specific embodiment
The utility model is described in further detail below in conjunction with attached drawing 1-6.
Referring to Fig.1 and Fig. 2, the cooling cylinder of extruder is used for a kind of polymer foaming processing disclosed by the utility model
Body, including the cooling cylinder of combined type and the cooling cylinder of monoblock type, cylinder includes several sequentially connected cooling unit sections, can be with
Only be arranged a cooling unit section, also can be set it is multiple, according to the actual situation select fair amount cooling unit section
Spliced, each cooling unit section includes inner cylinder 1 and outer cylinder 2, is interference fitted between 2 internal diameter of 1 outer diameter of inner cylinder and outer cylinder
Or small―gap suture cooperation, an entirety can also be connected into using welding manner between inner cylinder 1 and outer cylinder 2.When inner cylinder 1 and outer cylinder
When 2 interference fit, the installation of inner cylinder 1 Yu outer cylinder 2 is realized using hot jacket mode.For the structural strength for guaranteeing inner cylinder 1 and outer cylinder 2
And heating conduction, the material of inner cylinder 1 and outer cylinder 2 is nitrated steel or medium carbon steel, for the corrosion resistance for improving 1 inner wall of inner cylinder
Can, extend inner cylinder 1 service life, on 1 inner wall of inner cylinder be equipped with bimetallic alloy layer, bimetallic alloy layer with a thickness of 2mm.
Referring to Fig. 2 and Fig. 3, it is equipped with spiral shape coolant flow channel 3 along 1 length direction of inner cylinder on the outer surface of inner cylinder 1,
Outer cylinder 2 is equipped with inlet pipe 21 and outlet pipe 22, inlet pipe 21 and outlet pipe 22 respectively with helical flow path two corresponding in coolant flow channel 3
End communicates, and can also be mutually communicated in each helical flow path starting point at both ends and outlet end to reduce inlet/outlet pipe quantity.It is cooling
When, cooling medium is entered in coolant flow channel 3 by inlet pipe 21, after coolant flow channel 3, is flowed out out of outlet pipe 22, cooling medium
The heat of 1 internal product of inner cylinder is taken away, realizes the cooling of high temperature polymer, in the present embodiment, cooling medium can be high temperature
Conduction oil or other runny nose media, converted products can be PP, PS or other high molecular materials.
Referring to Fig. 2 and Fig. 3, the section of coolant flow channel 3 can be trapezoidal, rectangle or semicircle or other curves, be
Facilitate processing, in the present embodiment, the cross sectional shape of coolant flow channel 3 is isosceles trapezoid, and the section of coolant flow channel 3 is set in open
It sets, i.e., the single section of coolant flow channel 3 is inverted isosceles trapezoid, on the axial cross section of inner cylinder 1, adjacent 3 phase of coolant flow channel
The upper bottom edge length range of isosceles trapezoid between adjacent notch is 1-30mm, can increase cutting for coolant flow channel 3 as far as possible in this way
The area in face increases the circulation of cooling medium, improves the cooling efficiency of product in inner cylinder 1.
Referring to Fig. 2 and Fig. 3, to further increase cooling efficiency, while guaranteeing the reliability of cooling procedure, is located at same
3 numbers of coolant flow channel on inner cylinder 1 are 1-32, and each coolant flow channel 3 is sequentially distributed along 1 circumferencial direction of inner cylinder, correspondingly,
Inlet pipe 21 and outlet pipe 22 on outer cylinder 2 are correspondingly arranged with the item number of coolant flow channel 3, each coolant flow channel 3, corresponding one into
Pipe 21 and outlet pipe 22.Coolant flow channel 3 is arranged to multiple, can not only guarantee that distribution of the coolant flow channel 3 on inner cylinder 1 is close
Degree, while the length of single coolant flow channel 3 can be reduced, facilitate processing, and can be to avoid coolant flow channel 3 because length is spent
It is long, cause fluid resistance in inlet pipe 21 to increase, while coolant flow channel 3 can also be reduced and occur the probability blocked when in use, and
And even if a coolant flow channel 3 blocks, other coolant flow channels 3 still be can be used normally, to the product in inner cylinder 1 into
Row cooling, greatly improves the reliability of cooling procedure.
In addition, in order to further facilitate installation, cylinder can be at least two cooling unit section and successively splice referring to Fig. 6
It forms, each cooling unit section includes an outer cylinder 2 and an inner cylinder 1, and adjacent 2 end of outer cylinder is fixed using ring flange
Connection, this is the cooling cylinder of combined type;Referring to Fig. 5, cooling cylinder can also be only made of a cooling unit section, the cooling list
First section includes the outer cylinder 2 that an inner cylinder 1 is located at outside inner cylinder 1, and outer cylinder 2 is several, and outer cylinder 2 is sequentially sleeved at outside inner cylinder 1,
It is fixed on inner cylinder 1 between adjacent outer cylinder 2 using welding form, this structure is referred to as the cooling cylinder of monoblock type, at this point, inside
Coolant flow channel 3 on cylinder 1 is not only multiple in the setting of 1 circumferential direction array of inner cylinder, can also be arranged in 1 length direction array of inner cylinder
Multiple groups coolant flow channel 3.Referring to Fig. 2 and Fig. 3, in the present embodiment, a cooling unit section length is the 0.5- of 1 internal diameter of inner cylinder
50 times, cooling cylinder total length is 10-60 times of 1 internal diameter Di of inner cylinder, by cooling unit section and the control of cooling cylinder length upper
It states inside range, it can be ensured that the reasonable flow passage resistance force of waterproof of unit cooling section, so that it is guaranteed that cooling medium consumption, improves cooling effect
Rate reduces the temperature difference for entering and leaving medium, it is ensured that each cooling section cell temperature distributing homogeneity.Cooling cylinder total length is controlled upper
It states in range, it is ensured that total amount of cooling water in all cooling sections reaches the requirement of the total treating capacity of extruder.
To guarantee cooling efficiency, in this implementation, 3 bottom surface of coolant flow channel is with the distance between the inner surface of inner cylinder 1 range
0.02Di-0.15Di, Di are the interior diameter of inner cylinder 1, i.e. the distance between 1 internal diameter Di of inner cylinder and 3 basal diameter diameter of coolant flow channel
Difference can be derived from Fourier law, and when encountering single layer planar wall, heat transfer form is to stablize heat transfer at this time,
Assuming that the single layer planar wall for having the area of a homogeneous very big, with a thickness of b, the temperature in planomural is only along the x-axis side perpendicular to wall surface
To variation, in steady heat conduction, heat conduction rate Q is not changed over time, and heat transfer area A and thermal coefficient λ are also constant,
Then Fourier formula can simplify are as follows:
It is rewritten into the general type of rate of heat transfer equation, then is had:
In formula: b----- planar wall thickness, unit: m;
△ t----- planomural two sides temperature difference, i.e., thermally conductive motive force, unit: K;
R=b/ λ A------ thermal conduction resistance, unit: K/W.
This formula explanation, the heat conduction rate of single layer planar wall is directly proportional to motive force △ t, is inversely proportional with thermal resistance.It is applied to this
In embodiment, 1 inner wall of inner cylinder and outside wall temperature it is constant in the case where, motive force △ t is steady state value;And 1 material of inner cylinder is certain,
1 thermal coefficient of inner cylinder is also certain value;In this way under identical heat-conducting area, the heat transfer efficiency Q of single layer planar wall, with single flat
The thickness faced the wall and meditated is inversely, that is to say, that the distance between thermally conductive runner bottom surface and 1 inner wall of inner cylinder are smaller, cooling cylinder
Heat transference efficiency is higher, and the cooling effect of product is also just best, in the present embodiment, the interior table of 3 bottom surface of coolant flow channel and inner cylinder 1
The distance between face range is 0.02Di-0.15Di, and 3 bottom surface of coolant flow channel and 1 inner surface of inner cylinder are arranged within the above range,
It can either guarantee heat transfer efficiency, while can guarantee the structural strength of inner cylinder 1 again, the mechanics such as the pressure resistance of inner cylinder 1 and bend resistance
Performance can be guaranteed, processing and using when inner cylinder 1 service life be unaffected.
Referring to Fig. 2 and Fig. 3,3 depth bounds of coolant flow channel are 5-30mm, and the depth of coolant flow channel 3 determines cooling medium
Flow, the depth of coolant flow channel 3 is arranged in above range, can not only guarantee that the flow of cooling medium can satisfy use
It needing, cooling medium can take away enough heats, cooling efficiency is improved, while also can ensure that the structural strength of inner cylinder 1,
Guarantee reliability when using.In the present embodiment, 1 internal diameter of inner cylinder that the lead of coolant flow channel 3 is 0.5-10 times, coolant flow channel 3
Lead decide that on same axis direction, the length of coolant flow channel 3 is corresponding with 1 internal diameter of inner cylinder by 3 length of coolant flow channel
Setting not only facilitates processing, guarantees that the length of coolant flow channel 3 can satisfy cooling requirement, and can reduce to 1 structure of inner cylinder
The influence of intensity.
Referring to Fig. 2 and Fig. 3, in order to further ensure the cooling efficiency of inner cylinder 1, the inside diameter ranges of inner cylinder 1 are arranged in 90-
600mm, the inner cylinder 1 in the inside diameter ranges can satisfy the extrusion output that most of polymer foaming process needs.
The implementation principle of the present embodiment are as follows: when cooling, cooling medium is entered in coolant flow channel 3 by inlet pipe 21, in cooling
In runner 3 after conveying, flowed out from the outlet pipe 22 of 3 other end of coolant flow channel, by between 1 inner wall of 3 bottom surface of coolant flow channel and inner cylinder
1 body of inner cylinder heat transfer, the heat of product inner cylinder 1 inside is taken away, final cooling medium from outlet pipe 22 export, cooling medium pass through
After supercooling, enters coolant flow channel 3 from inlet pipe 21 again, high temperature polymer is efficiently cooled down.
The embodiment of present embodiment is the preferred embodiment of the utility model, and not limitation is originally practical new according to this
The protection scope of type, therefore: the equivalence changes that all structures, shape, principle according to the utility model are done should all be covered by practical
Within novel protection scope.
Claims (10)
1. a kind of polymer foaming processing cooling cylinder of extruder, cylinder includes several sequentially connected cooling unit areas
Section, the cooling unit section includes cylinder, it is characterised in that: the cylinder includes the inner cylinder (1) and outer cylinder mutually to socket-connect
(2), spiral shape coolant flow channel (3) are equipped with along inner cylinder (1) length direction on inner cylinder (1) outer surface, outer cylinder (2) body two
End is respectively equipped with the inlet pipe (21) communicated with coolant flow channel (3) and outlet pipe (22).
2. the cooling cylinder that extruder is used in a kind of polymer foaming processing according to claim 1, it is characterised in that: each institute
Stating distance Hb range between cooling unit section coolant flow channel (3) bottom surface and the inner surface of inner cylinder (1) is 0.02Di-0.15Di,
Wherein Di is the interior diameter of inner cylinder (1).
3. the cooling cylinder that extruder is used in a kind of polymer foaming processing according to claim 2, it is characterised in that: each institute
Stating cooling unit section coolant flow channel (3) depth capacity Hc range is 5-40mm, and the lead of the coolant flow channel (3) is 0.1-
100 times inner cylinder (1) internal diameter Di.
4. the cooling cylinder that extruder is used in a kind of polymer foaming processing according to claim 3, it is characterised in that: each institute
Stating cooling unit section coolant flow channel (3) cross sectional shape is inverted isosceles trapezoid or rectangle or circular curve shape, described
Adjacent channels rib upper bottom edge width L range is 1-30mm on the axial cross section of inner cylinder (1).
5. a kind of polymer foaming processing according to claim 1 or 2 or 3 or 4 cooling cylinder of extruder, feature
Be: each cooling unit section inner cylinder (1) external surface coolant flow channel (3) item number is 1-32, each coolant flow channel (3)
Along inner cylinder (1), circumferencial direction is sequentially distributed.
6. the cooling cylinder that extruder is used in a kind of polymer foaming processing according to claim 5, it is characterised in that: each institute
The inside diameter ranges for stating the inner cylinder (1) of cooling unit section are 90-600mm.
7. the cooling cylinder that extruder is used in a kind of polymer foaming processing according to claim 1, it is characterised in that: described
Cylinder is made of a cooling unit section, and inner cylinder (1) quantity is one in the cooling unit section, and outer cylinder (2) is several
A, the outer cylinder (2) is sequentially sleeved at inner cylinder (1) outside along inner cylinder (1) length direction.
8. the cooling cylinder that extruder is used in a kind of polymer foaming processing according to claim 1, it is characterised in that: described
Cylinder is made of at least two cooling unit sections, and inner cylinder (1) and outer cylinder (2) quantity are one in each cooling unit section
It is a.
9. the cooling cylinder that extruder is used in a kind of polymer foaming processing according to claim 7 or 8, it is characterised in that:
Each cooling unit section length is 0.5-20 times of inner cylinder (1) internal diameter Di, the ratio of cooling cylinder total length and inner cylinder (1) internal diameter
Example range is 10-60.
10. the cooling cylinder that extruder is used in a kind of polymer foaming processing according to claim 1, it is characterised in that: each
The cooling unit section inner cylinder (1) and outer cylinder (2) are made of nitrated steel or medium carbon steel, and inner cylinder (1) inner wall is equipped with double
Metal alloy layer, the inner cylinder (1) and outer cylinder (2) are fixed by welding or interference fit.
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Cited By (1)
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CN109605712A (en) * | 2018-12-28 | 2019-04-12 | 南京越升挤出机械有限公司 | A kind of polymer foaming processing cooling cylinder of extruder |
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Publication number | Priority date | Publication date | Assignee | Title |
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CN109605712A (en) * | 2018-12-28 | 2019-04-12 | 南京越升挤出机械有限公司 | A kind of polymer foaming processing cooling cylinder of extruder |
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Address after: 211100 No. 31, Yuantai Road, Dongshan street, Jiangning District, Nanjing City, Jiangsu Province Patentee after: Jiangsu Yuesheng Technology Co.,Ltd. Address before: 211100 Dongshan Street Industrial Zone, Jiangning District, Nanjing, Jiangsu Patentee before: Useon (Nanjing) Extrusion Machinery Co.,Ltd. |