IE86889B1

IE86889B1 - Concentrates preparation device

Info

Publication number: IE86889B1
Application number: IE20150242A
Authority: IE
Inventors: Zhu Gong
Original assignee: Zhu Gong
Priority date: 2014-11-28
Filing date: 2015-08-11
Publication date: 2018-04-04
Also published as: IES20150263A2; CN105435475A; AU2015100475A4; CN104399261A; GB2536756A; CN105344118A; CN105396307A; AU2015100476A4; CN105289019A; CN105396305A; CN104399261B; CN105396306A; IES86678B2; CN105363226A; GB2536756B; IE20150242A1; CN105413203A; CN105435474A; CN105457319A; GB201520927D0

Abstract

The invention relates to a concentrates preparation device using low pressure and low boiling point. The device comprises a boiler, an accumulator unit, a cooling unit, a depressurization unit; the sidewall of the boiler unit near to the bottom portion is provided with a sampling unit, the upper cover of the boiler unit is provided with a condensing unit; the sampling chamber passes through the upper and lower surfaces of the base body, the isobaric chamber passes through the front surface of the base body and through the front and back surfaces of the sampling chamber; the sealing barrel communicates with the outside through the first, second, third and fourth ducts; the output duct, water outlet duct and the water inlet duct of the boiler respectively connects with the second water valve of the accumulator unit, the input and output ends of the cooling unit, the third water valve connects with the input end of the depressurization unit, the first and fourth water valves connect with the atmosphere. The device of the invention has good reliability and high efficiency.

Description

Concentrates preparation device Field of the Invention The invention relates to a concentrates preparation device, especially to a concentrates preparation device using low pressure and low boiling point.

Description of prior art The boiling point of water decreases with the pressure, so water can be boiling with low temperature under low pressure, the boiling water changes liquid water into water vapor, mist water vapor condenses on the interface between cool and hot, a lot of mist collects together to form water drop, and a lot of water drop collects together to form water flow, whether we can use the above principle to lower the moisture content of the mixture so as to increase the concentration. is Summary of the present invention The object of the invention is to provide a concentrates preparation device so as to solve the above problem.

Therefore, the invention provide a concentrates preparation device, the device comprises a boiler unit, an accumulator unit, a cooling unit and a depressurization unit, the boiler unit has a sealing structure, and at a bottom portion thereof is provided with a feeding opening, a discharging opening and a heating unit; a sidewall of the boiler unit is provided with a sampling unit that is proximate to a bottom portion of the boiler unit, a cover of the boiler unit is provided with a condensing unit. Inside the cover is provided with a collecting portion of the condensing unit, the collecting 2/20 portion includes a bar confluence rod fitting with an interior crown surface of a cover body and a confluence ring fitting with the interior crown surface ofthe cover body. An opening ofthe confluence ring is toward a top portion of the cover body; the confluence ring and the cover body defines a confluence chamber, a tail end of the bar confluence rod extends to the confluence chamber communicated with an outside atmosphere through an output duct.

A cooling portion of is located outside the cover, the cooling portion has a plurality of ringlike sheets coaxial with one another, the ringlike sheet is arranged along an exterior crown surface of the cover body, an axis of the ringlike sheet is coaxial with an axis ofthe cover body, a bottom portion of the ringlike sheet fits with the exterior crown surface of the cover body, a top portion of the condensing unit is provided with a water inlet duct, a is bottom portion of the condensing unit is provided with a water outlet duct.

The sampling unit is provided with a base body, a movable rod, a limiting pin, a sampling chamber, a sampling bore, an axle sleeve I, an axle sleeve II and an isobaric chamber; the sampling chamber passes through a first and second surface of the base body, the isobaric chamber is a cylindrical blind bore, the isobaric chamber passes through a third surface ofthe base body and passes through a first and second surface ofthe sampling chamber.

The axle sleeve I has an interference fitting with the isobaric chamber, the movable rod hermetically slidingly mating with the axle sleeve I and the axle sleeve II, the limiting pin is fastened to the movable rod, the limiting pin mates with the first or second surface ofthe sampling chamber, 3/20 inside the base body is provided with a gas permeable passage, a head end of the gas permeable passage communicates with the isobaric chamber, a tail end of the gas permeable passage communicates with the outside atmoshpere.

The accumulator unit is provided with a barrel, a first duct, a second duct, a third duct, a fourth duct, a first water valve, a second water valve, a third water valve, a fourth water valve and a water level tagging pipe; the barrel communicates with the outside atmosphere through the first, second, third and fourth duct; the first, second, third and fourth duct switch between opening and closing respectively through the first, second, third and fourth water valve.

The output duct of the confluence chamber of the boiler unit communicates is with the second water valve of the accumulator unit, the water outlet duct of the cooling portion of the boiler unit communicates with an input end of the cooling unit through a fifth water valve, the water inlet duct of the cooling portion of the boiler unit communicates with an output end of the cooling unit through a sixth water valve, the third water valve of the 20 accumulator unit communicates with an input end of the depressurization unit through a fifth duct, the first and fourth water valve communicates with the outside atmosphere.

The bar confluence rod is provided with an abutment surface corresponding to an interior crown surface of the cover body, two first arcuate surfaces are symmetrically arranged to two side surfaces perpendicular to the abutment surface to form an opposed invagination, two second arcuate surfaces are 4/20 arranged to the top surface parallel to the abutment surface to form an opposed invagination, between the first and second arcuate surface forms an overflow prevention edge, the bar confluence rod proximate to a top end thereof is provided with a first slope and a second slope, an angle formed by the first and second slope is an obtuse angle, the second slope slopes from a top end of the bar confluence rod to the abutment surface, the first slope slopes from the top end of the bar confluence rod to the abutment surface, the second arcuate surface extends to the second slope, the first arcuate surface extends to the first slope.

Single-side section of the confluence ring is a form of a letter L, a bottom edge of the L is perpendicular to the interior crown surface of the cover, a perpendicular edge of the L is parallel to the interior crown surface of the cover.

The movable rod is at a withdraw position and the sampling bore is outside the base body when the limiting pin mates with the first surface of the sampling chamber; the movable rod is at an insertion position and the sampling bore is inside the sampling chamber when the limiting pin mates with the second surface of the sampling chamber.

The gas permeable passage extends to the third surface of the base body, the sampling chamber of the sampling unit is inside a boiler, a handle is outside the boiler.

The first duct is located proximate to a bottom portion of the barrel, an interior opening of the second duct is proximate to the bottom portion of /20 the barrel and above an interior opening of the first duct, an interior openings of the third and fourth ducts are proximate to a top portion of the barrel, the second and third water valves are fixedly connected with each other by a connecting block so as to rotate together.

Advantageous Effects The second and third water valves are fixedly connected with each other by the connecting block so as to rotate together, such arrangement increases the stability of the device, and avoids such disadvantages, 1. It is needed to switch the second and third water valves on when the depressurization unit decompresses the boiler unit, if the second water valve is switched on while the third water valve is forgotten to be switched on, it is still at off position, then the depressurization unit can not is decompress the boiler unit, such that the depressurization works for nothing; if the third water valve is switched on while the second water valve is forgotten to be switched on, it is still at off position, then the depressurization unit can not decompress the boiler unit, such that the depressurization works for nothing. 2. It is needed to switch the second and third water valves off when the accumulator unit is draining water, if the third water valve is switched off while the second water valve is forgotten to be switched off, it is still at on position, then when the fourth water valve is switched on, the outside atmosphere compresses water in the barrel into the second duct, water flows through the second and fifth water valves into the boiler, when the confluence chamber is full of back flowing water, water overflows and drops into the prepared concentrates, such that the density of concentrates is 6/20 reduced.

When the sampling unit takes samples of concentrates from the boiler, it is no necessary to stop concentration process or to open a cover of the boiler.

Concentrates in the boiler can be taken out through the sampling bore of the sampling unit, the movable rod can take samples freely with the help of gas permeable passage for keeping the pressure balance of ends of the movable rod.

The cooling portion of the condensing unit consists of a plurality of ringlike sheets arranged coaxially and step-shaped, such arrangement enlarges the connecting area between the cover of the boiler and the cooling liquid so as to increase the cooling efficiency. is The first and second arcuate surfaces arranged to the bar confluence rod enlarge the interface between hot and cool so as to increase the condensing efficiency.

The overflow prevention edge arranged to the bar confluence rod makes condensed water drop slide along the first and second arcuate surfaces into the confluence chamber so as to prevent condensed water drop directly from dropping into the concentrates, such that the density of concentrates is reduced.

At the time when the second and third water valves are switched on, water in ducts is compressed back to the boiler, due to the cushion effect of the confluence chamber, water is kept in the confluence chamber rather than 7/20 drops directly into the concentrates.

Brief description of the drawing In the following, the invention will be described in greater detail by means of some embodiments with reference to the accompanying drawings, in which Fig.l is a 3d-drawing of the concentrates preparation device; Fig.2 is a 3d-drawing of the boiler in Fig.l; Fig.3 is an exploded 3d-drawing of the boiler; Fig.4 is a 3d-drawing of the boiler without the cover in Fig.3; Fig.5 is a top view of the cover of the boiler in Fig.3; Fig.6 is a 3d-drawing of the cover in Fig.5; Fig.7 is a 3d-drawing of the cover from another view angle in Fig.5; Fig.8 is an exploded 3d-drawing of the cover in Fig.5; Fig.9 is a sectional view of Fig.5 along A-A direction; Fig.10 is a sectional view of Fig.5 along B-B direction; Fig.ll is a detailed view of the part I in Fig. 12; Fig.12 is a 3d-drawing of a single bar confluence rod in Fig.8; Fig.13 is a detailed view of the part II in Fig.12; Fig.14-18 are 3d-drawings of the sampling unit in Fig.3, wherein the movable rod is at different positions; Fig.19 is an exploded 3d-drawing of the sampling unit in Fig.3; Fig.2O is a sectional 3d-drawing of the sampling unit in Fig.3; Fig.21-23 are sectional front views of the sampling unit, wherein the movable rod is at different position; Fig.24 is a sectional 3d-drawing of the accumulator unit in Fig.l; Fig.25 is a detailed view of the accumulator unit in Fig.24; 8/20 Fig.26 is an exploded 3d-drawing of the second and third water valves in Fig.25. 1. boiler unit; 11. cover; 12. heating unit; 13. sidewall; 14. sampling unit; 15. feeding opening; 16. discharging opening;.1101. cover body; 1102. confluence ring; 1103. bar confluence rod; 1104. ringlike sheet; 1105. output duct; 1106. water inlet duct; 1107. water outlet duct; 1108. gas inlet duct; 1109. water outlet opening; io 1103a. abutment surface; 1103b. first arcuate surface; 1103c. second arcuate surface; 1103d. overflow prevention edge; 1103e. second slope; 1103f. first slope; 1103g. third slope; 1401. base body; 1402. limiting pin; 1403. movable rod; is 1404. sampling bore; 1405. sampling chamber; 1406. handle; 1407. shaft sleeve; 1408. gas permeable passage; 1409. isobaric chamber; 2. accumulator unit; 20. connecting block; 21. barrel; 22. fourth water valve; 23. third water valve; 24. second water valve; 25. first water valve; 26. water level tagging pipe; 27. fourth duct; 28. third duct; 29. second duct; 210. first duct; 201. circular shaft; 3. cooling unit; 4. depressurization unit.

Detailed description of the preferred embodiment In order to distinguish between the interior opening and the exterior 9/20 opening, the opening which is inside the container is called the interior opening, the opening which is outside the container is called the exterior opening.

Referring to Fig.l, it is a concentrates preparation device of the invention, the device comprises a boiler unit l,an accumulator unit 2, a cooling unit 3 and a depressurization unit 4; an output duct 1105 of the confluence chamber of the boiler unit 1 communicates with a second water valve 24 of the accumulator unit 2, a water outlet duct 1107 of a cooling portion of the io boiler unit 1 communicates with an input end of the cooling unit 3 through a fifth water valve, a water inlet duct 1106 of the cooling portion of the boiler unit 1 communicates with an output end of the cooling unit 3 through a sixth water valve, a third water valve 23 of the accumulator unit 2 communicates with an input end of the depressurization unit 4 through a is fifth duct, a first and fourth water valve 25,22 of the accumulator unit 2 communicate with an outside atmosphere.

Referring to Fig.2-4, a sidewall 13 of the boiler unit 1 is provided with a sampling unit 14 that is proximate to a bottom portion of the boiler unit 1, a cover 11 of the boiler unit 1 is provided with a condensing unit, the boiler unit 1 has a sealing structure, a feeding opening 15, a discharging opening 16 and a heating unit 12 arranged to a bottom portion of the boiler unit 1. Referring to Fig.5, 6, 9 ,10, the cooling portion of the condensing unit is located outside the cover 11, the cooling portion includes a plurality of ringlike sheets 1104 arranged coaxially, and the ringlike sheet 1104 are arranged along the crown surface of a cover body 1101, an axis of the ringlike sheet 1104 is coaxial with an axis of the cover body 1101, a bottom /20 portion of the ringlike sheet 1104 fits with an exterior crown surface of the cover body 1101, a distance from a top portion of the ringlike sheet 1104 to a bottom surface of the cover body 1101 is tapering such as to decrease with increasing self diameter. The top ring of the ringlike sheet 1104 is provided with a water inlet duct 1106, of which a bottom portion fixedly connects with the top portion of the cover body 1101, a bottom portion of the water inlet duct 1106 is provided with a plurality of water outlet openings 1109; a bottom ring of the ringlike sheet 1104 is provided with a water outlet duct 1107, water with low temperature flows into a top ring io through the water inlet duct 1106, water overflows into a next ring below the top ring when the top ring is full of water with low temperature, water with low temperature sequentially fills the rings one after one, finally water goes out of the water outlet duct 1107 of the bottom ring, obviously, the temperature of the top ring is higher than the temperature of the bottom is ring.

Referring to Fig.7, 8, 9, 10, the collecting portion of the condensing unit is located inside the cover 11, the collecting portion includes a bar confluence rod 1103 fitting with an interior crown surface of the cover body 1101 and a confluence ring 1102 fitting with an interior crown surface of the cover body 1101, an opening of the confluence ring 1102 is toward a top portion of the cover body 1101, the confluence ring 1102 and the cover body 1101 form a confluence chamber, a tail end of the bar confluence rod 1103 extends into the confluence chamber, the single section of the confluence ring 1102 is a form of a letter L, a bottom edge of the L is perpendicular to the interior crown surface of the cover 11, a perpendicular edge of the L is parallel to the interior crown surface of the cover 11, the confluence chamber 11/20 communicates with the outside atmosphere through the output duct 1105, of which the interior opening is proximate to the bottom portion of the confluence chamber and far below the top portion of the perpendicular edge of the L.

Referring to Fig.ll, 12, 13, the bar confluence rod 1103 is provided with an abutment surface 1103a corresponding to an interior crown surface of the cover body 1101, two first arcuate surfaces 1103b are symmetrically arranged to two side surfaces perpendicular to the abutment surface 1103a io to form an opposed invagination, a second arcuate surface 1103c is arranged to the top surface parallel to the abutment surface 1103a to form an opposed invagination, between the first and second arcuate surface 1103b, 1103c forming an overflow prevention edge 1103d, the bar confluence rod 1103 proximate to a top end thereof is provided with a first is slope 1103f and a second slope 1103e, an angle formed by the first and second slope is an obtuse angle, the second slope 1103e slopes from a top end of the bar confluence rod 1103 to the abutment surface 1103a, the first slope 1103f slopes from a top end of the bar confluence rod 1103 to the abutment surface 1103a, the second arcuate surface 1103c extends to the 20 second slope 1103e, the first arcuate surface 1103b extends to the first slope 1103f. Two third slopes 1103g are symmetrically arranged to the end proximate to the first slope 1103f of the bar confluence rod 1103, the third slope 1103g make the end near to the first slope 1103f of the bar confluence rod 1103 form a sharp corner, a plurality of bar confluence rods 25 are arranged in a circle around the sharp corner by such arrangement that the third slopes 1103g close up by face to face. 12/20 Hot water steam in the boiler condenses into water drop when hot steam touches the cool first or second arcuate surface 1103b, 1103c of the bar confluence rod 1103, water drop slides into the confluence chamber along the first or second arcuate surface 1103b, 1103c of the bar confluence rod 1103 under the cooperation between the overflow prevention edge 1103d and the surface tension of the water drop, water drop collects together in the confluence chamber and then goes out of the confluence chamber through the output duct 1105. io Referring to Fig.19, 20, the sampling unit 14 includes a base body 1401, a movable rod 1403, a limiting pin 1402, a sampling chamber 1405, a sampling bore 1404, a shaft sleeve 1407 and an isobaric chamber 1409.

Referring to Fig.21, the sampling chamber 1405 goes through a first and is second surface of the base body 1401, the isobaric chamber 1409 is a cylindrical blind bore, the isobaric chamber 1409 passes through a third surface of the base body 1401 and through the first and second surface of the sampling chamber 1405; the shaft sleeve 1407 has an interference fitting with the isobaric chamber 1409, the movable rod 1403 hermetically 20 slidingly mates with the axle sleeve 1407, the limiting pin 1402 is fastened to the movable rod 1403, the limiting pin 1402 mates with the first surface or the second surface of the sampling chamber 1405. The movable rod 1403 is at a withdraw position and the sampling bore (1404) is outside the base body 1401 when the limiting pin 1402 mates with the first surface of the 25 sampling chamber 1405; the movable rod 1403 is at an insertion position and the sampling bore 1404 is inside the sampling chamber 1405 when the limiting pin 1402 mates with the second surface of the sampling chamber 13/20 1405, referring to Fig. 14, 15.

Referring to Fig.20, inside the base body 1401 is provided with a gas permeable passage 1408, of which a head and tail end respectively communicate with the isobaric chamber 1409 and the outside atmosphere, the air permeable passage 1408 extends to the third surface of the base body 1401, air pressure of the isobaric chamber 1409 is equal to the outside air pressure with the help of the gas permeable passage 1408 so as to make the movable rod 1403 moves more flexibly. The movable rod 1403 io proximate to the third surface of the base body 1401 is provided with a handle 1406, of which a diameter is greater than an interior diameter of the shaft sleeve 1407, the sampling chamber 1405 of the sampling unit 14 is inside the boiler, the handle 1406 is outside the boiler. is Referring to Fig.24, 25, the accumulator unit 2 is provided with a barrel 21, a first duct 210, a second duct 29, a third duct 29, a fourth duct 27, a first water valve 25, a second water valve 24, a third water valve 23, a fourth water valve 22 and a water level tagging pipe 26. The barrel 21 communicates with the outside atmosphere through the first, second, third, and fourth duct 210,29,28,27; the first, second, third, and fourth duct 210,29,28,27 are switched between opening and closing respectively through the first, second, third and fourth water valve 25,24,23,22; the first duct 210 is located proximate to a bottom portion of the barrel 21, an interior opening of the second duct 29 is proximate to a bottom portion of the barrel 21 and above an interior opening of the first duct 210, an interior openings of the third and fourth ducts 28, 27 are proximate to the top portion of the barrel 21. 14/20 Referring to Fig.26, the second and third water valve have synchronous action, which is achieved by such arrangement, the connecting block 20 with a contour corresponding to a handle of the water valve is respectively provided with a through hole at each end of a head and tail end, the handle of the water valve at the respective position is provided with a through hole, the connecting block 20 is configured between the two handles of the water valve, two circular shafts 201 connects the handle with the connecting block 20, and then circular shaft 201,the handle and the connecting block 20 are io fastened together by a retaining ring.

The concentrates preparation device of the invention includes a depressurization process, a condensing process, an accumulating process, a draining process and a sampling process. is Depressurization process Switching off the first, fourth and sixth water valves 25, 22, switching on the second, third, fifth, seventh, eighth and ninth water valves 24,23. Turning on the depressurization unit 4 to make the air in the boiler pass sequentially through the fifth, second, third and ninth water valves 24, 23 into the depressurization unit 4 so as to decrease the air pressure in the boiler. Condensing process Turning on the cooling unit 3 to make cooling liquid thereof loop sequentially through the seventh water valve, the top ring, the bottom ring and the eighth water valve, the temperature of the top cover of the boiler is less than the temperature of the hot steam in the boiler with the help of cooling liquid. Turning on the heating unit 12 in the boiler to increase the temperature of the mixture therein, the boiling point of water in the /20 mixture is decreased under the low air pressure in the boiler, so the water can be boiling at low temperature to produce hot steam, which condenses into water drop when touches the bar confluence rod 1103 with lower temperature with respect to hot steam, water drop slides into the confluence chamber along the first or second arcuate surface 1103b, 1103c with the help of cooperation between overflow prevention edge 1103d and surface tension of water drop, the confluence chamber collects water drop slid from the bar confluence rod 1103. Through the condensing process, water in the mixture in the boiler is continuously transferred into the io confluence chamber so as to decrease the content of water in the mixture.

Accumulating process When water level in the confluence chamber is over the interior opening of the output duct 1105, through which water is drained into the accumulator is unit 2, water passes sequentially through the fifth water valve and the second water valve 24, there are three conditions in the accumulating process: 1. the air pressure in the boiler is greater than the air pressure in the accumulator unit 2; 2. the air pressure in the boiler is equal to the air pressure in the accumulator unit 2; 3. the air pressure in the boiler is less than the air pressure in the accumulator 2.

When in condition 1, water in the confluence chamber is compressed into the accumulator unit 2 by the air pressure.

When in condition 2, water in the confluence chamber flows into the accumulator unit 2 under the gravity force, because the confluence chamber is above the accumulator unit. 16/20 When in condition 3, turning on the depressurization unit 4 to decrease the air pressure in the accumulator unit 2 and make it less than the air pressure in the boiler, such that the condition 3 is changed to condition 1 or condition 2; the accumulator unit 2 accumulates water through above three methods.

Because the heating unit 12 in the boiler is heating, the temperature in the boiler is greater than the temperature in the accumulator unit 2, so the air io pressure in the boiler is greater than the air pressure in the accumulator unit 2, thus, heating is good for condition 1.

When the density of the concentrates reaches the predetermined-density, the heating unit 12 stops heating, the air pressure in the boiler is decreased, is turning on the depressurization unit 4 for avoiding that the air pressure in the boiler is less than the air pressure in the accumulator unit 2, the air pressure in the accumulator unit 2 is less than the air pressure in the boiler through the depressurization unit 4 so as to compress the water condensed from the rest steam into accumulator unit 2. Because the water level in the 20 confluence chamber is above the interior opening of the output duct 1105, steam in the boiler do not directly pass into the accumulator unit 2 so as to reduce bad impact from steam to the depressurization unit 4; because the interior opening of the second duct 29 is near to the bottom portion of the barrel 21, and the interior opening of the third duct 28 is near to the top 25 portion of the barrel 21, it is avoided that water compressed out of the second duct 29 is immediately inhaled into the third duct 28 when the depressurization unit 4 works, such arrangement that the interior opening is 17/20 arrange to the top portion of the barrel 21 can reduce the risk of water in the barrel 21 passing into the third duct 28.

Draining process When the water level tagging pipe 26 displays that the water level reaches the predetermined-density, the second water valve 24 is turn25 off firstly, because the second water valve 24 acts together with the third water valve 23 through the connecting block 24, the third water valve 23 is turned off when the second water valve 24 is turned off, from then on, water io condensed in the boiler is stored by the confluence chamber provisionally, the accumulator unit 2 is isolated from the boiler after the second and third water valves 24,23 are switched off; the fourth water valve 22 is switched on for an equal air pressure between the accumulator unit 2 and the outside atmosphere, the first water valve 25 is switched after achieving the is equal air pressure, water in the accumulator unit 2 flows out from the first water valve 25 due to the gravity force, the draining of accumulator unit 2 is achieved.

After water in the accumulator unit 2 is drained off, the first and fourth water valves 25,22 are turned off firstly so as to isolate the accumulator unit 2 from the outside atmosphere, after that, the second water valve 24 is turned on secondly, meanwhile the third water valve 23 is turned on too, because the air pressure in the accumulator unit 2 is greater than the air pressure in the boiler, water in the duct is compressed back to the boiler at the time when the second and third water valves 24,23 are turned on, water is kept in the confluence chamber rather than flows into the concentrates due to the buffering effect of the confluence chamber. When the air 18/20 pressure in the accumulator unit 2 is equal to the air pressure in the boiler, condensed water provisionally stored in the confluence chamber flows to the accumulator unit 2 under the gravity force. The depressurization unit 4 is switched on for keeping a low air pressure condition in the boiler so as to keep the air pressure at a predetermined-density, switching on the depressurization unit 4 speeds up water in the confluence chamber flowing to the accumulator unit 2.

Sampling process io Referring to Fig.21,22,23, the sampling unit 14 takes samples of concentrates in the boiler during the concentrating process to make concentration detection of samples. In order to increase detecting accuracy, the handle 1406 is rotated fast before sampling, referring to Fig.18, the remnant sample left in the sampling bore 1404 is thrown out due to the is centrifugal force, then the sampling bore is upwards with the help of the direction mark on the handle 1406; the movable rod 1403 is drawn out to the withdraw position after the sampling bore 1404 is full of concentrates, detector detects the concentration of the sample in the sampling bore, or detector detects the concentration of the sample in the glassware dropped from the sampling bore due to the gravity force after rotating the movable rod 1403 to make the sampling bore 1404 be downwards. The movable rod 1403 is pushed back to the insertion position after sampling process.

After the density of concentrates in the boiler reaches the predetermined-density, the heating unit 12, the depressurization unit 14, the fifth water valve and the sixth water valve are switched off firstly, air from the outside goes into the boiler through the gas inlet duct 1108 so as 19/20 to make the air pressure in the boiler be equal to the outside air pressure, the present air pressure in the boiler is greater than the beginning of concentrating, the boiling point of water in the concentrates increases accordingly. Because the heating unit 12 is turned off, water in the concentrates do not boil any long, the concentrates do not loose water any more, that is the present density is kept.

Opening the discharging opening 16 to let the prepared concentrates flow out from the discharging opening 16, which is switched off after the concentrates is drained off. Opening the feeding opening 15 to let the io mixture unconcentrated flow into the boiler, the feeding opening 15 is switched off when the mixture reaches the predetermined-density to isolate air in the boiler from the outside atmosphere for the next concentrating process.

Obviously, water in the accumulator unit 2 can be drained out during the is boiler is inputting mixture or outputting contracts. The detailed process is that, the ninth water valve is switched off firstly, then the sixth water valve is switched on, due to the pressure difference water in the confluence chamber is compressed to the accumulator unit 2; after the air pressure in the accumulator unit 2 and in the boiler is equal to the air pressure of the 20 outside atmosphere, water in the confluence chamber flows to the accumulator unit 2 under the gravity force, meanwhile the first water valve is switched on for draining of water from the accumulator unit 2.

The depressurization unit 4 is an air extracting pump or a vacuum pump. 25 The cooling unit 3 is provided with an input end and an output end, the cooling liquid flows into the cooling unit 3 from the input end, the cooling fin of the cooling unit 3 takes heat away from the cooling liquid into the /20 atmosphere so as to make the temperature of the cooling liquid from the output end of the cooling unit 3 cooler than the temperature of the cooling liquid from the input end of the cooling unit 3.

Claims

1. A concentrates preparation device, comprising a boiler unit (1), an accumulator unit (2), a cooling unit (3) and a depressurization unit (4), the boiler unit (1) having a sealing structure, and at a bottom portion thereof being provided with a feeding opening (15), a discharging opening (16) and 5 a heating unit (12); characterized in that a sidewall (13) of the boiler unit (1) is provided with a sampling unit (14) that is proximate to a bottom portion of the boiler unit (1), a cover (11) of the boiler unit (1) being provided with a condensing unit, inside the cover (11) being provided with a collecting portion of the condensing unit, io the collecting portion including a bar confluence rod (1103) which fits with an interior crown surface of a cover body (1101) and a confluence ring (1102) which fits with the interior crown surface of the cover body (1101), an opening of the confluence ring (1102) being toward a top portion of the cover body (1101), the confluence ring (1102) and the cover body (1101) is defining a confluence chamber, a tail end of the bar confluence rod (1103) extending to the confluence chamber which is communicated with an outside atmosphere through an output duct (1105); a cooling portion being located outside the cover (11), the cooling portion having a plurality of ringlike sheets (1104) coaxial with one another, 20 the ringlike sheet (1104) being arranged along an exterior crown surface of the cover body (1101), an axis of the ringlike sheet (1104) being coaxial with an axis of the cover body (1101), a bottom portion of the ringlike sheet (1104) fitting with the exterior crown surface of the cover body (1101), a top portion of the condensing unit being provided with a water inlet duct 25 (1106), a bottom portion of the condensing unit being provided with a water outlet duct (1107);

2. /5 the sampling unit (14) being provided with a base body (1401), a movable rod (1403), a limiting pin (1402), a sampling chamber (1405), a sampling bore (1404), an axle sleeve I, an axle sleeve II and an isobaric chamber (1409); the sampling chamber (1405) passing through a first and 5 second surface of the base body (1401), the isobaric chamber (1409) being a cylindrical blind bore, the isobaric chamber (1409) passing through a third surface of the base body (1401) and passing through a first and second surface of the sampling chamber (1405); the axle sleeve I having an interference fitting with the isobaric io chamber (1409), the movable rod (1403) hermetically slidingly mating with the axle sleeve I and the axle sleeve II, the limiting pin (1402) being fastened to the movable rod (1403), the limiting pin (1402) mating with the first or second surface of the sampling chamber (1405), inside the base body (1401) being provided with a gas permeable passage (1408), a head is end of the gas permeable passage (1408) communicating with the isobaric chamber (1409), a tail end of the gas permeable passage (1408) communicating with the outside atmosphere; the accumulator unit (2) being provided with a barrel (21), a first duct (210), a second duct (29), a third duct (28), a fourth duct (27), a first 20 water valve (25), a second water valve (24), a third water valve (23), a fourth water valve (22) and a water level tagging pipe (26); the barrel (21) communicating with the outside atmosphere through the first, second, third and fourth duct (210,29,28,27); the first, second, third and fourth duct (210,29,28,27) switching between opening and closing respectively through 25 the first, second, third and fourth water valve (25,24,23,22); the output duct (1105) of the confluence chamber of the boiler unit (1) communicating with the second water valve (24) of the accumulator 3. /5 unit (2), the water outlet duct (1107) of the cooling portion of the boiler unit (1) communicating with an input end of the cooling unit (3) through a fifth water valve, the water inlet duct (1106) of the cooling portion of the boiler unit (1) communicating with an output end of the cooling unit (3) 5 through a sixth water valve, the third water valve (23) of the accumulator unit (2) communicating with an input end of the depressurization unit (4) through a fifth duct, the first and fourth water valve (25,22) communicating with the outside atmosphere. io 2. A concentrates preparation device according to claim 1, characterized in that the bar confluence rod (1103) is provided with an abutment surface (1103a) corresponding to the interior crown surface of the cover body (1101), a first arcuate surface (1103b) being symmetrically arranged to is two side surfaces perpendicular to the abutment surface (1103a) to form an opposed invagination, a second arcuate surface (1103c) being arranged to a top surface parallel to the abutment surface (1103a) to form an opposed invagination, between the first and second arcuate surface (1103b,1103c) forming an overflow prevention edge (1103d), the bar confluence rod (1103) 20 proximate to a top end thereof being provided with a first slope (1103f) and a second slope (1103e), an angle formed by the first and second slope (1103f,1103e) being an obtuse angle, the second slope (1103e) sloping from a top end of the bar confluence rod (1103) to the abutment surface (1103a), the first slope (1103f) sloping from the top end of the bar confluence rod 25 (1103) to the abutment surface (1103a), the second arcuate surface (1103c) extending to the second slope (1103e), the first arcuate surface (1103b) extending to the first slope (1103f). 4. /5

3. A concentrates preparation device according to claim 1, characterized in that single-side section of the confluence ring (1102) is a form of a letter L, a bottom edge of the L being perpendicular to the interior 5 crown surface of the cover (11), a perpendicular edge of the L being parallel to the interior crown surface of the cover (11).

4. A concentrates preparation device according to claim 1, characterized in that io the movable rod (1403) is at a withdraw position and the sampling bore (1404) is outside the base body (1401) when the limiting pin (1402) mates with the first surface of the sampling chamber (1405); the movable rod (1403) being at an insertion position and the sampling bore (1404) being inside the sampling chamber (1405) when the limiting pin (1402) is mates with the second surface of the sampling chamber (1405).

5. A concentrates preparation device according to claim 1, characterized in that the gas permeable passage (1408) extends to the third surface of 20 the base body (1401), the sampling chamber (1405) of the sampling unit (14) being inside a boiler, a handle (1406) being outside the boiler.

6. A concentrates preparation device according to claim 1, characterized in that 25 the first duct (210) is located proximate to a bottom portion of the barrel (21), an interior opening of the second duct (29) being proximate to the bottom portion of the barrel (21) and above an interior opening of the 5/5 first duct (210), an interior openings of the third and fourth ducts (28, 27) being proximate to a top portion of the barrel (21), the second and third water valve (24,23) being fixedly connected with each other by a connecting block (20) so as to rotate together.