CN106642859A

CN106642859A - Ice producing assembly and method for controlling temperature of ice producing cavity

Info

Publication number: CN106642859A
Application number: CN201611190271.3A
Authority: CN
Inventors: 邵阳; 司增强
Original assignee: Hefei Hualing Co Ltd; Midea Group Co Ltd; Hefei Midea Refrigerator Co Ltd
Current assignee: Hefei Hualing Co Ltd; Midea Group Co Ltd; Hefei Midea Refrigerator Co Ltd
Priority date: 2016-12-21
Filing date: 2016-12-21
Publication date: 2017-05-10
Anticipated expiration: 2036-12-21
Also published as: WO2018113183A1; CN106642859B

Abstract

The invention relates to an ice producing assembly, which comprises an ice producing cavity, an ice producing machine arranged in the upper part of the interior of the ice producing cavity, and an ice storage box arranged in the lower part of the interior of the ice producing cavity. The ice producing assembly also comprises a movable partition plate, which is arranged between the ice producing machine and the ice storage box and is used to communicate/partition the ice producing machine and the ice storage box; a fan, which is arranged in the opening in the upper end of the ice producing cavity; an ice storage area temperature sensor, which is arranged in the lower part of the ice storage box, is connected to the inner wall of the ice storage box, and is used to collect the actual temperature of the ice storage area; and a microprocessor, which is connected to the ice storage area temperature sensor, receives the actual temperature collected by the ice storage area temperature sensor, is connected to the fan, and controls the operation mode of the fan. The ice producing assembly has the advantages that the ice producing area and the ice storage area are separated; the energy loss is reduced, the ice output is increased, and the temperature can be simply controlled.

Description

A kind of temperature-controlled process of Icemaker assembly and ice making cavity

Technical field

The present invention relates to refrigerating equipment field, specifically, is related to the temperature control of a kind of Icemaker assembly and ice making cavity Method.

Background technology

Ice machine of the prior art is typically mounted at a back, and ice bank (ice storage barrel) is rest directly upon the ice machine Lower section, after ice machine full ice, ice cube is fallen directly in the ice bank.Now ice machine is complete with the space residing for ice bank Full-mesh, ice making and ice storage in same cavity, so temperature and ice machine of the ice machine in ice-making process in ice bank Environment temperature is close, and the actually required storage temperature of ice cube is higher relative to ice making temperature, thus causes cold Loss, in turn results in corresponding ice-making capacity and reduces.In addition when ice machine begins to warm up and deices, ice machine heating wire works, meeting Ice machine environment temperature is increased, cause the temperature in ice bank fluctuation occur, affect the storage of ice cube.

The content of the invention

The technical problem to be solved is to provide a kind of Icemaker assembly for separating ice making area and ice storage area and carries For a kind of temperature control scheme to after ice making and ice storage separation.

The technical scheme that the present invention solves above-mentioned technical problem is as follows：

The present invention provides a kind of Icemaker assembly, including ice making cavity, installed in the ice machine on ice making inside cavity top, with And positioned at the ice bank of ice making cavity body inner lower, also include：

Active clapboard, the active clapboard be arranged between ice machine and ice bank for connect or separate ice machine and Ice making cavity is divided into ice making area and ice storage area two parts by ice bank, the active clapboard；

Fan, the fan is arranged at the opening of ice making cavity upper end, what the open communication ice making evaporator was located Cavity and ice making cavity；

Ice storage area temperature sensor, the ice storage area temperature sensor is located at ice bank bottom and is connected to the interior of ice bank On wall, for gathering ice storage area actual temperature；

Microprocessor, the microprocessor is connected with ice storage area temperature sensor and receives ice storage area temperature sensor and adopts The ice storage area actual temperature of collection, the microprocessor is connected with fan and controls the operational mode of fan.

The invention has the beneficial effects as follows：Ice making and ice storage subregion, reduce energy loss, lift ice-making capacity；Avoid ice machine Begin to warm up when deicing, cause the temperature in ice bank fluctuation occur, affect the storage of ice cube；Ice making and ice storage subregion, ice storage Room temperature is of a relatively high, and alveolar layer around storage chamber can be made thinning, increases the size of ice bank, and then increases ice storage amount；Ice storage The cooperation of area's temperature sensor and microprocessor can separate after ice storage area temperature simple control, it is not necessary to add other again Device, realizes the simplification of structure.

On the basis of above-mentioned technical proposal, the present invention can also do following improvement.

Further, also including ice making area temperature sensor, the ice making area temperature for gathering ice making area actual temperature Sensor is located at the top of ice machine and is connected on ice making cavity inner wall；The microprocessor and ice making area temperature sensor phase Connect and receive the ice making area actual temperature of ice making area temperature sensor collection.

It is using the beneficial effect of above-mentioned further scheme：By add ice making area's temperature sensor and with microprocessor phase Coordinate, realize the monitoring and collection of the temperature to ice making area, and then make temperature control more sophisticated.

Further, the Icemaker assembly also includes stationary barrier, and one end of the stationary barrier is another with ice making cavity Side wall is fixedly connected, and one end of the active clapboard is connected with the side wall of ice making cavity and turns by rotary shaft of connection end Dynamic, the active clapboard front of motor contacts with stationary barrier or separates.

It is using the beneficial effect of above-mentioned further scheme：Stationary barrier and active clapboard with the use of can be more preferable The compartment, and the event trace of active clapboard is reduced, making is installed and gets up more convenient.

Further, the active clapboard is provided with multiple equally distributed ventilating openings.

It is using the beneficial effect of above-mentioned further scheme：The setting of ventilating opening makes the part cold air in ice making region can be with Ice storage region is blowed to, so as to ensure the temperature of ice storage.

Further, the active clapboard includes clapboard body and two engaging lugs, and described two engaging lugs are fixedly connected on The both sides of clapboard body one end；There are the connecting plate for extending internally, two engaging lug difference on the ice making cavity inner wall It is connected by connector with the connecting plate, the clapboard body is provided with multiple equally distributed ventilating openings, the dividing plate The other end of body contacts with stationary barrier.

Further, the pivot of the center of gravity of the active clapboard and the active clapboard is in same vertical straight line.

It is using the beneficial effect of above-mentioned further scheme：The center of gravity of active clapboard is with the point of rotation of dividing plate same vertical On line, it is ensured that the original state of active clapboard is heeling condition, when ice cube falls on active clapboard, active clapboard is subject to downward Power, active clapboard is just opened, and when ice cube falls completely, active clapboard recovers initial position under self gravitation, continues To temperature insulating.

Further, also including the dynamic clamping head and quiet clamping head being connected between the ice making cavity inner wall and clapboard body, it is described every Plate body is separated under external force with stationary barrier, recover in the presence of dynamic clamping head and quiet clamping head after external force terminates to it is solid The position that determine dividing plate contacts.

It is using the beneficial effect of above-mentioned further scheme：By the elastic force and the resistance of stationary barrier of elastic component, it is ensured that The original state of active clapboard is heeling condition, and when ice cube falls on active clapboard, active clapboard is forced downwards, activity Dividing plate is just opened, and when ice cube falls completely, active clapboard recovers initial position under self gravitation, continues to play thermal insulation work With.

Further, the dynamic clamping head and quiet clamping head is elastic circlip, and the connector is bolt, and the elastic circlip is socketed in spiral shell On bolt, the engaging lug and connecting plate are and are equipped with through hole, and the engaging lug and connecting plate are two, and described two Individual connecting plate is located at the outside of described two engaging lugs, and the screw bolt passes are simultaneously set on engaging lug and connecting plate In through hole, one end of the elastic circlip is connected with ice making cavity inner wall, and the other end is connected with clapboard body.

It is using the beneficial effect of above-mentioned further scheme：There is provided one kind specifically disclosure satisfy that active clapboard in ice making The scheme of compartment when rotating ice storage.

Further, the active clapboard is MOD.

Further, the minimum range on the ice bank between edge and active clapboard pivot is less than the active clapboard Length.

The Icemaker assembly also includes ice making evaporator, and the ice making evaporator is connected to the top of ice making cavity, described Fan is arranged at the opening of ice making cavity upper end, cavity and ice making cavity that the open communication ice making evaporator is located.

The invention further relates to a kind of refrigerator, including Icemaker assembly as above, the Icemaker assembly is installed in refrigerator doors On body or in the storage chamber of refrigerator.

The invention further relates to a kind of temperature-controlled process of ice making cavity, by the system as described in claim 1-7 is arbitrary Ice component is realized, comprised the steps：

1) ice storage area preset temperature W2 is set in microprocessor；

2) ice storage area temperature sensor gathers actual temperature T2 of ice storage area and is transferred in microprocessor；

3) microprocessor is by comparative analysis ice storage area preset temperature W2 and the relation of actual temperature T2 of ice storage area, control The operational mode of fan.

A kind of beneficial effect of temperature-controlled process of ice making cavity of the present invention is：There is provided a kind of ice making to separate with ice storage Temperature-controlled process；The cooperation of ice storage area temperature sensor and microprocessor can separate after ice storage area temperature simple control System, it is not necessary to add other devices again, realize the simplification of structure.

Further, the step 3) including following situation：

3-1) when ice making function is opened, in ice-making process,

If W2 is ＞ T2, fan slow-speed of revolution operation,

If W2 is ＜ T2, the high rotating speed operation of fan；

3-2) when ice making function is opened, deice or water filling during, stopping fan rotation；

3-3) when ice making function is closed,

If W2 is ＞ T2, stopping fan rotation,

If W2 is ＜ T2, fan slow-speed of revolution operation.

Wherein described fan is that fan is commonly used in refrigerator, and the fan at least has the operation of high rotating speed and slow-speed of revolution operation two The pattern of kind.

It is using the beneficial effect of above-mentioned further scheme：Temperature control of the detailed differentiation under difference in functionality state Method, effectively while control temperature, reduces excessive control unit so that simple structure, and energy loss is reduced.

Further, the Icemaker assembly also includes ice making area temperature sensor, and ice making area temperature sensor is located at system The top of ice maker is simultaneously connected on ice making cavity inner wall, for gathering ice making area actual temperature；The microprocessor and ice storage area Temperature sensor is connected and receives the ice storage area actual temperature of ice storage area temperature sensor collection；

The step 1) in be additionally included in microprocessor ice making area preset temperature W1 be set；The step 2) in also include Actual temperature T1 in temperature sensor collection ice making area of ice making area is simultaneously transferred in microprocessor；The step 3) including following feelings Condition：

3-1) when ice making function is opened, in ice-making process,

If W1 is ＞ T1, W2 ＞ T2, stopping fan rotation or microcirculation,

If W1 is ＜ T1, W2 ＞ T2, fan slow-speed of revolution operation,

If W2 is ＜ T2, the high rotating speed operation of fan；

3-3) when ice making function is closed,

If W2 is ＞ T2, stopping fan rotation,

If W2 is ＜ T2, fan slow-speed of revolution operation.

Wherein described fan is that fan is commonly used in refrigerator, and the fan at least has the operation of high rotating speed and slow-speed of revolution operation two The pattern of kind, when only there is fan the operation of high rotating speed and the slow-speed of revolution to run both of which, when ice making function is opened, in ice making Cheng Zhong, if W1 is ＞ T1, W2 ＞ T2, stopping fan rotation；If fan has high rotating speed operation, slow-speed of revolution operation and microcirculation three During the pattern of kind, when ice making function is opened, in ice-making process, if W1 is ＞ T1, W2 ＞ T2, fan operation microcirculation pattern is pole Slowly run.It is using the beneficial effect of above-mentioned further scheme：Ice making area of the detailed differentiation under difference in functionality state With the temperature-controlled process of ice storage area, effectively while control temperature, excessive control unit is reduced so that structure letter Single, energy loss is reduced.

Further, the step 1) in, the ice making area preset temperature W1 is -25 DEG C～-10 DEG C, and the ice storage area is preset Temperature W2 is -10 DEG C～0 DEG C.

It is using the beneficial effect of above-mentioned further scheme：The interval setting of said temperature can meet ice making and ice storage need Ask, unnecessary energy loss is avoided that again.

Description of the drawings

Fig. 1 is the structural representation of the Icemaker assembly when active clapboard of the present invention is closed；

Fig. 2 is the structural representation of the Icemaker assembly when active clapboard of the present invention is opened；

Fig. 3 is the side view of the active clapboard of the present invention；

Fig. 4 is the top view of the active clapboard of the present invention.

In accompanying drawing, the list of parts representated by each label is as follows：

1st, ice machine, 2, ice bank, 3, active clapboard, 31, clapboard body, 32, engaging lug, 33, ventilating opening, 4, it is fixed every Plate, 5, fan, 6, ice machine evaporator, 7, ice making area temperature sensor, 8, ice storage area temperature sensor.

Specific embodiment

The principle and feature of the present invention are described below in conjunction with accompanying drawing, example is served only for explaining the present invention, and It is non-for limiting the scope of the present invention.

Embodiment 1

A kind of Icemaker assembly, including ice making cavity, the ice machine 1 above ice making inside cavity, and positioned at system The ice bank 2 of ice inside cavity bottom, also includes：

Active clapboard 3, the active clapboard 3 be arranged between ice machine 1 and ice bank 2 for connecting or separating ice making Ice making cavity is divided into ice making area and ice storage area two parts by machine 1 and ice bank 2, the active clapboard 3；

Fan 5, the fan 5 is arranged at the opening of ice making cavity upper end, and the open communication ice making evaporator 6 is located Cavity and ice making cavity；

Ice storage area temperature sensor 8, the ice storage area temperature sensor 8 for gathering ice storage area actual temperature is located at storage Ice chest bottom is simultaneously connected on the inwall of ice bank；

Microprocessor, the microprocessor is connected with ice storage area temperature sensor 8 and receives ice storage area temperature sensor 8 The ice storage area actual temperature of collection, the microprocessor is connected with fan 5 and controls the operational mode of fan 5.

One end of the active clapboard 3 is connected with the side wall of ice making cavity and rotates by rotary shaft of connection end, institute Active clapboard 3 is stated including clapboard body 31 and two engaging lugs 32, described two engaging lugs 32 are fixedly connected on clapboard body 31 The both sides of one end；There is the connecting plate for extending internally, the engaging lug passes through with the connecting plate on the ice making cavity inner wall Connector is connected, and the clapboard body 31 is provided with multiple equally distributed ventilating openings 33, the clapboard body 31 it is another End contacts with stationary barrier 4.The pivot X of the center of gravity of the active clapboard 3 and the active clapboard 3 is same vertically straight On line.

The Icemaker assembly also includes ice making evaporator 6, and the ice making evaporator 6 is connected to the top of ice making cavity, institute State fan 5 to be arranged at the opening of ice making cavity upper end, cavity and ice making cavity that the open communication ice making evaporator 6 is located Body.

The temperature-controlled process of above-mentioned ice making cavity, comprises the steps：

1) ice storage area preset temperature W2 is set in microprocessor；

3) microprocessor is by comparative analysis ice storage area preset temperature W2 and the relation of actual temperature T2 of ice storage area, control The operational mode of fan；

Wherein described step 3) including following situation：

3-1) when ice making function is opened, in ice-making process,

If W2 is ＞ T2, fan slow-speed of revolution operation,

If W2 is ＜ T2, the high rotating speed operation of fan；

3-3) when ice making function is closed,

If W2 is ＞ T2, stopping fan rotation,

If W2 is ＜ T2, fan slow-speed of revolution operation.

The step 1) in, the ice making area preset temperature W1 is -25 DEG C～-10 DEG C, the ice storage area preset temperature W2 For -10 DEG C～0 DEG C.

Embodiment 2

Ice making area temperature sensor 7, the ice making area temperature sensor 7 for gathering ice making area actual temperature is located at system The top of ice maker 1 is simultaneously connected on ice making cavity inner wall；

Microprocessor, the microprocessor is connected with ice making area temperature sensor 7 and receives ice making area temperature sensor 7 The ice making area actual temperature of collection, the microprocessor is connected with ice storage area temperature sensor 8 and receives ice storage area temperature and passes The ice storage area actual temperature of the collection of sensor 8, the microprocessor is connected with fan 5 and controls the operational mode of fan 5；It is fixed Dividing plate 4, one end of the stationary barrier 4 is fixedly connected with the opposite side wall of ice making cavity, one end and the system of the active clapboard 3 The side wall of ice cavity is connected and with connection end as rotary shaft rotation, the front of motor of the active clapboard 3 and the phase of stationary barrier 4 Contact is separated.

The active clapboard 3 is MOD, including motor and clapboard body, and the clapboard body is in motor Be rotated by, the clapboard body is provided with multiple equally distributed ventilating openings 33.

A kind of temperature-controlled process of ice making cavity, comprises the steps：

1) ice making area preset temperature W1 and ice storage area preset temperature W2 are set in microprocessor；

2) ice making area temperature sensor gathers actual temperature T1 in ice making area and is transferred in microprocessor；Ice storage area temperature Actual temperature T2 of sensor collection ice storage area is simultaneously transferred in microprocessor；

3) microprocessor is by comparative analysis ice storage area preset temperature W2 and actual temperature T2 and the ice making area of ice storage area The relation of actual temperature T1 in preset temperature W1 and ice making area, controls the operational mode of fan；

Wherein, the step 3) including following situation：

3-1) when ice making function is opened, in ice-making process,

If W1 is ＞ T1, W2 ＞ T2, stopping fan rotation,

If W1 is ＜ T1, W2 ＞ T2, fan slow-speed of revolution operation,

If W2 is ＜ T2, the high rotating speed operation of fan；

3-3) when ice making function is closed,

If W2 is ＞ T2, stopping fan rotation,

If W2 is ＜ T2, fan slow-speed of revolution operation.

Embodiment 3

As Figure 1-3, a kind of Icemaker assembly, including ice making cavity, the ice machine above ice making inside cavity 1, and positioned at the ice bank 2 of ice making cavity body inner lower, also include：

Microprocessor, the microprocessor is connected with ice storage area temperature sensor 8 and receives ice storage area temperature sensor 8 The ice storage area actual temperature of collection, the microprocessor is connected with fan 5 and controls the operational mode of fan 5；

Ice making area temperature sensor 7, the ice making area temperature sensor 7 for gathering ice making area actual temperature is located at system The top of ice maker 1 is simultaneously connected on ice making cavity inner wall；The microprocessor is connected and receives with ice making area temperature sensor 7 The ice making area actual temperature of the collection of ice making area temperature sensor 7；

Also include stationary barrier 4, one end of the stationary barrier 4 is fixedly connected with the opposite side wall of ice making cavity, described One end of active clapboard 3 is connected with the side wall of ice making cavity and rotates by rotary shaft of connection end, and the active clapboard 3 is non- Connection end contacts or separates with stationary barrier 4.

The active clapboard 3 is provided with multiple equally distributed ventilating openings 33.

The active clapboard 3 includes clapboard body 31 and two engaging lugs 32, and described two engaging lugs 32 are fixedly connected on The both sides of the one end of clapboard body 31；There is the connecting plate that extends internally on the ice making cavity inner wall, the engaging lug with it is described Connecting plate is connected by connector, and the clapboard body 31 is provided with multiple equally distributed ventilating openings 33, the dividing plate sheet The other end of body 31 contacts with stationary barrier 4.

Also include the dynamic clamping head and quiet clamping head being connected between the ice making cavity inner wall and clapboard body 31, the clapboard body 31 are separated under external force with stationary barrier 4, recover in the presence of dynamic clamping head and quiet clamping head after external force terminates to fixation The position that dividing plate 4 contacts.

The dynamic clamping head and quiet clamping head is elastic circlip, and the connector is bolt, and the elastic circlip is socketed on bolt, institute The one end for stating elastic circlip is connected with ice making cavity inner wall, and the other end is connected with clapboard body 31.

Length of the minimum range on the ice bank 1 between edge and the pivot of active clapboard 3 less than the active clapboard 3 Degree.

Wherein described fan is that fan is commonly used in refrigerator, and the fan has the operation of high rotating speed, slow-speed of revolution operation and micro- follows Ring Three models.

Wherein, the step 3) including following situation：

3-1) when ice making function is opened, in ice-making process,

If W1 is ＞ T1, W2 ＞ T2, fan microcirculation,

If W1 is ＜ T1, W2 ＞ T2, fan slow-speed of revolution operation,

If W2 is ＜ T2, the high rotating speed operation of fan；

3-3) when ice making function is closed,

If W2 is ＞ T2, stopping fan rotation,

If W2 is ＜ T2, fan slow-speed of revolution operation.

Embodiment 4

A kind of refrigerator, including the Icemaker assembly as described in embodiment 1-3 is arbitrary, the Icemaker assembly is arranged on refrigerator door In the upper or storage chamber of refrigerator.

In describing the invention, it is to be understood that term " on ", D score, "front", "rear", the instruction such as " vertical " Orientation or position relationship are, based on orientation shown in the drawings or position relationship, to be for only for ease of the description present invention and simplification is retouched State, rather than indicate or imply indication device or element must have specific orientation, with specific azimuth configuration and operation, Therefore it is not considered as limiting the invention.

Additionally, term " first ", " second " are only used for describing purpose, and it is not intended that indicating or implying relative importance Or the implicit quantity for indicating indicated technical characteristic.Thus, define " first ", the feature of " second " can express or Implicitly include at least one this feature.In describing the invention, " multiple " are meant that at least two, such as two, three It is individual etc., unless otherwise expressly limited specifically.

In the present invention, unless otherwise clearly defined and limited, fisrt feature second feature " on " or D score can be with It is the first and second feature directly contacts, or the first and second features are by intermediary mediate contact.

In the description of this specification, the description of reference term " one embodiment " etc. means to combine the embodiment or example The specific features of description, structure, material or feature are contained at least one embodiment of the present invention or example.In this explanation In book, identical embodiment or example are necessarily directed to the schematic representation of above-mentioned term.And, the concrete spy of description Levy, structure, material or feature can in an appropriate manner be combined in any one or more embodiments or example.Additionally, In the case of not conflicting, those skilled in the art can by the different embodiments or example described in this specification and The feature of different embodiments or example is combined and combines.

The foregoing is only presently preferred embodiments of the present invention, not to limit the present invention, all spirit in the present invention and Within principle, any modification, equivalent substitution and improvements made etc. should be included within the scope of the present invention.

Claims

1. a kind of Icemaker assembly, including ice making cavity, installed in the ice machine (1) on ice making inside cavity top, and positioned at system The ice bank (2) of ice inside cavity bottom, it is characterised in that also include：

Active clapboard (3), the active clapboard (3) be arranged between ice machine (1) and ice bank (2) for connecting or separating Ice making cavity is divided into ice making area and ice storage area two parts by ice machine (1) and ice bank (2), the active clapboard (3)；

Fan (5), the fan (5) is arranged at the opening of ice making cavity upper end；

Ice storage area temperature sensor (8), the ice storage area temperature sensor (8) is positioned at ice bank bottom and is connected to ice bank On inwall, for gathering ice storage area actual temperature；

Microprocessor, the microprocessor is connected with ice storage area temperature sensor (8) and receives ice storage area temperature sensor (8) The ice storage area actual temperature of collection, the microprocessor is connected with fan (5) and controls the operational mode of fan (5).

2. a kind of Icemaker assembly according to claim 1, it is characterised in that described also including ice making area temperature sensor (7) Ice making area temperature sensor (7) is positioned at the top of ice machine (1) and is connected on ice making cavity inner wall, for gathering ice making area reality Border temperature；The microprocessor is connected with ice making area temperature sensor (7) and receives what ice making area temperature sensor (7) gathered Ice making area actual temperature.

3. a kind of Icemaker assembly according to claim 1, it is characterised in that also including stationary barrier (4), the stationary barrier (4) one end is fixedly connected with the opposite side wall of ice making cavity, one end of the active clapboard (3) and the side wall of ice making cavity It is connected and rotates by rotary shaft of connection end, active clapboard (3) front of motor contacts with stationary barrier (4) or divides From.

4. a kind of Icemaker assembly according to claim 1, it is characterised in that the active clapboard (3) is provided with multiple uniform The ventilating opening (33) of distribution.

5. according to a kind of arbitrary Icemaker assembly of claim 1-4, it is characterised in that the active clapboard (3) is including dividing plate Body (31) and two engaging lugs (32), described two engaging lugs (32) are fixedly connected on the both sides of clapboard body (31) one end； There is the connecting plate for extending internally, two engaging lugs (32) pass through respectively with the connecting plate on the ice making cavity inner wall Connector is connected, and the clapboard body (31) is provided with multiple equally distributed ventilating openings (33), the clapboard body (31) The other end contact with stationary barrier (4).

6. a kind of Icemaker assembly according to claim 5, it is characterised in that the center of gravity of the active clapboard (3) and the work The pivot of dynamic dividing plate (3) is in same vertical straight line.

7. a kind of Icemaker assembly according to claim 5, it is characterised in that also including be connected to the ice making cavity inner wall and Dynamic clamping head and quiet clamping head between clapboard body (31), the clapboard body (31) is separated under external force with stationary barrier (4), Recover to the position contacted with stationary barrier (4) in the presence of dynamic clamping head and quiet clamping head after external force terminates.

8. a kind of refrigerator, it is characterised in that include the Icemaker assembly as described in claim 1-7 is arbitrary, the Icemaker assembly peace It is mounted on refrigerator door or in the storage chamber of refrigerator.

9. a kind of temperature-controlled process of ice making cavity, it is characterised in that by the ice making group as described in claim 1-7 is arbitrary Part is realized, comprised the steps：

1) ice storage area preset temperature W2 is set in microprocessor；

3) microprocessor controls fan by comparative analysis ice storage area preset temperature W2 and the relation of actual temperature T2 of ice storage area Operational mode.

10. a kind of temperature-controlled process of ice making cavity according to claim 9, it is characterised in that the step 3) bag Include following situation：

3-1) when ice making function is opened, in ice-making process,

If W2 is ＞ T2, fan slow-speed of revolution operation,

If W2 is ＜ T2, the high rotating speed operation of fan；

3-3) when ice making function is closed,

If W2 is ＞ T2, stopping fan rotation,

If W2 is ＜ T2, fan slow-speed of revolution operation.

A kind of 11. temperature-controlled process of ice making cavity according to claim 9, it is characterised in that the Icemaker assembly Also include ice making area temperature sensor (7), ice making area temperature sensor (7) is positioned at the top of ice machine (1) and is connected to On ice making cavity inner wall, for gathering ice making area actual temperature；The microprocessor is connected with ice making area temperature sensor (7) And receive ice making area temperature sensor (7) collection ice making area actual temperature；

The step 1) in be additionally included in microprocessor ice making area preset temperature W1 be set；The step 2) in also include ice making Actual temperature T1 in temperature sensor collection ice making area of area is simultaneously transferred in microprocessor；The step 3) including following situation：

3-1) when ice making function is opened, in ice-making process,

If W1 is ＞ T1, W2 ＞ T2, stopping fan rotation or microcirculation,

If W1 is ＜ T1, W2 ＞ T2, fan slow-speed of revolution operation,

If W2 is ＜ T2, the high rotating speed operation of fan；

3-3) when ice making function is closed,

If W2 is ＞ T2, stopping fan rotation,

If W2 is ＜ T2, fan slow-speed of revolution operation.

12. a kind of temperature-controlled process of ice making cavity according to claim 11, it is characterised in that the step 1) In, the ice making area preset temperature W1 is -25 DEG C～-10 DEG C, and the ice storage area preset temperature W2 is -10 DEG C～0 DEG C.