CN204505810U - Improve the device of crystallizer bottleneck cooling production efficiency - Google Patents
Improve the device of crystallizer bottleneck cooling production efficiency Download PDFInfo
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- CN204505810U CN204505810U CN201420873301.0U CN201420873301U CN204505810U CN 204505810 U CN204505810 U CN 204505810U CN 201420873301 U CN201420873301 U CN 201420873301U CN 204505810 U CN204505810 U CN 204505810U
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Abstract
The utility model discloses a kind of device improving crystallizer bottleneck cooling production efficiency, comprise cooling rotary plate, multiple refrigerating head assembly, insert embryo lobe plate, carry embryo lobe plate, de-embryo lobe plate, crystallization chain is provided with protective sleeve, bottle embryo is arranged in protective sleeve, and bottle preform mouth exposes to protective sleeve, refrigerating head assembly is arranged on cooling rotary plate, and refrigerating head assembly is arranged on the top of protective sleeve, refrigerating head assembly comprises upper mounting plate and lower installation board, cooling axis body, the axis of guide, upper mounting plate is provided with upper roller, lower installation board is provided with bottom roller, insert embryo lobe plate, carry embryo lobe plate, de-embryo lobe plate is installed in the rotate path of refrigerating head assembly, de-embryo lobe plate is arranged on the downstream carrying embryo lobe plate, insert the top that embryo lobe plate is positioned at upper roller, carry the below that embryo lobe plate is positioned at bottom roller, de-embryo lobe plate is between upper roller and bottom roller.It can make crystallizer bottleneck cool production efficiency raising.
Description
Technical field
The utility model relates to crystallizer technology, particularly a kind of device improving crystallizer bottleneck cooling production efficiency.
Background technology
Traditional crystallizer cools the mode of bottleneck employing as shown in Figure 1: start to insert the cooling of bottle embryo at A place refrigerating head, be rotated counterclockwise to the insertion of B place and put in place, be rotated counterclockwise to starting during C place to transfer to bottle embryo, put in place to the dial-out of D place, terminate cooling, its shortcoming is under cooling certain condition of single bottle preform mouth time, and whole piece crystallizer cooling bottleneck production efficiency is relatively low.
Summary of the invention
Based on this, be necessary the defect for prior art, a kind of device improving crystallizer bottleneck cooling production efficiency is provided.
A kind of device improving crystallizer bottleneck cooling production efficiency, comprise cooling rotary plate, multiple refrigerating head assembly, insert embryo lobe plate, carry embryo lobe plate, de-embryo lobe plate, the crystallization chain of crystallizer is arranged along the periphery of cooling rotary plate, crystallization chain is provided with protective sleeve, bottle embryo is arranged in protective sleeve, and bottle preform mouth exposes to protective sleeve, multiple refrigerating head assembly is arranged on cooling rotary plate centered by the axial line of cooling rotary plate, and refrigerating head assembly is arranged on the top of protective sleeve, described refrigerating head assembly comprises upper mounting plate and the lower installation board of stacked on top of one another setting, cooling axis body, the axis of guide be connected with cooling rotary plate, the axis of guide is successively through upper mounting plate, lower installation board, dottle pin is provided with between upper mounting plate and lower installation board, cooling axis body is fixed on upper mounting plate, and the spindle nose of cooling axis body exposes through lower installation board, upper mounting plate at least one side parallel with the tangential direction of cooling rotary plate is provided with upper roller, the side of lower installation board and described upper roller the same side is provided with bottom roller, described slotting embryo lobe plate, carry embryo lobe plate, de-embryo lobe plate is installed in the rotate path of refrigerating head assembly, insert embryo lobe plate and be arranged on the porch that crystallization chain enters cooling rotary plate, carry embryo lobe plate and be arranged on the exit that crystallization chain lays out cooling rotary plate, with described porch for starting point, direction of rotation along cooling rotary plate rotates, described de-embryo lobe plate is arranged on the downstream carrying embryo lobe plate, insert the top that embryo lobe plate is positioned at upper roller, carry the below that embryo lobe plate is positioned at bottom roller, de-embryo lobe plate is between upper roller and bottom roller.
Its further technical scheme is as follows:
Described de-embryo lobe plate is arranged near described slotting embryo lobe plate.
Described refrigerating head assembly also comprises straight line axle sleeve, lower straight line axle sleeve, described upper straight line axle sleeve, lower straight line axle sleeve are all enclosed within the axis of guide, described dottle pin is arranged between straight line axle sleeve and lower straight line axle sleeve, described upper mounting plate is enclosed within linear axis and puts, and lower installation board is enclosed within lower linear axis and puts.
Described refrigerating head assembly also comprises material returned ring, described material returned ring set cooling axis body spindle nose on and be fixed on lower installation board.
The device of described raising crystallizer bottleneck cooling production efficiency also comprises de-embryo guide rail, and described de-embryo guide rail correspondence is arranged on the below of de-embryo lobe plate, forms the guide-track groove holding bottom roller between the lower surface of de-embryo lobe plate and the upper surface of de-embryo guide rail.
Along the direction of rotation of cooling rotary plate, the lower surface of described slotting embryo lobe plate in downward trend gradually, described in carry the upper surface of embryo lobe plate in the trend risen gradually, the upper surface of described de-embryo lobe plate is in the trend risen gradually.
The two sides that described upper mounting plate is parallel with the tangential direction of cooling rotary plate are equipped with upper roller, the two sides that lower installation board is parallel with the tangential direction of cooling rotary plate are equipped with bottom roller 260, and the top of two upper rollers is equipped with one block of described slotting embryo lobe plate, the below of two bottom rollers is equipped with described in one piece carries embryo lobe plate, is equipped with one block of described de-embryo lobe plate between the upper roller of the same side and bottom roller.
Improve a method for crystallizer bottleneck cooling production efficiency, comprise the steps:
Crystallization chain rotates along cooling rotary plate direction of rotation around the periphery of cooling rotary plate, and cooling rotary plate drives refrigerating head assembly to rotate;
When the upper roller of refrigerating head assembly moves along the lower surface of inserting embryo lobe plate, the spindle nose of cooling axis body inserts in the bottle embryo on crystallization chain in protective sleeve gradually, starts to carry out heat exchange;
Crystallization chain and cooling rotary plate synchronous rotary, when the bottom roller of refrigerating head assembly moves along the upper surface carrying embryo lobe plate, the spindle nose of cooling axis body and bottle embryo move up and are separated with crystallization chain gradually;
Cooling rotary plate drives the bottle embryo be separated with crystallization chain to continue to rotate, when the upper surface of the de-embryo lobe plate in upper roller edge of refrigerating head assembly is moved and the bottom roller of refrigerating head assembly moves along the lower surface taking off embryo lobe plate, the spindle nose of cooling axis body moves up, the lower installation board stop of the bottle indusium refrigerating head assembly on it is separated with the spindle nose of cooling axis body, terminates heat exchange.
Its further technical scheme is as follows:
When the upper roller of refrigerating head assembly moves along the upper surface taking off embryo lobe plate, also comprise the steps:
The bottom roller of refrigerating head assembly moves along the guide-track groove formed between the lower surface and the upper surface of de-embryo guide rail of de-embryo lobe plate.
When the upper roller of refrigerating head assembly moves along the upper surface of de-embryo lobe plate, when the spindle nose of cooling axis body moves up, also comprise the steps:
Material returned loop resistance gear on bottle indusium lower installation board lower surface on the spindle nose of cooling axis body, is separated with the spindle nose of cooling axis body gradually.
Below the advantage of preceding solution or principle are described:
The device and method of above-mentioned raising crystallizer bottleneck cooling production efficiency, by arranging slotting embryo lobe plate, carry embryo lobe plate, de-embryo lobe plate, embryo will be carried and de-embryo is separated, refrigerating head assembly is single bottle embryo cool time by the time of inserting embryo lobe plate and turn to de-embryo lobe plate, the mode of relatively traditional crystallizer cooling bottleneck, equal for cool time at single bottle embryo, when the crystallization chain radius of gyration is identical, the linear velocity of refrigerating head assembly is improved, and the linear velocity of refrigerating head assembly is identical with the linear velocity of crystallization chain, so the linear velocity of crystallization chain have also been obtained raising, thus the production efficiency making crystallizer cool bottleneck improves.
Accompanying drawing explanation
Fig. 1 is the schematic diagram of traditional crystallizer bottleneck cooling;
Fig. 2 is the overall schematic of the device of the raising crystallizer bottleneck cooling production efficiency described in the utility model embodiment;
Fig. 3 inserts the partial schematic diagram of embryo state for device described in the utility model embodiment;
Fig. 4 carries the partial schematic diagram of embryo state for device described in the utility model embodiment;
Fig. 5 takes off the partial schematic diagram of embryo state for device described in the utility model embodiment;
Fig. 6 is the structural representation of refrigerating head assembly described in the utility model embodiment.
Description of reference numerals:
1, crystallization chain, 2, protective sleeve, 3, bottle embryo, 4, water flowing cover; 10, cooling rotary plate, 20, refrigerating head assembly, 210, upper mounting plate, 220, lower installation board; 230, axis body is cooled, 240, the axis of guide, 250, upper roller; 260, bottom roller, 270, upper straight line axle sleeve, 280, lower straight line axle sleeve; 290, material returned ring, 30, insert embryo lobe plate, 40, carry embryo lobe plate; 50, de-embryo lobe plate, 60, de-embryo guide rail, 70, guide-track groove.
Detailed description of the invention
As shown in Figures 2 to 6, a kind of device improving crystallizer bottleneck cooling production efficiency, comprise cooling rotary plate 10, multiple refrigerating head assembly 20, insert embryo lobe plate 30, carry embryo lobe plate 40, de-embryo lobe plate 50, the crystallization chain 1 of crystallizer is arranged along the periphery of cooling rotary plate 10, crystallization chain 1 is provided with protective sleeve 2, bottle embryo 3 is arranged in protective sleeve 2, and bottle preform mouth exposes to protective sleeve 2, multiple refrigerating head assembly 20 is arranged on cooling rotary plate 10 centered by the axial line of cooling rotary plate 10, and refrigerating head assembly 20 is arranged on the top of protective sleeve 2, described refrigerating head assembly 20 comprises upper mounting plate 210 and the lower installation board 220 of stacked on top of one another setting, cooling axis body 230, the axis of guide 240 be connected with cooling rotary plate 10, the axis of guide 240 is successively through upper mounting plate 210, lower installation board 220, dottle pin (not shown) is provided with between upper mounting plate 210 and lower installation board 220, cooling axis body 230 is fixed on upper mounting plate 210, and the spindle nose of cooling axis body 230 exposes through lower installation board 220, upper mounting plate 210 at least one side parallel with the tangential direction of cooling rotary plate 10 is provided with upper roller 250, lower installation board 210 is provided with bottom roller 260 with the side of described upper roller 250 the same side, described slotting embryo lobe plate 30, carry embryo lobe plate 40, de-embryo lobe plate 50 is installed in the rotate path of refrigerating head assembly 20, insert embryo lobe plate 30 and be arranged on the porch that crystallization chain 1 enters cooling rotary plate 10, i.e. AB section, carry embryo lobe plate 40 and be arranged on the exit that crystallization chain 1 lays out cooling rotary plate 10, i.e. EF section, with described porch for starting point, direction of rotation along cooling rotary plate 10 rotates, described de-embryo lobe plate 50 is arranged on the downstream carrying embryo lobe plate 40, i.e. GH section, insert the top that embryo lobe plate 30 is positioned at upper roller 250, carry the below that embryo lobe plate 40 is positioned at bottom roller 260, de-embryo lobe plate 50 is between upper roller 250 and bottom roller 260.As shown in Figure 6, the two sides that in the application, upper mounting plate 210 is parallel with the tangential direction of cooling rotary plate 10 are all provided with upper roller 250, the two sides that lower installation board 210 is parallel with the tangential direction of cooling rotary plate 10 are all provided with bottom roller 260, and the top of two upper rollers 250 is equipped with one block of described slotting embryo lobe plate 30, the below of two bottom rollers 260 is equipped with described in one piece carries embryo lobe plate 40, one block of described de-embryo lobe plate 50 is equipped with between the upper roller 250 of the same side and bottom roller 260, when such setting makes refrigerating head assembly to move or moves down, both sides are simultaneously stressed, keep two lateral balances, avoid slotting embryo, carry embryo, the situation appearance that de-embryo is not in place.
By arranging slotting embryo lobe plate 30, carry embryo lobe plate 40, de-embryo lobe plate 50, embryo will be carried and de-embryo is separated, the time that refrigerating head assembly 20 turns to de-embryo lobe plate 50 by slotting embryo lobe plate 30 is single bottle embryo cool time, the mode of relatively traditional crystallizer cooling bottleneck, equal for cool time at single bottle embryo, when crystallization chain 1 radius of gyration is identical, the linear velocity of refrigerating head assembly 20 is improved, and the linear velocity of refrigerating head assembly 20 is identical with the linear velocity of crystallization chain 1, so the linear velocity of crystallization chain 1 have also been obtained raising, thus crystallizer bottleneck cooling production efficiency is improve, and slotting embryo lobe plate 30 is arranged on the porch that crystallization chain 1 enters cooling rotary plate 10, carry embryo lobe plate 40 and be arranged on the exit that crystallization chain 1 lays out cooling rotary plate 10, bottle preform mouth is made to have time enough to cool in protective sleeve 2, when making to carry embryo, bottle preform mouth can bind round on the spindle nose of cooling axis body 230 because cooling produces contraction, be unlikely to drop, the mode of traditional crystallizer cooling bottleneck, because cool time is constant, and the distance that cool time, intercrystalline chain rotated with bottle embryo necessarily, so speed cannot improve.
With reference to Fig. 1, cooling the single bottle preform mouth time is t, and traditional crystallizer bottleneck cooling effectiveness is relatively low, and computing formula is as follows:
The crystallization chain translational speed of V1-traditional, R-crystallization chain radius of gyration, ω
1-traditional crystallization chain angular speed, α
aB-insert embryo section, α
cD-put forward embryo section and de-embryo section, n
1-traditional crystallization chain rotating speed;
V1=R × ω
1, because of ω
1=2n
1π, n
1=(180-α
aB-α
cD)/360/t, substitutes into can obtain above formula:
V1=R×2n
1π=2πR(180-α
AB-α
CD)/360/t(mm/s);
With reference to Fig. 2, suppose that single bottle embryo is equal for cool time, when crystallization chain 1 radius of gyration is identical, the linear velocity V2>V1 of the refrigerating head assembly 20 described in the present embodiment, because the linear velocity of refrigerating head assembly 20 is the same with the linear velocity of crystallization chain 1, so the linear velocity of crystallization chain 1 also improve than originally, crystallizer bottleneck cooling production efficiency improve, and computing formula is as follows:
Crystallization chain 1 translational speed described in V2-the present embodiment, R-crystallization chain 1 radius of gyration, ω
2crystallization chain 1 angular speed described in-the present embodiment, α
aB-insert embryo section, α
eF-put forward embryo section, α
gH-de-embryo section, α
hAangle between-straight line OA and OH, n
2crystallization chain 1 rotating speed described in-the present embodiment;
V2=R × ω
2, because of ω
2=2n
2π, n
2=(360-α
aB-α
gH-α
hA)/360/t, substitutes into can obtain above formula:
V2=R×2n
2π=2πR(360-α
AB-α
GH-α
HA)/360/t(mm/s)
Because of α
hA<180 °, so V2>V1;
Suppose: α
aB=α
cD=α
gH=10 °, α
hA=60 °
Then: V2/V1=280/160=1.75=175%, production efficiency improves 75%.
Described in the present embodiment, de-embryo lobe plate 50 is arranged near described slotting embryo lobe plate 30.Arrange like this and can reduce de-angle between embryo lobe plate 50 and slotting embryo lobe plate 30, the linear velocity of refrigerating head assembly 20 and the linear velocity of crystallization chain 1 are improved, enhances productivity further.
As shown in Fig. 3 to 6, described in the present embodiment, refrigerating head assembly 20 also comprises material returned ring 290, described material returned ring 290 be enclosed within cooling axis body 230 spindle nose on and be fixed on lower installation board 220.By arranging material returned ring 290, making de-embryo more smooth, and can not bottle preform mouth be injured.
The device of described raising crystallizer bottleneck cooling production efficiency also comprises de-embryo guide rail 60, described de-embryo guide rail 60 correspondence is arranged on the below of de-embryo lobe plate 50, forms the guide-track groove 70 holding bottom roller 260 between the lower surface of de-embryo lobe plate 50 and the upper surface of de-embryo guide rail 60.By guide-track groove 70, in de-embryo process, make lower installation board 220 vertical direction keep geo-stationary, bottle embryo is separated quickly and smoothly with cooling axis body 230.
Along the direction of rotation of cooling rotary plate 10, in the present embodiment, the direction of rotation of cooling rotary plate 10 is counterclockwise, the lower surface of described slotting embryo lobe plate 30 is in downward trend gradually, in slotting embryo process, drive refrigerating head assembly 20 entirety to move down gradually, the described upper surface carrying embryo lobe plate 40 is the trend risen gradually, drive refrigerating head assembly 20 entirety gradually on move, the upper surface of described de-embryo lobe plate 50 in the trend risen gradually, drive upper mounting plate 210 relatively lower installation board 220 gradually on move.
With reference to Fig. 3 to Fig. 5, the principle of device of the raising crystallizer bottleneck cooling production efficiency described in the present embodiment is described as follows:
Cooling initial state A → B:(is shown in Fig. 3)
Insert embryo lobe plate 30 and form cam mechanism with upper roller 250, insert embryo lobe plate 30 geo-stationary, refrigerating head assembly 20 is when pivot (with reference to Fig. 1) rotates, according to cam mechanism operation principle, insert embryo lobe plate 30 lower surface and will press downwards roller 250, make it to move downward, because upper roller 250 and upper mounting plate 210 are linked together, cooling axis body 230 is fixed on upper mounting plate 210, so drive cooling axis body 230 to insert in bottle preform mouth along the axis of guide 240 direction, (cooling axis body 230 cools with circulating chilled water to start to carry out heat exchange, cold water overlaps 4 by water flowing and enters cooling axis body 230),
Carry embryo state E → F:(and see Fig. 4)
Carry embryo lobe plate 40 and form cam mechanism with bottom roller 260, carry embryo lobe plate 40 geo-stationary, refrigerating head assembly 20 is when pivot (with reference to Fig. 1) rotates, according to cam mechanism operation principle, carry embryo lobe plate 40 upper surface and incite somebody to action upwardly bottom roller 260, make it to move upward, because bottom roller 260 and lower installation board 220 are linked together, lower installation board 220 and upper mounting plate 210 can slide along the axis of guide 240, promotion upper mounting plate 210 moves up by lower installation board 220, drive cooling axis body 230 and bottle embryo to move up to be separated with crystallization chain 1, bottle preform mouth binds round on the spindle nose of cooling axis body 230 because of producing contraction after cooling,
Cooling done state G → H:(is shown in Fig. 5)
De-embryo lobe plate 50 forms cam mechanism with upper roller 250, de-embryo lobe plate 50 geo-stationary, refrigerating head assembly 20 is when pivot (with reference to Fig. 1) rotates, according to cam mechanism operation principle, de-embryo lobe plate 50 upper surface incites somebody to action upwardly upper roller 250, make it upwards moving linearly, because upper roller 250 and upper mounting plate 210 are linked together, cooling axis body 230 is fixed on upper mounting plate 210, so drive cooling axis body 230 and bottle embryo to move up, roll in the guide-track groove 70 that bottom roller 260 is formed between de-embryo lobe plate 50 and de-embryo guide rail 60 simultaneously, vertical direction keeps geo-stationary, bottom roller 260 and material returned ring 290 are fixed on lower installation board 220, so material returned ring 290 vertical direction keeps geo-stationary, when bottle embryo and cooling axis body 230 move up simultaneously, bottle embryo upper surface will be stopped by material returned ring 290 lower surface, reduce gradually with cooling axis body 230 contact area, until depart from completely with cooling axis body 230, terminate the state of cooling, bottle embryo is fallen in embryo bucket under gravity.
As shown in Figure 6, described refrigerating head assembly 20 also comprises straight line axle sleeve 270, lower straight line axle sleeve 280, described upper straight line axle sleeve 270, lower straight line axle sleeve 280 are all enclosed within the axis of guide 240, described dottle pin is arranged between straight line axle sleeve and lower straight line axle sleeve 280, described upper mounting plate 210 is enclosed within straight line axle sleeve 270, and lower installation board 220 is enclosed within lower straight line axle sleeve 280.By arranging upper straight line axle sleeve 270, lower straight line axle sleeve 280 makes upper mounting plate 210, lower installation board 220 more successfully move up and down along the axis of guide 240.
Improve a method for crystallizer bottleneck cooling production efficiency, comprise the steps:
Crystallization chain 1 rotates along cooling rotary plate 10 direction of rotation around the periphery of cooling rotary plate 10, and cooling rotary plate 10 drives refrigerating head assembly 20 to rotate;
When the upper roller 250 of refrigerating head assembly 20 moves along the lower surface of slotting embryo lobe plate 30, the spindle nose of cooling axis body 230 inserts in the bottle embryo on crystallization chain 1 in protective sleeve 2 gradually, starts to carry out heat exchange;
Crystallization chain 1 and cooling rotary plate 10 synchronous rotary, when the bottom roller 260 of refrigerating head assembly 20 moves along the upper surface carrying embryo lobe plate 40, the spindle nose of cooling axis body 230 and bottle embryo move up and are separated with crystallization chain 1 gradually;
Cooling rotary plate 10 drives the bottle embryo be separated with crystallization chain 1 to continue to rotate, when the upper roller 250 of refrigerating head assembly 20 moves along the upper surface of de-embryo lobe plate 50 and the bottom roller 260 of refrigerating head assembly 20 moves along the guide-track groove 70 formed between the lower surface and the upper surface of de-embryo guide rail 60 of de-embryo lobe plate 50, the spindle nose of cooling axis body 230 moves up, material returned ring 290 on lower installation board 220 lower surface of the bottle indusium refrigerating head assembly 20 on it stops, be separated with the spindle nose of cooling axis body 230, terminate heat exchange.
The method can effectively make the speed of crystallization chain 1 and cooling rotary plate 10 improve, thus improves crystallizer bottleneck cooling production efficiency.
Each technical characteristic of the above embodiment can combine arbitrarily, for making description succinct, the all possible combination of each technical characteristic in above-described embodiment is not all described, but, as long as the combination of these technical characteristics does not exist contradiction, be all considered to be the scope that this description is recorded.
The above embodiment only have expressed several embodiment of the present utility model, and it describes comparatively concrete and detailed, but therefore can not be interpreted as the restriction to the utility model the scope of the claims.It should be pointed out that for the person of ordinary skill of the art, without departing from the concept of the premise utility, can also make some distortion and improvement, these all belong to protection domain of the present utility model.Therefore, the protection domain of the utility model patent should be as the criterion with claims.
Claims (7)
1. one kind is improved the device of crystallizer bottleneck cooling production efficiency, it is characterized in that, comprise cooling rotary plate, multiple refrigerating head assembly, insert embryo lobe plate, carry embryo lobe plate, de-embryo lobe plate, the crystallization chain of crystallizer is arranged along the periphery of cooling rotary plate, crystallization chain is provided with protective sleeve, bottle embryo is arranged in protective sleeve, and bottle preform mouth exposes to protective sleeve, multiple refrigerating head assembly is arranged on cooling rotary plate centered by the axial line of cooling rotary plate, and refrigerating head assembly is arranged on the top of protective sleeve, described refrigerating head assembly comprises upper mounting plate and the lower installation board of stacked on top of one another setting, cooling axis body, the axis of guide be connected with cooling rotary plate, the axis of guide is successively through upper mounting plate, lower installation board, dottle pin is provided with between upper mounting plate and lower installation board, cooling axis body is fixed on upper mounting plate, and the spindle nose of cooling axis body exposes through lower installation board, upper mounting plate at least one side parallel with the tangential direction of cooling rotary plate is provided with upper roller, the side of lower installation board and described upper roller the same side is provided with bottom roller, described slotting embryo lobe plate, carry embryo lobe plate, de-embryo lobe plate is installed in the rotate path of refrigerating head assembly, insert embryo lobe plate and be arranged on the porch that crystallization chain enters cooling rotary plate, carry embryo lobe plate and be arranged on the exit that crystallization chain lays out cooling rotary plate, with described porch for starting point, direction of rotation along cooling rotary plate rotates, described de-embryo lobe plate is arranged on the downstream carrying embryo lobe plate, insert the top that embryo lobe plate is positioned at upper roller, carry the below that embryo lobe plate is positioned at bottom roller, de-embryo lobe plate is between upper roller and bottom roller.
2. the device improving crystallizer bottleneck cooling production efficiency as claimed in claim 1, is characterized in that, described de-embryo lobe plate is arranged near described slotting embryo lobe plate.
3. the device improving crystallizer bottleneck cooling production efficiency as claimed in claim 1, it is characterized in that, described refrigerating head assembly also comprises straight line axle sleeve, lower straight line axle sleeve, described upper straight line axle sleeve, lower straight line axle sleeve are all enclosed within the axis of guide, described dottle pin is arranged between straight line axle sleeve and lower straight line axle sleeve, described upper mounting plate is enclosed within linear axis and puts, and lower installation board is enclosed within lower linear axis and puts.
4. the as claimed in claim 3 device improving crystallizer bottleneck cooling production efficiency, it is characterized in that, described refrigerating head assembly also comprises material returned ring, and described material returned ring set is on the spindle nose of cooling axis body and be fixed on lower installation board.
5. the device improving crystallizer bottleneck cooling production efficiency as claimed in claim 4, it is characterized in that, it also comprises de-embryo guide rail, described de-embryo guide rail correspondence is arranged on the below of de-embryo lobe plate, forms the guide-track groove holding bottom roller between the lower surface of de-embryo lobe plate and the upper surface of de-embryo guide rail.
6. the device of the raising crystallizer bottleneck cooling production efficiency as described in any one of claim 1 to 5, it is characterized in that, along the direction of rotation of cooling rotary plate, the lower surface of described slotting embryo lobe plate is in downward trend gradually, the described upper surface carrying embryo lobe plate is the trend risen gradually, and the upper surface of described de-embryo lobe plate is in the trend risen gradually.
7. the device of the raising crystallizer bottleneck cooling production efficiency as described in any one of claim 1 to 5, it is characterized in that, the two sides that described upper mounting plate is parallel with the tangential direction of cooling rotary plate are equipped with upper roller, the two sides that lower installation board is parallel with the tangential direction of cooling rotary plate are equipped with bottom roller (260), and the top of two upper rollers is equipped with one block of described slotting embryo lobe plate, the below of two bottom rollers is equipped with described in one piece carries embryo lobe plate, is equipped with one block of described de-embryo lobe plate between the upper roller of the same side and bottom roller.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201420873301.0U CN204505810U (en) | 2014-12-31 | 2014-12-31 | Improve the device of crystallizer bottleneck cooling production efficiency |
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|---|---|---|---|
| CN201420873301.0U CN204505810U (en) | 2014-12-31 | 2014-12-31 | Improve the device of crystallizer bottleneck cooling production efficiency |
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| CN204505810U true CN204505810U (en) | 2015-07-29 |
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Cited By (1)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN104552899A (en) * | 2014-12-31 | 2015-04-29 | 广州达意隆包装机械股份有限公司 | Device and method for improving crystallizer bottle mouth cooling production efficiency |
-
2014
- 2014-12-31 CN CN201420873301.0U patent/CN204505810U/en not_active Withdrawn - After Issue
Cited By (3)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN104552899A (en) * | 2014-12-31 | 2015-04-29 | 广州达意隆包装机械股份有限公司 | Device and method for improving crystallizer bottle mouth cooling production efficiency |
| WO2016107079A1 (en) * | 2014-12-31 | 2016-07-07 | 广州达意隆包装机械股份有限公司 | Device and method for improving cooling production efficiency of crystallizer bottle mouth |
| US10315351B2 (en) | 2014-12-31 | 2019-06-11 | Guangzhou Tech-Long Packaging Machinery Co., Ltd | Apparatus and method for improving production efficiency of crystallizer bottleneck cooling |
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