CN207831746U - A kind of fluid state ice ice machine with agitating function - Google Patents

Abstract

The utility model is related to a kind of fluid state ice ice machines with agitating function, including shell, cavity is provided in shell, heat-conducting cylinder is provided in cavity, cavity is divided into ice making cavity and refrigerating chamber, ice making cavity lower end is provided with water filling import, upper end is provided with Sorbet outlet, a shaft is coaxially arranged in ice making cavity, the rising of shaft outer periphery axial screw, which is provided with, send slab, shell is provided with motor, it send and is fixedly installed several inner cavity spoilers on slab, each inner cavity spoiler wherein side is close to shaft, the other side of the opposite side is along sending slab spiral direction to move closer to heat-conducting cylinder.Using the above scheme, it provides a kind of by the way that inner cavity spoiler is arranged on sending slab, so that fluid media (medium) moves under the action of the spoiler of inner cavity towards heat-conducting cylinder direction, so that fluid media (medium) is mixed close to heat-conducting cylinder position, it finally and under differential pressure action flows back to close to rotating shaft position, plays a kind of fluid state ice ice machine with agitating function of stirring action.

Description

A kind of fluid state ice ice machine with agitating function

Technical field

The utility model is related to a kind of ice machine, in particular to a kind of fluid state ice ice machines with agitating function.

Background technology

Ice machine is a kind of liquid water to be passed through refrigeration system so that liquid water carries out heat with the refrigerant in refrigeration system It exchanges, to make liquid water form a kind of refrigerating machine equipment of coast ice by way of cooling.

Fluid state ice ice machine is most commonly seen one of ice machine, for manufacturing stream of the state between fluid and solid State ice.Traditional fluid state ice ice machine is as shown in Fig. 2, include cylinder shell 1 ', shell 1 ' is interior to be run through in the vertical direction It is provided with cylinder cavity 11 ', and the axial direction of cavity 11 ' is identical as vertical direction, shell 1 ' is located at the axial direction of cavity 11 ' Both ends are respectively arranged with upper cover plate 12 ' and lower cover 13 ', are carried out 11 ' both ends of cavity by upper cover plate 12 ' and lower cover 13 ' In addition closing is provided with one piece of cylindrical circular heat-conducting cylinder 2 ' in cavity 11 ', and heat-conducting cylinder 2 ' is coaxially disposed with cavity 11 ', will Cavity 11 ' is divided into the ice making cavity 111 ' positioned at 2 ' inner wall side of heat-conducting cylinder and the refrigerating chamber 112 ' positioned at 2 ' outer wall side of heat-conducting cylinder, In, 111 ' lower end of ice making cavity is provided with water filling import 1111 ', and upper end is provided with Sorbet outlet 1112 ', in addition in ice making cavity 111 ' A shaft 4 ' is coaxially arranged with ice making cavity 111 ' in an axial direction, and upper cover plate 12 ' is fixed with the electricity of a drive shaft 4 ' rotation Machine 5 ', in addition, the rising of 4 ' outer periphery axial screw of shaft is provided with and send slab 3 '.It therefore can be by water filling import 1111 ' by liquid State water injects ice making cavity 111 ', and by filling refrigerant in refrigerating chamber 112 ' so that refrigerant passes through heat-conducting cylinder 2 ' and liquid State water carries out heat exchange, and to make liquid water be frozen into ice, during which, motor 5 ' drives shaft 4 ' and slab 3 ' is sent to rotate so that Liquid water and ice are together along sending slab 3 ' to rise, and since mixture of ice and water is always flowing during rising, because This so that the ice formed is in fluidised form shape, is finally discharged from Sorbet outlet 1112 ' in upper end fluid state ice and liquid water.

However above-mentioned this traditional fluid state ice ice machine is used, it is close to lead since refrigerant is located in refrigerating chamber The liquid water solidification of hot cylinder side is more abundant, and then heat exchange is less for the liquid water close to shaft side so that close to shaft side Liquid water can not be frozen into ice, in addition, the ice condensed close to heat-conducting cylinder side is since heat exchange is abundant so that be excessively frozen into The larger ice cube of particle does not meet fluid state ice requirement, therefore is only located at shaft and heat-conducting cylinder between the two in entire ice making cavity Middle position can just generate effective fluid state ice so that whole ice-maker makes ice inefficiency, and doping is solid in fluid state ice State ice so that ice making poor quality.

Utility model content

In view of the deficienciess of the prior art, the purpose of this utility model is to provide one kind by being arranged on sending slab Inner cavity spoiler so that when fluid media (medium) flows through inner cavity spoiler, moved towards heat-conducting cylinder direction under the action of spoiler in inner cavity, So that fluid media (medium) is mixed close to heat-conducting cylinder position, finally and under differential pressure action flows back to close to rotating shaft position, play and stir Mix a kind of fluid state ice ice machine with agitating function of effect.

To achieve the above object, the utility model provides following technical solution：Including shell, it is provided in the shell For the cavity of ice making, one piece of cylindrical circular heat-conducting cylinder, and heat-conducting cylinder axial direction and vertical identical, institute are provided in the cavity It states cavity by heat-conducting cylinder to be divided into for the ice making cavity of filling liquid water and the refrigerating chamber for filling refrigerant, and ice making cavity is located at Heat-conducting cylinder inner wall side, refrigerating chamber are located at heat-conducting cylinder outer wall side, and the ice making cavity lower end is provided with water filling import, and upper end is provided with ice Sand outlet, is coaxially arranged with a shaft in the ice making cavity, and the shaft outer periphery axial screw rising is provided with for will Send slab of the mixture of ice and water from water filling import towards Sorbet outlet delivery, the shell are provided with the electricity that drive shaft circumferentially rotates Machine, described send is fixedly installed several inner cavity spoilers for stirring the fluid media (medium) in ice making cavity on slab, each described interior Chamber spoiler wherein side is close to shaft, and the other side of the opposite side is along sending slab spiral direction to move closer to heat conduction Cylinder.

By using above-mentioned technical proposal, since ice making needs to absorb heat to liquid water using refrigerant so that liquid Water is frozen into ice, therefore by the way that heat-conducting cylinder is arranged in cavity so that and cavity is divided into refrigerating chamber and ice making cavity by heat-conducting cylinder, to Refrigerant can be added to refrigerating chamber so that the refrigeration in refrigerating chamber by the way that liquid water is added to ice making cavity from water filling import Agent absorbs liquid water in ice making cavity, and liquid water is caused to be frozen into ice, during which, motor drive shaft and wiper into Row rotation so that mixture of ice and water transmits from bottom to up under the drive of wiper, and is gradually coagulated in transmission process liquid water Gu at fluid state ice, it is discharged to be exported from the Sorbet of upper end.In addition, in order to make the icing rate higher of fluid state ice, in ice making cavity Inner cavity spoiler is set, as shown in Figure 3 so that with the mixture of ice and water of the directions v1 flowing in sending slab rotation process, by The interference of inner cavity spoiler and flowed along the directions v2, and constantly converged towards heat-conducting cylinder direction so that close to heat-conducting cylinder inner wall The pressure of side increases, therefore fluid is constantly turned by close heat-conducting cylinder side towards close along the direction v3, v4 under the action of pressure difference Axis side is flowed, to play from Inside To Outside mixed flow, then the flow regime of mixed flow inwardly again.It the advantage is that：It is interior The setting of chamber spoiler so that making fluid by sending the rotation of slab, slab radial direction is constantly inside and outside to be mixed along sending so that is leaned on The lower fluid of temperature outside and the higher fluid temperature (F.T.) of temperature in the inner part are complementary, can not only make the liquid water close to inside abundant Heat release and be frozen into fluid state ice, and liquid water in the outer part is made to be unlikely to excessive solidification at solid ice, therefore by inner cavity No matter the liquid water of spoiler effect close to heat-conducting cylinder side is also proximate to shaft side in entire ice making cavity, and equal solidifiable generates Fluid state ice greatly improves the ice making efficiency of fluid state ice.

The utility model is further arranged to：Each inner cavity spoiler length direction is arranged in an axially parallel mode with shaft, respectively The inner cavity spoiler length is identical as the screw pitch of slab is sent, and the both ends of each inner cavity spoiler length are fixedly installed on phase respectively Adjacent send slab.

By using above-mentioned technical proposal, the length direction of inner cavity spoiler is identical as the screw pitch of slab is sent, and by length The both sides in direction, which are fixed on, send slab upper and lower ends, therefore inner cavity spoiler can be to the fluid of any level position in a screw pitch Medium plays the role of flow-disturbing so that flow-disturbing is more abundant.

The utility model is further arranged to：Each inner cavity spoiler is equidistantly arranged along sending slab spiral direction Cloth, and horizontal position is higher bigger with shaft spacing.

By using above-mentioned technical proposal, the inner cavity spoiler of spaced set makes flow-disturbing effect more uniform, most Big degree plays the role of flow-disturbing；In addition to this, each inner cavity spoiler is not arranged in identical radial position so that disturbs inner cavity The spacing of flowing plate to heat-conducting cylinder and shaft is unalterable, but selects inner cavity spoiler with the gradual court of the raising of horizontal position Heat-conducting cylinder direction is close, therefore can make innermost fluid under the action of inner cavity spoiler in layer constantly towards heat conduction Cylinder direction is close, to reach maximum mixing effect, and and non local stirring.

The utility model is further arranged to：The refrigerating chamber lower end is provided with refrigerant inlet, and upper end is provided with refrigeration Agent exports, and is provided with the deflector of guiding refrigerant flowing in the refrigerating chamber, and the deflector along refrigerating chamber from down toward Upper spiral setting.

By using above-mentioned technical proposal, in order to enable refrigerant adequately to carry out heat exchange with ice making cavity, in refrigerating chamber It is interior that the deflector helically risen is set, and by refrigerant inlet setting in refrigerating chamber bottom end, refrigerant outlet setting is being freezed Agent upper end so that refrigerant enters from bottom end, and along the gradual spiral of deflector, is finally left from upper end, so that Refrigerant is fully contacted with heat-conducting cylinder, improves capacity usage ratio.

The utility model is further arranged to：Several refrigeration for hybrid refrigeration intracavitary are provided in the refrigerating chamber The exocoel spoiler of agent, each exocoel spoiler edge are parallel to deflector direction helical arrangement and are set to refrigerating chamber.

By using above-mentioned technical proposal, exocoel spoiler is set in refrigerating chamber so that refrigerant is flowing through exocoel flow-disturbing When part, had to be flowed around exocoel spoiler by the interference of exocoel spoiler, to cause refrigerant in exocoel The rear of spoiler forms the vortex phenomenons such as Karman vortex street so that the refrigerant under laminar condition, which shows, destroys laminar condition simultaneously The phenomenon that being mutually mixed, after being mutually mixed, the refrigerant of same pitch position is nearly at same temperature state so that refrigerant Heat exchange more fully is carried out with heat-conducting cylinder, to improve production efficiency, in addition, exocoel spoiler edge is parallel to deflector Direction helical arrangement so that mutually across a certain distance, just refrigerant is disturbed there are one exocoel spoiler, to adequately right Refrigerant in entire refrigerating chamber is mixed, and production efficiency is greatly improved.

The utility model is further arranged to：Each exocoel spoiler includes the refrigerant for will be far from heat-conducting cylinder side With close to heat-conducting cylinder side the first spoiler for being mutually mixed of refrigerant and for the upper end in the same screw pitch of refrigerating chamber to be freezed The second spoiler that agent and lower end refrigerant are mutually mixed, in each exocoel spoiler the quantity of the first spoiler be one piece, The quantity of second spoiler is two pieces, and first spoiler one end is fixedly installed on heat-conducting cylinder, and the other end is along runner direction It is gradually distance from heat-conducting cylinder, two pieces of second spoiler one end are fixedly installed on the first spoiler both sides up and down, the other end respectively Adjacent deflector is moved closer to along the flow direction of refrigerant, is arranged in being flared along refrigerant flow direction.

By using above-mentioned technical proposal, analyzed it is found that in the same horizontal position, due in refrigerating chamber by actual conditions Do not contacted with heat-conducting cylinder far from the refrigerant of heat-conducting cylinder side, thus its to absorb heat from heat-conducting cylinder less so that heating compared with Slowly, temperature is relatively low, and the refrigerant in refrigerating chamber close to heat-conducting cylinder side is in direct contact with heat-conducting cylinder, therefore it absorbs and comes from heat conduction The heat of cylinder is more so that heating is very fast, and temperature is higher, so the refrigerant far from heat-conducting cylinder side does not carry out energy adequately It exchanges so that after a cycle, energy is not fully utilized and reduces production efficiency, the utility model setting first Spoiler will be far from the refrigerant of heat-conducting cylinder side by the first spoiler and the refrigerant close to heat-conducting cylinder side be mutually mixed, from And so that the refrigerant temperature close to heat-conducting cylinder side declines, and can more fully absorb the heat on heat-conducting cylinder.Except this it Outside, it is gradually increasing along deflector due to refrigerant, refrigerant is gradually absorbed heat in uphill process and temperature is made to get over Come higher, under same screw pitch, equally show identical temperature gradient, thus due to the refrigerant temperature of top is higher, under The refrigerant temperature of side is relatively low, to cause the heat-conducting cylinder hot swap condition of different level position under same screw pitch different so that Heat exchange is uneven to thereby reduce production efficiency and the quality of production, and the second spoiler is arranged in utility model, is disturbed by second Upper end refrigerant in the same screw pitch of refrigerating chamber is mutually mixed by flowing plate with lower end refrigerant, so that upper and lower ends refrigerant Temperature is identical, not only more fully absorbs the heat on heat-conducting cylinder, and improves ice making quality.In addition to this, One spoiler one end is fixed on heat-conducting cylinder, and the other end is gradually distance from heat-conducting cylinder, therefore as shown in figure 4, system along runner direction Cryogen with the directions v5 when flowing to the first spoiler, it will is flowed to far from heat-conducting cylinder direction with the directions v6 along the first spoiler It is dynamic so that refrigerant is mutually mixed, and after blending, cause refrigerating chamber to increase far from pressure at heat-conducting cylinder, close to heat-conducting cylinder Locate pressure to reduce, under the drive of pressure, flow away, make towards heat-conducting cylinder with the directions v7 far from the refrigerant at heat-conducting cylinder again Obtaining the refrigerant temperature at heat-conducting cylinder reduces, to play the system of refrigerant of the mixing far from heat-conducting cylinder side and close heat-conducting cylinder side The effect of cryogen.In addition, being arranged two piece of second spoiler in the first spoiler both sides, and set in flaring along flow direction Set, therefore as shown in figure 5, refrigerant when flowing to the second spoiler with the directions v5, it will along the second spoiler with the directions v8 It is flowed to upper and lower both sides, to be mutually mixed with the refrigerant of upper and lower ends, later due to upper and lower ends and spoiler horizontal position The place of setting forms pressure difference so that and refrigerant is flowed with the directions V9 again, forms Karman vortex street phenomenon, and under Karman vortex street phenomenon, Refrigerant is mutually mixed, to play the role of the upper end refrigerant in the same screw pitch of hybrid refrigeration chamber and lower end refrigerant.

The utility model is further described with reference to the accompanying drawings and detailed description.

Description of the drawings

Fig. 1 is the elevational cross-sectional view of specific embodiment of the present invention；

Fig. 2 is the elevational cross-sectional view of traditional ice machine；

Fig. 3 is flow regime of the ice making cavity fluid under the effect of inner cavity spoiler in specific embodiment of the present invention Figure；

Fig. 4 is flow regime figure of the refrigerant under the effect of the first spoiler in specific embodiment of the present invention；

Fig. 5 is flow regime figure of the refrigerant under the effect of the second spoiler in specific embodiment of the present invention；

Fig. 6 is the installation diagram of heat-conducting cylinder, deflector and spoiler in specific embodiment of the present invention；

Fig. 7 is the part drawing of spoiler in specific embodiment of the present invention；

Fig. 8 is the enlarged drawing of A in Fig. 1.

Specific implementation mode

It is new to this practicality below in conjunction with attached drawing to keep the purpose of this utility model, technical solution and advantage clearer Type is described in further detail.

As shown in Figure 1, the utility model discloses a kind of fluid state ice ice machine with agitating function, including one is in cylinder The shell 1 of body, coaxially opens up that there are one cylinder cavitys 11 in shell 1 in an axial direction, and cavity 11 runs through down vertically The both ends of shell 1 in addition, the axial both ends that shell 1 is located at cavity 11 are respectively arranged with upper cover plate 12 and lower cover 13, and pass through Upper cover plate 12, lower cover 13 are fixedly connected by bolt with shell 1 so that cavity 11 forms an enclosure space, makes for ice making With.

In addition, one piece of cylindrical circular heat-conducting cylinder 2 is provided in the present embodiment hollow cavity 11, and heat-conducting cylinder 2 and cavity 11 Coaxial arrangement, and cavity 11 is divided into ice making cavity 111 and refrigerating chamber 112, wherein ice making cavity 111 is located at 2 inner wall side of heat-conducting cylinder, Refrigerating chamber 112 is located at 2 outer wall side of heat-conducting cylinder, therefore can be filled out in refrigerating chamber 112 by the filling liquid water in ice making cavity 111 Fill refrigerant（Wherein freon etc. can be used in refrigerant）So that the liquid in refrigerant suction ice making cavity 111 in refrigerating chamber 112 The heat of state water, to make liquid water solidification freeze.In addition, upper cover plate 12 and lower cover 13 are located at the setting of 2 outer wall side of heat-conducting cylinder There is ring type seal 6, and the ring type seal 6 on upper cover plate 12 is extruded between upper cover plate 12 and heat-conducting cylinder 2, on lower cover 13 Ring type seal 6 be extruded between lower cover 13 and heat-conducting cylinder 2, therefore by ring type seal 6 and heat-conducting cylinder 2 by ice making cavity 111 with refrigerating chamber 112 mutually completely cut off, structure as shown in figure 8, and shell 1 and the sealing means of upper cover plate 12 and lower cover 13 it is same Reason setting.

In addition, being provided with a water injection pipe 131 in the present embodiment on lower cover 13, wherein water injection pipe 131 is L-shaped, and one End extends in ice making cavity 111, the other end is set to 13 downside of lower cover so that water injection pipe 131 is formed in 111 inner end of ice making cavity Water filling import 1311, similarly, upper cover plate 12 are provided with cylindrical circular Sorbet pipe 121, and are provided with Sorbet on Sorbet pipe 121 and go out Mouth 1211 so that the Sorbet in ice making cavity 111 can pass through Sorbet and export 1211 discharges.

In addition, being provided with a shaft 3 being coaxially disposed with ice making cavity 111, shaft in ice making cavity 111 in the present embodiment 3 axial both ends are rotatablely connected by ball bearing and upper cover plate 12 and lower cover 13 respectively, in addition, 3 outer periphery axial screw of shaft It screws on to rise and is provided with and send slab 31, wherein sending slab 31 solid by the modes such as welding or being wholely set close to 3 end of shaft and shaft 3 Fixed connection, far from 3 end of shaft and 2 clearance fit of heat-conducting cylinder, and fit clearance is less than 1cm, therefore by sending 31 periphery of slab can Play the role of striking off to the ice sheet on 2 inner wall of heat-conducting cylinder, in addition 12 upper end of upper cover plate is provided with a motor 122 and retarder 123, Rotating speed is exported by retarder 123 and is acted on shaft 3 by motor 122, and shaft 3 is made to circumferentially rotate, and wherein motor 122 passes through spiral shell Bolt is fixedly connected on upper cover plate 12.Therefore, it when motor 122 starts, drives shaft 3 and slab 31 is sent to rotate so that send slab 31 liquid waters that can will be close to 1311 end of water filling import along spiral direction export 1211 directions towards Sorbet from bottom to up and transmit.

In addition, sending in the present embodiment is fixedly installed several inner cavity spoilers 4 for stirring ice making cavity 111 on slab 31 Interior fluid media (medium), wherein inner cavity spoiler 4 is in rectangular parallelepiped structure, and length direction is arranged in an axially parallel mode with shaft 3, size It is identical as the pitch size of slab 31 is sent, therefore the both sides difference of each inner cavity spoiler 4 along its length is by welding Send slab 31 to be fixedly connected with adjacent, in addition, as shown in figure 3, the side of inner cavity spoiler 4 in the width direction close to shaft 3, The other side of the opposite side is gradually arranged towards far from 3 direction of shaft along sending 31 spiral direction of slab so that inner cavity flow-disturbing Plate 4 and the shaft 3 of corresponding position are radial in a certain angle, wherein preferably, as shown in figure 3, angle is in 30 °.Therefore, slab is sent 31 in rotation process, makes fluid media (medium) along the directions v1 relative flow, and by the effect of inner cavity spoiler 4 and towards heat-conducting cylinder 2 Direction mixed flow so that 2 side pressure of heat-conducting cylinder increases by force, towards 3 side mixed flow of shaft under differential pressure action so that fluid state ice freezing efficiency is more It is high.

Preferably, each inner cavity spoiler 4 in the present embodiment is along sending 31 spiral direction of slab equidistantly to arrange, and Horizontal position is higher bigger with 3 spacing of shaft, and 6 inner cavities are provided in the screw pitch that wherein the present embodiment send slab 31 at one and are disturbed Flowing plate 4, and centered on a shaft 3, angularly array is in sending on slab 31, and angle is 60 °, in addition, 6 spoilers are with level Height is to put in order, and the spacing to shaft 3 is sequentially increased, and adjacent increase spacing is identical, is slightly less than（In heat-conducting cylinder 2 3 outer diameter of diameter-shaft）/5.Therefore most inner side fluid in a screw pitch in order by lower by 6 pieces of inner cavity deflectors 16 Effect so that fluid from close to 3 side of shaft be moved to close to 2 side of heat-conducting cylinder realize to the greatest extent across and form maximum pressure It is strong poor, keep mixed flow more abundant so that fluid state ice freezing efficiency higher.

In addition, the present embodiment middle casing 1, which is located on the side wall of lower end, is equipped with a refrigerant inlet pipe 14, and refrigerant into Pipe 14 extends to 1 inside of shell outside shell 1 and is connected to refrigerating chamber 112, and shell 1, which is located on the side wall of upper end, to be worn Have a refrigerant outlet pipe 15, and refrigerant outlet pipe 15 extended to outside shell 11 inside of shell and with refrigerating chamber 112 Connection, in addition, refrigerant inlet pipe 14, which is located in refrigerating chamber 112, is provided with refrigerant inlet 141, refrigerant outlet pipe 15 is located at refrigeration Refrigerant outlet 151 is provided in chamber 112, therefore can be by carrying out injection refrigerant to refrigerant inlet pipe 14, refrigerant passes through Refrigerant inlet 141 enters refrigerating chamber 112, and is moved upwards along refrigerating chamber 112, eventually by refrigerant outlet 151 and from Refrigerant outlet pipe 15 is left.

In addition, be provided with deflector 16 in refrigerating chamber 112 in the present embodiment, and deflector 16 was along refrigerating chamber 112 weeks It is arranged to spiral from bottom to up, wherein deflector 16 is welded close to 2 side of heat-conducting cylinder and heat-conducting cylinder 2, close to 1 side of shell and shell Body 1 welds so that refrigerant only can not be ramped vertically along 16 spiral of deflector, therefore be increased greatly Residence time of the refrigerant in refrigerating chamber 112 is added, to carry out refrigeration to the greatest extent.

As shown in fig. 6, in addition, being provided with several exocoel spoilers 5, and exocoel in refrigerating chamber 112 in the present embodiment Spoiler 5 is arranged in 2 outer wall of heat-conducting cylinder along the hand of spiral for being parallel to deflector 16, therefore refrigerant is along deflector 16 Exocoel spoiler 5 will be constantly met during rising, and is constantly shunted simultaneously under the action of exocoel spoiler 5 There are the vortex phenomenons such as Karman vortex street, to play the role of mix refrigerant.

Wherein, it is preferred that the spacing in the present embodiment between two neighboring exocoel spoiler 5 is identical so that refrigerant Mixing is more uniform, and will produce certain vibration since refrigerant flows through exocoel spoiler 5, and spaced set exocoel is disturbed Flow part 5 so that can cancel out each other between vibration, reduce Oscillation Amplitude, ice machine work is made more to stablize.

As shown in fig. 7, additionally, it is preferred that, each exocoel spoiler 5 in the present embodiment includes the first spoiler 51 and the Two spoilers 52, wherein the first spoiler 51 is used to will be far from the refrigerant of the refrigerant and close 2 side of heat-conducting cylinder of 2 side of heat-conducting cylinder It is mutually mixed, the second spoiler 52 is used to lower end refrigerant mutually mix the upper end refrigerant in 112 same screw pitch of refrigerating chamber It closes, it is preferred that the quantity of the first spoiler 51 in each exocoel spoiler 5 is one, and the quantity of the second spoiler 52 is Two, wherein 51 one end of the first spoiler is fixed on heat-conducting cylinder 2, the other end is gradually distance from heat-conducting cylinder 2 along runner direction, from And to have a certain degree along runner direction shape between the first spoiler 51 and heat-conducting cylinder 2 so that formed as shown in Figure 4 Flow regime, in addition, two piece of second deflector 16 is respectively fixedly disposed at the both sides up and down of the first spoiler 51, wherein fixation side The modes such as integrated molding setting or welding can be used in formula, and two piece of second 52 streamwise of spoiler is arranged in flaring, makes It obtains the first spoiler 51 and the second spoiler 52 forms the shape of similar isosceles trapezoid, therefore refrigerant is in the second spoiler 52 Flow regime as shown in Figure 5 is formed under effect.

Preferably, the first spoiler 51 in the present embodiment is fixedly installed fixed plate 53 close to 2 end of heat-conducting cylinder, wherein solid Fixed board 53 is arranged in parallel with heat-conducting cylinder 2, and offers a through-hole for passing through fixed plate 53 and heat-conducting cylinder 2 in fixed plate 53 The modes such as bolt, riveting connect.In addition, fixed plate 53 and heat-conducting cylinder 2 are fixedly connected there are many modes, such as welding, one The modes such as molding.

Claims (6)

1. a kind of fluid state ice ice machine with agitating function, including shell, the cavity for ice making is provided in the shell, Be provided with one piece of cylindrical circular heat-conducting cylinder in the cavity, and heat-conducting cylinder it is axial with it is vertically identical, the cavity is by heat-conducting cylinder It is divided into for the ice making cavity of filling liquid water and the refrigerating chamber for filling refrigerant, and ice making cavity is located at heat-conducting cylinder inner wall side, Refrigerating chamber is located at heat-conducting cylinder outer wall side, and the ice making cavity lower end is provided with water filling import, and upper end is provided with Sorbet outlet, the system Ice intracavitary is coaxially arranged with a shaft, the shaft outer periphery axial screw rising be provided with for by mixture of ice and water from note For water inlet towards the slab that send of Sorbet outlet delivery, the shell is provided with the motor that drive shaft circumferentially rotates, it is characterised in that： Described send is fixedly installed several inner cavity spoilers for stirring the fluid media (medium) in ice making cavity on slab, each inner cavity is disturbed Flowing plate wherein side is close to shaft, and the other side of the opposite side is along sending slab spiral direction to move closer to heat-conducting cylinder.

2. a kind of fluid state ice ice machine with agitating function according to claim 1, it is characterised in that：Each inner cavity Spoiler length direction is arranged in an axially parallel mode with shaft, and each inner cavity spoiler length is identical as the screw pitch of slab is sent, and each The both ends of inner cavity spoiler length are fixedly installed on respectively adjacent send slab.

3. a kind of fluid state ice ice machine with agitating function according to claim 1, it is characterised in that：Each inner cavity Spoiler is along sending slab spiral direction equidistantly to arrange, and horizontal position is higher bigger with shaft spacing.

4. a kind of fluid state ice ice machine with agitating function according to claim 1, it is characterised in that：The refrigerating chamber Lower end is provided with refrigerant inlet, and upper end is provided with refrigerant outlet, and guiding refrigerant flowing is provided in the refrigerating chamber Deflector, and along refrigerating chamber, spiral is arranged the deflector from bottom to up.

5. a kind of fluid state ice ice machine with agitating function according to claim 4, it is characterised in that：The refrigerating chamber Several exocoel spoilers for the refrigerant of hybrid refrigeration intracavitary are inside provided with, each exocoel spoiler edge, which is parallel to, leads Flowing plate direction helical arrangement is set to refrigerating chamber.

6. a kind of fluid state ice ice machine with agitating function according to claim 5, it is characterised in that：Each exocoel Spoiler includes the first flow-disturbing for will be far from the refrigerant of heat-conducting cylinder side be mutually mixed close to the refrigerant of heat-conducting cylinder side Plate and the second spoiler for upper end refrigerant and the lower end refrigerant in the same screw pitch of refrigerating chamber to be mutually mixed, it is each described The quantity of the first spoiler is one piece in exocoel spoiler, the quantity of the second spoiler is two pieces, first spoiler one end It is fixedly installed on heat-conducting cylinder, the other end is gradually distance from heat-conducting cylinder, two pieces of second spoiler one end difference along runner direction Being fixedly installed on the first spoiler, both sides, the other end move closer to adjacent deflector along the flow direction of refrigerant up and down, It is arranged in being flared along refrigerant flow direction.