CN216251491U - Electro-hydraulic integrated connecting assembly and split type ice storage air conditioner - Google Patents

Abstract

The utility model discloses an electro-hydraulic integrated connecting assembly and a split type ice-storage cold air conditioner, wherein the electro-hydraulic integrated connecting assembly comprises: the socket is provided with a first liquid passing connecting part and a first conductive connecting part; the plug is provided with a second liquid passing connecting part and a second conductive connecting part; when the plug is connected with the socket in a matched mode, the second liquid passing connecting portion is correspondingly connected with the first liquid passing connecting portion to allow liquid to pass through, and the second conductive connecting portion is correspondingly connected with the first conductive connecting portion to achieve electric conduction. The technical scheme of the utility model can reduce the structural complexity of the split type ice-storage cold air conditioner with the electro-hydraulic integrated connecting component and simplify the assembling and using process of the split type ice-storage cold air conditioner.

Description

Electro-hydraulic integrated connecting assembly and split type ice storage air conditioner

Technical Field

The utility model relates to the technical field of air conditioners, in particular to an electro-hydraulic integrated connecting assembly and a split type ice cold storage air conditioner.

Background

The split ice-storage air conditioner usually comprises a refrigerator and an ice storage machine which are arranged in a split mode, and a refrigerant connecting pipe and an electric connecting wire are connected between the refrigerator and the ice storage machine. Therefore, a pipeline connector is required to be arranged corresponding to the coolant connecting pipe, and a circuit connector is required to be arranged corresponding to the electrical connecting line, so that the structure of the product is complicated, and the assembly and the use are not facilitated.

SUMMERY OF THE UTILITY MODEL

The utility model mainly aims to provide an electro-hydraulic integrated connecting component, aiming at reducing the structural complexity of a split type ice-storage cooling air conditioner with the electro-hydraulic integrated connecting component and simplifying the assembly and use process of the split type ice-storage cooling air conditioner.

In order to achieve the above object, the present invention provides an electro-hydraulic integrated connection assembly comprising:

the socket is provided with a first liquid passing connecting part and a first conductive connecting part; and

the plug is provided with a second liquid passing connecting part and a second conductive connecting part;

when the plug is connected with the socket in a matched mode, the second liquid passing connecting portion is correspondingly connected with the first liquid passing connecting portion to allow liquid to pass through, and the second conductive connecting portion is correspondingly connected with the first conductive connecting portion to achieve electric conduction.

Optionally, the socket is provided with an insertion cavity, and the first liquid passing connection part and the first conductive connection part are both arranged in the insertion cavity;

the plug is inserted into the inserting cavity in a matching mode.

Optionally, the first liquid passing connection portion is provided with a liquid passing jack, the second liquid passing connection portion is provided with a liquid passing plug, and the liquid passing plug is inserted into the liquid passing jack in an adaptive manner.

Optionally, the socket is further provided with a movable blocking piece which can movably cover the liquid passing insertion hole;

the plug is further provided with a blocking piece driving structure, and in the process that the plug is close to the socket, the blocking piece driving structure can drive the movable blocking piece to open the liquid passing jack, so that the liquid passing plug can be inserted into the liquid passing jack.

Optionally, the blocking piece driving structure includes a switch piece at least partially exposed from the plug, and a pushing piece arranged on the plug, the pushing piece is connected with the switch piece in a linkage manner, and the pushing piece can be driven to push the movable blocking piece to open the liquid passing jack by operating the switch piece.

Optionally, the switch member includes a handle exposed outside on the plug, and a driving rod disposed in the plug, and the driving rod is connected with the handle in a bending manner;

the pushing piece comprises a transmission rod arranged on the plug and a pushing plate connected with the transmission rod in a bending mode, and the pushing plate is rotatably connected with the plug;

the driving rod is connected with the driving rod in a linkage manner;

the handle is operated, the driving rod can be driven to move through the driving rod, and therefore the pushing plate rotates to push the movable blocking piece.

Optionally, the socket is further provided with an elastic member connected with the movable blocking piece, and the elastic member is used for enabling the movable blocking piece to have a tendency of moving towards a direction of closing the liquid passing insertion hole.

Optionally, the outer circumferential surface of the liquid passing plug is provided with a positioning caulking groove corresponding to the movable baffle;

after the liquid passing plug is inserted into the liquid passing jack in a matching mode and the separation blade driving structure is released, at least part of the movable separation blade is clamped into the positioning caulking groove under the action of the elastic piece.

Optionally, the socket is further provided with a liquid isolating rib for isolating the first liquid passing connection portion from the first conductive connection portion.

Optionally, the socket is further provided with a liquid leakage hole located on one side of the liquid isolating rib close to the first liquid passing connection portion.

Optionally, one of the socket and the plug is provided with a plug-in inductive switch, and the other is provided with a trigger piece; when the trigger piece triggers the plugging inductive switch, the plug is connected with the socket in place.

Optionally, the insertion inductive switch is configured as a tact switch, and the trigger is configured to abut against a press rib for triggering the tact switch.

The utility model also provides a split type ice-storage air conditioner which comprises the electro-hydraulic integrated connecting component.

According to the technical scheme, the liquid passing connecting part and the conductive connecting part are formed on the socket and the plug, so that a liquid passage through which liquid can pass and a conductive passage through which current can flow can be formed simultaneously only by matching and connecting one socket and one plug.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the structures shown in the drawings without creative efforts.

FIG. 1 is a schematic structural diagram of a split-type ice-storage air conditioner in accordance with an embodiment of the present invention;

FIG. 2 is a schematic structural diagram of the split ice-storage air conditioner of FIG. 1 between a refrigerator and a socket;

FIG. 3 is a schematic structural diagram of a receptacle of the electro-hydraulic coupling assembly according to an embodiment of the present invention;

FIG. 4 is a schematic structural diagram of a plug of the electro-hydraulic coupling assembly according to an embodiment of the present invention;

FIG. 5 is an enlarged view of a portion of FIG. 4 at A;

FIG. 6 is a schematic view of the plug of FIG. 4 from another perspective;

FIG. 7 is a schematic cross-sectional view of an embodiment of an electro-hydraulic coupling assembly of the present invention taken in one direction;

FIG. 8 is a schematic cross-sectional view of the electro-hydraulic coupling assembly of FIG. 7 in another orientation;

FIG. 9 is a schematic structural view of a second liquid passing connection portion of the plug of the electro-hydraulic integrated connecting assembly in FIG. 7;

FIG. 10 is a schematic view of a first fluid passing connection portion of the receptacle of the electro-hydraulic integrated connection assembly of FIG. 7;

fig. 11 is a partial enlarged view of fig. 1 at B.

The reference numbers illustrate:

the implementation, functional features and advantages of the objects of the present invention will be further explained with reference to the accompanying drawings.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

It should be noted that if directional indications (such as up, down, left, right, front, and back … …) are involved in the embodiment of the present invention, the directional indications are only used to explain the relative positional relationship between the components, the movement situation, and the like in a specific posture, and if the specific posture is changed, the directional indications are changed accordingly.

In addition, if there is a description of "first", "second", etc. in an embodiment of the present invention, the description of "first", "second", etc. is for descriptive purposes only and is not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In addition, if the meaning of "and/or" and/or "appears throughout, the meaning includes three parallel schemes, for example," A and/or B "includes scheme A, or scheme B, or a scheme satisfying both schemes A and B. In addition, technical solutions between various embodiments may be combined with each other, but must be realized by a person skilled in the art, and when the technical solutions are contradictory or cannot be realized, such a combination should not be considered to exist, and is not within the protection scope of the present invention.

The utility model provides an electro-hydraulic integrated connecting assembly.

Referring to fig. 1 to 4, in an embodiment of the present invention, the electro-hydraulic integrated connecting assembly 1 includes:

a socket 11 provided with a first liquid passing connection portion 111 and a first conductive connection portion 112; and

a plug 12 provided with a second liquid passing connection part 121 and a second conductive connection part 122;

when the plug 12 is connected to the socket 11 in a matching manner, the second liquid-passing connection portion 121 is correspondingly connected to the first liquid-passing connection portion 111 for liquid to pass through, and the second conductive connection portion is correspondingly connected to the first conductive connection portion 112 for electrical conduction.

It can be understood that the first connecting portion 111 and the second connecting portion 121 are provided with liquid passing channels, and when the first connecting portion 111 and the second connecting portion 121 are correspondingly connected, the liquid passing channels of the two connecting portions are communicated with each other, so that liquid can pass through the channels.

In this embodiment, the first conductive connection portion 112 is configured as a conductive contact, and the second conductive connection portion 122 is configured as a conductive sheet. However, the design is not limited thereto, and in other embodiments, the first conductive connection portion 112 and the second conductive connection portion 122 may be configured as conductive contacts, or the first conductive connection portion 112 and the second conductive connection portion 122 may be configured as conductive sheets, or other conductive structures capable of realizing reliable electrical connection between the two.

According to the technical scheme, the liquid passing connecting part and the conductive connecting part are formed on the socket 11 and the plug 12, so that a liquid passage through which liquid can pass and a conductive passage through which current can flow can be formed simultaneously only by matching and connecting the socket 11 and the plug 12, compared with the technical scheme that the socket 11 and the plug 12 are required to be respectively configured on the liquid passage and the conductive passage, the technical scheme can save one socket 11 and plug 12 assembly and can also save one connecting operation of the socket 11 and the plug 12, and therefore the structural complexity of the split type ice cold storage air conditioner with the electro-hydraulic integrated connecting assembly 1 can be reduced, and the assembling and using process of the split type ice cold storage air conditioner is simplified.

It should be noted that, for the split type ice storage air conditioner, a coolant loop needs to be formed between the refrigerator 2 and the ice storage machine 3, that is, both a coolant path flowing from the refrigerator 2 to the ice storage machine 3 and a coolant path flowing from the ice storage machine 3 to the refrigerator 2 need to be formed, that is, two opposite liquid paths need to be formed between the socket 11 and the plug 12, so that two first liquid passing connection portions 111 are provided on the socket 11, and two second liquid passing connection portions 121 are provided on the plug 12. Similarly, two first conductive connecting portions 112 are provided on the socket 11, and two second conductive connecting portions 122 are provided on the plug 12. However, the present design is not limited thereto, and in other embodiments, in the case that the electro-hydraulic integrated connecting assembly 1 is applied to other products (non-split type ice thermal storage air conditioner), only one, or three or more than three, may be provided for the first liquid passing connecting portion 111 and the first conductive connecting portion 112 on the socket 11, and correspondingly, only one, or three or more than three, may be provided for the second liquid passing connecting portion 121 and the second conductive connecting portion 122 on the plug 12.

Optionally, referring to fig. 3, in the present embodiment, the socket 11 is provided with a plug cavity 110, and the first liquid passing connection portion 111 and the first conductive connection portion 112 are both disposed in the plug cavity 110; the plug 12 is adapted to be inserted into the insertion cavity 110. It can be understood that the side cavity wall of the plug cavity 110 has the function of positioning and guiding, when the plug 12 is inserted into the cavity opening of the plug cavity 110 in an aligned manner, the first liquid passing connection portion 111 is opposite to the second liquid passing connection portion 121, and the first conductive connection portion 112 is opposite to the second conductive connection portion 122, so that the connection convenience between the plug 12 and the socket 11 can be improved. In addition, the plug 12 and the plugging cavity 110 are inserted in a matching manner, so that the connection reliability between the plug 12 and the socket 11 is improved; however, the design is not limited thereto, and in other embodiments, the plugging cavity 110 may not be provided, and a binding member (for example, but not limited to, a cable tie) may be used to bind the plug 12 and the socket 11 together after the plug 12 is plugged into the socket 11, so as to improve the connection reliability between the plug 12 and the socket 11.

Further, referring to fig. 3, 4 and 7, in the present embodiment, the first liquid passing connection portion 111 is provided with a liquid passing insertion hole 111a, the second liquid passing connection portion 121 is provided with a liquid passing plug 121a, and the liquid passing plug 121a is adapted to be inserted into the liquid passing insertion hole 111 a; therefore, the connection sealing performance between the first liquid passing connecting part 111 and the second liquid passing connecting part 121 is improved, and the probability of liquid leakage at the joint of the first liquid passing connecting part and the second liquid passing connecting part is reduced. However, the design is not limited thereto, and in other embodiments, the positions of the liquid passing insertion hole 111a and the liquid passing plug 121a may be switched, that is, the liquid passing plug 121a is disposed on the first liquid passing connection portion 111, and the liquid passing insertion hole 111a is disposed on the second liquid passing connection portion 121; in other embodiments, the liquid passing through hole 111a and the liquid passing through plug 121a may not be provided, and the liquid passing through port of the first liquid passing connection portion 111 and the liquid passing through port of the second liquid passing connection portion 121 may be directly connected to each other.

Further, referring to fig. 3 to 10, in this embodiment, the socket 11 is further provided with a movable stopper 113 that movably covers the liquid passing insertion hole 111 a; the plug 12 is further provided with a baffle driving structure 123, and in a process that the plug 12 approaches towards the socket 11, that is, in a process that the plug 12 is inserted into the insertion cavity 110, the baffle driving structure 123 can drive the movable baffle 113 to open the liquid passing insertion hole 111a, so that the liquid passing plug 121a can be inserted into the liquid passing insertion hole 111 a. It can be understood that before the plug 12 is inserted into the plug cavity 110, the movable flap 113 covers the liquid passing insertion hole 111a, so that other foreign objects can be prevented from being inserted into the liquid passing insertion hole 111 a. In the present invention, the shutter driving mechanism 123 may be manually controlled or may be automatically controlled.

Optionally, the movable flap 113 is slidably connected to the first liquid passing connection portion 111, so that the movable flap 113 can movably cover the liquid passing insertion hole 111 a. However, the design is not limited thereto, and in other embodiments, the movable blocking piece 113 may also be, but not limited to, pivotally connected to the first liquid passing connection portion 111.

As for the technical solution that the movable blocking piece 113 is slidably connected to the first liquid passing connection portion 111, optionally, the movable blocking piece 113 is provided with a liquid passing hole 113 a; when the movable blocking piece 113 covers the liquid passing insertion hole 111a, the liquid passing hole 113a is staggered with the liquid passing insertion hole 111a, and when the movable blocking piece 113 opens the liquid passing insertion hole 111a, the liquid passing hole 113a is coincident with the hole center of the liquid passing insertion hole 111 a.

Further, in this embodiment, the blocking sheet driving structure 123 includes a switch member 131 at least partially exposed from the plug 12, and a pushing member 132 disposed on the plug 12, wherein the pushing member 132 is linked with the switch member 131; the switch member 131 is operated to drive the pushing member 132 to push the movable blocking piece 113, so as to open the liquid passing insertion hole 111 a. It can be understood that the flap driving structure 123 in this embodiment is a manually controlled structure, and the portion of the switch member 131 exposed outside the plug 12 is used for the user to operate. Alternatively, the pushing action of the pushing member 132 on the movable blocking plate 113 may be realized by a telescopic action or a swinging action. In addition, the switch member 131 of the present embodiment indirectly drives the movable blocking sheet 113 through the pushing member 132; however, the design is not limited thereto, and in other embodiments, the switch member 131 for directly driving the movable blocking piece 113 may be further disposed.

Further, the switch 131 includes a handle 141 exposed outside on the plug 12 and a driving rod 142 disposed in the plug 12, and the driving rod 142 is connected to the handle 141 in a bent manner; the pushing part 132 comprises a transmission rod 151 arranged on the plug 12 and a pushing plate 152 connected with the transmission rod 151 in a bending manner, and the pushing plate 152 is rotatably connected with the plug 12; the driving rod 142 is linked with the driving rod 151; when the handle 141 is operated, the driving rod 151 can be driven to move by the driving rod 142, so that the pushing plate 152 rotates to push the movable blocking piece 113. Without loss of generality, the housing of the plug 12 is provided with an avoiding groove 120 corresponding to the handle 141, and the avoiding groove 120 extends towards the socket 11 and provides an operating stroke for the handle 141. In this embodiment, the pushing plate 152 is rotatably connected to the plug 12 to drive the movable baffle to open the plugging via hole by a swinging motion. In this embodiment, the pushing plate 152 is rotatably connected to the plug 12; however, the design is not limited thereto, and in other embodiments, the transmission rod 151 may be rotatably connected to the plug 12.

Optionally, the pushing plate 152 and the transmission rod 151 are integrally formed, that is, the pushing plate 152 and the transmission rod 151 are different parts of the same component, so that the number of components of a product can be reduced, the assembly process can be saved, and the assembly efficiency can be improved. However, the design is not limited thereto, and in other embodiments, the pushing plate 152 and the driving rod 151 may be detachably connected, or welded, bonded, and the like.

Optionally, the handle 141 is detachably connected to the driving rod 142, so that when the exposed handle 141 is damaged, only the handle 141 can be detached and replaced, thereby reducing the maintenance cost of the product. Further optionally, in this embodiment, the handle 141 and the driving rod 142 are detachably connected through a screw locking structure, and the locking structure is stable and reliable; of course, in other embodiments, the handle 141 can also be connected to the driving rod 142 by, but not limited to, a snap-fit structure or other detachable structure. In other embodiments, the handle 141 may be integrally connected to the driving rod 142, for example, but not limited to, being welded, adhered, or directly integrally formed.

Optionally, referring to fig. 5, one end of the transmission rod 151, which is away from the pushing plate 152, is provided with a notch groove 151a, two opposite sides of one end of the driving rod 142, which is away from the handle 141, are respectively provided with a clamping notch 142a, the two clamping notches 142a are respectively clamped to two opposite side edges of the notch groove 151a, a limiting protrusion 151b, which is close to an opening of the notch groove 151a, is further disposed on a surface of the transmission rod 151, which is away from the handle 141, and the limiting protrusion 151b is configured to limit the clamping notch 142a to be automatically separated from the notch groove 151 a; thus, the driving rod 142 and the driving rod 151 can be reliably linked, so that the pushing plate 152 can be driven to move when the handle 141 is operated.

Optionally, referring to fig. 8, the flap driving structure 123 further includes a reset member 133 acting on the pushing member 132, and the reset member 133 is configured to make the pushing member 132 have a tendency to reset to an initial position (i.e., a position where the movable flap is not pushed). Optionally, the reset member 133 is disposed at an end of the transmission rod 151 away from the push-resisting plate 152. Further optionally, the reset member 133 is configured as a spring.

Further, referring to fig. 10, the socket 11 is further provided with an elastic member 114 connected to the movable flap 113, and the elastic member 114 is configured to make the movable flap 113 have a tendency to move toward a direction of closing the liquid passing insertion hole 111 a. It can be understood that the elastic member 114 is disposed such that the movable blocking piece 113 can keep covering the liquid passing insertion hole 111a in a natural state, thereby effectively limiting the insertion of other foreign objects into the liquid passing insertion hole 111 a. Optionally, the elastic member 114 is connected between the movable blocking piece 113 and the first liquid passing connection portion 111; however, the design is not limited thereto, and in other embodiments, the elastic element 114 may also be connected between the movable blocking piece 113 and the housing of the socket 11. Optionally, the elastic member 114 is configured as a spring, and the elasticity of the spring is good; however, the design is not limited thereto, and in other embodiments, the elastic member 114 may also be configured as an elastic block.

Further, referring to fig. 9 and 10, the outer circumferential surface of the liquid passing plug 121a is provided with a positioning caulking groove (121b) corresponding to the movable blocking piece 113; after the liquid passing plug 121a is adapted to be plugged into the liquid passing insertion hole 111a and the blocking piece driving structure 123 is released, under the action of the elastic member 114, the movable blocking piece 113 is at least partially clamped into the positioning insertion groove (121 b). For the technical scheme that the movable blocking piece 113 is provided with the liquid passing hole 113a, what is clamped into the positioning caulking groove (121b) is the edge of the liquid passing hole 113a of the movable blocking piece 113. In this embodiment, the liquid passing plug 121a can be effectively prevented from being disengaged from the liquid passing insertion hole 111a by the engagement of the movable blocking piece 113 and the positioning insertion groove (121b), so that the connection stability between the first liquid passing connection portion 111 and the second liquid passing connection portion 121 is ensured. It can be understood that, in this embodiment, when the plug 12 needs to be pulled out from the socket 11, the handle 141 needs to be operated first to drive the transmission rod 151 to move through the driving rod 142, so that the pushing plate 152 rotates to push the movable blocking piece 113, until the movable blocking piece 113 is separated from the positioning caulking groove (121b), and then the plug 12 can be pulled out. Optionally, the positioning caulking groove (121b) is configured as an annular groove, so compared with the technical solution that the positioning caulking groove (121b) is configured as an arc-shaped groove, in the process of assembling the liquid passing plug 121a to the plug 12, the technical solution of this embodiment does not need to consider the alignment condition between the arc-shaped groove and the movable blocking piece 113, thereby improving the assembly convenience of the product.

Further, the socket 11 is further provided with a liquid isolation structure for isolating the first liquid passing connection portion 111 from the first conductive connection portion 112, so as to reduce the leakage probability of the first conductive connection portion 112.

Optionally, referring to fig. 3, in this embodiment, the socket 11 is further provided with a liquid blocking rib 115, and the liquid blocking rib 115 is located between the first liquid passing connection portion 111 and the first conductive connection portion 112 to isolate the first liquid passing connection portion 111 from the first conductive connection portion 112; in this way, even if a liquid leakage phenomenon occurs on the side of the first liquid passing connection portion 111, the liquid barrier rib 115 can restrict the liquid from spreading toward the first conductive connection portion 112, thereby reducing the probability of the liquid leakage from the first conductive connection portion 112.

However, the design is not limited thereto, in other embodiments, in the case that the socket 11 is located below the plug 12, the liquid-proof structure may also be configured as a liquid-proof boss, and the first conductive connecting part 112 is disposed on the overnight boss.

Further, with continued reference to fig. 3, the socket 11 is further provided with a liquid leakage hole 116, and the liquid leakage hole 116 is located on one side of the liquid isolating rib 115 close to the first liquid passing connection portion 111; in this way, even if a leakage phenomenon occurs on the side of the first liquid passing connection portion 111, the leaked liquid can be discharged out of the socket 11 through the leakage hole 116, so that the probability of the leaked liquid passing through the liquid isolating rib 115 is reduced, and the leakage probability of the first conductive connection portion 112 is further reduced. Optionally, the weep hole 116 is located between two of the first liquid passing connection portions 111, so that the distance between the weep hole 116 and two of the first liquid passing connection portions 111 is short, and therefore, no matter which one of the first liquid passing connection portions 111 has a weeping phenomenon, the weeping can be discharged out of the socket 11 relatively quickly.

Further, referring to fig. 3 and 4, in the present embodiment, the socket 11 is provided with an insertion inductive switch 117, and the plug 12 is provided with a trigger 124 corresponding to the insertion inductive switch 117. However, the design is not limited thereto, and in other embodiments, the insertion inductive switch 117 may be disposed on the plug 12, and accordingly, the trigger 124 is disposed on the socket 11, as long as the position between the trigger 124 and the insertion inductive switch 117 corresponds. According to the technical scheme, whether the connection between the plug 12 and the socket 11 is reliable or not can be judged according to the working state of the plug-in inductive switch 117; specifically, when the triggering member 124 can trigger the plugging inductive switch 117, it indicates that the plug 12 and the socket 11 are connected in place, that is, the connection between the plug 12 and the socket 11 is already a reliable connection, and when the triggering member 124 fails to trigger the plugging inductive switch 117, it indicates that the plug 12 and the socket 11 are not connected in place, that is, the connection between the plug 12 and the socket 11 is not yet a reliable connection, and the user needs to further approach the plug 12 and the socket 11 to ensure the connection between the plug 12 and the socket 11 is reliable.

Optionally, in this embodiment, the plug-in inductive switch 117 is configured as a tact switch, and the trigger 124 is configured to abut against a pressing rib for triggering the tact switch; the touch switch is cheaper, and is beneficial to reducing the product cost. However, the design is not limited thereto, and in other embodiments, the plug inductive switch 117 may be configured as a hall switch, and the triggering element 124 is configured with a magnetic element for triggering the hall switch in a close manner; in yet other embodiments, the insertion-sensing switch 117 can be configured as an optoelectronic switch, and the triggering member 124 is configured with a light blocking sheet for blocking the light path of the optoelectronic switch to trigger the optoelectronic switch.

The utility model also provides a split type ice-storage air conditioner, referring to fig. 1 to 11, the split type ice-storage air conditioner comprises an electro-hydraulic integrated connecting assembly 1, the specific structure of the electro-hydraulic integrated connecting assembly 1 refers to the above embodiments, and as the split type ice-storage air conditioner adopts all the technical schemes of all the above embodiments, the split type ice-storage air conditioner at least has all the beneficial effects brought by the technical schemes of the above embodiments, and no further description is provided herein. Without loss of generality, the split type ice storage air conditioner comprises a refrigerator 2 and an ice storage machine 3 which are arranged in a split mode, a refrigerating medium connecting pipe 161 and an electric connecting wire between the refrigerator 2 and the ice storage machine 3 are connected through the electro-hydraulic integrated connecting assembly 1, specifically, the refrigerating medium connecting pipe 161 is communicated with a second liquid passing connecting part 121 of a plug 12 through a first liquid passing connecting part 111 of a socket 11, and the electric connecting wire is communicated with a second conductive connecting part 122 of the plug 12 through a first conductive connecting part 112 of the socket 11.

At least, the electrical connection line between the refrigerator 2 and the ice storage machine 3 is used to feed back the temperature information in the ice making tank in the refrigerator 2 to the controller on the ice storage machine 3, so that the controller can control the working state of the compressor on the ice storage machine 3 according to the temperature information. For example, when the temperature in the refrigerator is less than or equal to 0 ℃, the controller controls the compressor to stop to accumulate ice; for another example, when the temperature in the refrigerator is a preset temperature greater than 0 ℃, the controller controls the compressor to restart the ice storage mode. It is understood that the electrical connection line between the refrigerator 2 and the ice bank 3 is connected to a temperature detection device capable of detecting temperature information in the ice maker.

Referring to fig. 2, alternatively, in this embodiment, the socket 11 is fixedly installed on the refrigerator 2, and the plug 12 is connected to the coolant connecting pipe 161 and the end of the electrical connection line; in this way, the refrigerating machine 2 does not need to be provided with the refrigerant connection pipe 161 and the electric connection line exposed to the outside. However, the design is not limited thereto, and in other embodiments, the socket 11 may be fixed to the ice storage machine 3, and the plug 12 may be connected to the ends of the coolant connection tube 161 and the electrical connection line, so that the coolant connection tube 161 and the electrical connection line, which are exposed to the outside, do not need to be disposed on the ice storage machine 3; in other embodiments, the refrigerator 2 and the ice storage device 3 are both provided with a coolant connection tube 161 and an electrical connection wire exposed to the outside, the socket 11 is connected to the coolant connection tube 161 and the electrical connection wire end of one of the refrigerator 2 and the ice storage device 3, and the plug 12 is connected to the coolant connection tube 161 and the electrical connection wire end of the other.

Optionally, for the technical solution that the socket 11 is fixed to the refrigerator 2, the refrigerator 2 is provided with a cover plate 21 that can movably cover the plug cavity 110 of the socket 11; in this way, when the ice maker is in an idle state (e.g., storage state) or a transportation state, the plug cavity 110 can be covered by the cover plate 21, so as to prevent dust from depositing in the plug cavity 110.

Further optionally, the cover plate 21 is pivotally connected to the socket 11, so that the cover plate 21 can be conveniently opened and closed in a turnover manner; in particular, the cover 21 remains connected to the receptacle 11 in the open state of the cover 21, which reduces the probability of the cover 21 being lost. However, the design is not limited thereto, in other embodiments, the cover plate 21 may be slidably connected to the socket 11, so that the cover plate 21 can be conveniently opened and closed by a translational sliding manner; in still other embodiments, the cover plate 21 may be detachably connected to the socket 11, which is not limited in the present invention.

Optionally, referring to fig. 11, the coolant connection pipe 161, the first wire 162 connected to the temperature measuring device, and the second wire 163 connected to the plug-in inductive switch 117 are collectively coated by a heat-insulating and flame-retardant skin 164, so as to reduce the scattering degree of pipes and wires.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the scope of the present invention, and all modifications and equivalents of the present invention, which are made by the contents of the present specification and the accompanying drawings, or directly/indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims (12)

1. An integrative coupling assembling of electricity liquid which characterized in that includes:

the socket is provided with a first liquid passing connecting part and a first conductive connecting part; and

the plug is provided with a second liquid passing connecting part and a second conductive connecting part;

when the plug is connected with the socket in a matched mode, the second liquid passing connecting portion is correspondingly connected with the first liquid passing connecting portion to allow liquid to pass through, and the second conductive connecting portion is correspondingly connected with the first conductive connecting portion to achieve electric conduction.

2. The electro-hydraulic integrated connecting assembly according to claim 1, wherein the socket is provided with a plug cavity, and the first liquid passing connecting part and the first conductive connecting part are both arranged in the plug cavity;

the plug is inserted into the inserting cavity in a matching mode.

3. The electro-hydraulic integrated connecting assembly according to claim 1, wherein the first liquid passing connecting portion is provided with a liquid passing jack, the second liquid passing connecting portion is provided with a liquid passing plug, and the liquid passing plug is adapted to be plugged into the liquid passing jack.

4. The electro-hydraulic integrated connecting assembly of claim 3, wherein the socket is further provided with a movable baffle capable of movably covering the liquid passing jack;

the plug is further provided with a blocking piece driving structure, and in the process that the plug is close to the socket, the blocking piece driving structure can drive the movable blocking piece to open the liquid passing jack, so that the liquid passing plug can be inserted into the liquid passing jack.

5. The electro-hydraulic integrated connecting assembly according to claim 4, wherein the blocking piece driving structure comprises a switch piece at least partially exposed from the plug and a pushing piece arranged on the plug, the pushing piece is linked with the switch piece, and the pushing piece is driven to push the movable blocking piece to open the liquid passing jack by operating the switch piece.

6. The electro-hydraulic integrated connecting assembly according to claim 5, wherein the switch member comprises a handle exposed from the plug, and a driving rod arranged on the plug, and the driving rod is connected with the handle in a bending way;

the pushing piece comprises a transmission rod arranged on the plug and a pushing plate connected with the transmission rod in a bending mode, and the pushing plate is rotatably connected with the plug;

the driving rod is connected with the driving rod in a linkage manner;

the handle is operated, the driving rod can be driven to move through the driving rod, and therefore the pushing plate rotates to push the movable blocking piece.

7. The electro-hydraulic integrated connection assembly of claim 4, wherein the socket is further provided with a resilient member connected with the movable flap, and the resilient member is used for enabling the movable flap to have a tendency to move towards a direction of closing the liquid passing insertion hole.

8. The electro-hydraulic integrated connecting assembly according to claim 7, wherein the outer peripheral surface of the liquid passing plug is provided with a positioning caulking groove corresponding to the movable blocking piece;

after the liquid passing plug is inserted into the liquid passing jack in a matching mode and the separation blade driving structure is released, at least part of the movable separation blade is clamped into the positioning caulking groove under the action of the elastic piece.

9. The electro-hydraulic integrated connection assembly of claim 1, wherein the socket is further provided with a liquid isolating rib for isolating the first liquid passing connection part and the first conductive connection part; and/or

The socket is further provided with a liquid leakage hole which is located on one side, close to the first liquid passing connecting portion, of the liquid isolating rib.

10. The electro-hydraulic integrated connecting assembly according to any one of claims 1 to 9, wherein one of the socket and the plug is provided with a plug-in inductive switch, and the other is provided with a trigger; when the trigger piece triggers the plugging inductive switch, the plug is connected with the socket in place.

11. The electro-hydraulic integrated connection assembly of claim 10, wherein the plug-in inductive switch is configured as a tact switch, and the trigger is configured to abut against a bead that triggers the tact switch.

12. A split type ice-refrigerating air conditioner comprising an electro-hydraulic integrated connecting assembly as claimed in any one of claims 1 to 11.

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