CN216944127U - Transport package frock of air conditioner spare part - Google Patents

Abstract

The utility model discloses a transportation and packaging tool for air conditioner parts, wherein the air conditioner parts comprise an evaporator and a face frame, the transportation and packaging tool comprises a gasket assembly and an outer packaging box, the gasket assembly is provided with a positioning area, at least one part of the evaporator is matched with the positioning area so that the gasket assembly is sleeved outside the evaporator and assembled in the face frame together with the evaporator, and the outer packaging box is suitable for being sleeved outside the face frame. According to the transporting and packaging tool for the air conditioner parts, the evaporator is assembled in the face frame for packaging, so that the space in the face frame is reasonably utilized, the evaporator is prevented from occupying the space outside the face frame, the case packing space of the evaporator is saved, the using amount of outer packing cases is reduced, and the transporting and packaging cost of the air conditioner parts is reduced.

Description

Transport package tool for air conditioner parts

Technical Field

The utility model relates to the technical field of air conditioner packaging and transportation, in particular to a transportation and packaging tool for air conditioner parts.

Background

At present, air conditioner parts are usually packaged according to the type division of the parts in the process of export transportation, for example, a face frame is arranged in the same packaging box, an evaporator is arranged in the same packaging box, but the face frame and the evaporator occupy larger space, so that the packaging mode needs to use a larger number of packaging boxes, and the packaging cost is increased.

In order to solve the problems, the face frames are generally stacked and then packaged in the prior art, the packaging mode can improve the space utilization rate in the packaging box to a certain extent, but the space of 2/3-3/4 in the packaging box is still wasted, the packaging cost is still high, and when the evaporator is packaged independently, because the pipeline of the evaporator is easily damaged by collision, damaged and invalid, extra cellular boards and protection bags need to be added on the pipeline side in the packaging process, the packaging cost is further increased, the occupied space of the evaporator is increased, and the packaging cost of air conditioner parts is increased.

SUMMERY OF THE UTILITY MODEL

The present invention is directed to solving at least one of the problems of the prior art. Therefore, the utility model provides the transport packaging tool for the air conditioner parts, which reasonably utilizes the space in the packaging box, improves the space utilization rate of the packaging box, reduces the using number of the packaging box, further reduces the packaging cost of the air conditioner parts, and solves the technical problem of high packaging cost of the air conditioner parts in the prior art.

According to the transportation packaging tool for the air conditioner parts, the air conditioner parts comprise the evaporator and the face frame, and the transportation packaging tool comprises: the gasket assembly is provided with a positioning area, and at least one part of the evaporator is matched with the positioning area so that the gasket assembly is sleeved outside the evaporator and assembled in the face frame together with the evaporator; an outer packaging case adapted to be wrapped around the face frame.

According to the transportation and packaging tool for the air conditioner parts, the gasket assembly is sleeved outside the evaporator, and the gasket assembly and the evaporator are assembled in the face frame together, so that the space in the face frame is reasonably utilized, the evaporator is prevented from occupying the space outside the face frame, and the independent packaging of the evaporator is omitted, so that the packaging space of the evaporator is saved, the using amount of outer packaging boxes is reduced, the transportation and packaging cost of the air conditioner parts is reduced, the gasket assembly and the face frame are sleeved outside the evaporator, and the gasket assembly and the face frame are matched for protecting pipelines on the evaporator, and the evaporator is prevented from being damaged in the packaging or transportation process.

According to the transportation and packaging tool for the air conditioner parts, the gasket assembly comprises a first gasket and a second gasket, and the first gasket and the second gasket are sleeved at two ends of the evaporator respectively.

Optionally, the first gasket includes an end wall and a first stopper protrusion connected to the end wall, and one end of the evaporator is supported on the first stopper protrusion.

Optionally, the first gasket further includes a first side wall and a second side wall connected to the end wall, the first side wall and the second side wall have the same extending direction as the first limiting protrusion, a limiting region is defined between the first side wall and the first limiting protrusion, and one end of the evaporator is limited in the limiting region.

Optionally, an avoidance groove is formed in the first side wall, and a part of the evaporator abuts against the inside of the avoidance groove.

Optionally, one end of the first limiting protrusion close to the first sidewall is provided with a second limiting protrusion, one end of the evaporator is limited in the limiting area, and the end of the evaporator abuts against the second limiting protrusion.

Optionally, an avoiding area is further arranged on one side surface of the end wall close to the first limiting protrusion, and the avoiding area is used for avoiding a pipeline on the evaporator.

Optionally, a first weight-reducing hole is formed in the first limiting protrusion, and first weight-reducing grooves are formed in the outer surfaces of the first side wall and the second side wall.

Optionally, a limiting groove is formed in the second gasket, and the other end of the evaporator is limited in the limiting groove.

Optionally, a weight-reducing region is provided on the second pad.

Optionally, the first gasket and the second gasket are both integrally formed pieces.

According to the transportation and packaging tool for the air conditioner parts, a handle concave area is arranged on one side face, away from the evaporator, of the gasket assembly.

Additional aspects and advantages of the utility model will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by practice of the utility model.

Drawings

The above and/or additional aspects and advantages of the present invention will become apparent and readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings of which:

fig. 1 is an exploded view of a gasket assembly and air conditioning components according to some embodiments of the present invention.

Fig. 2 is a front view of a gasket assembly of some embodiments of the utility model assembled with an air conditioning component.

Fig. 3 is a schematic view of a gasket assembly of some embodiments of the utility model after assembly with an evaporator.

Fig. 4 is a schematic diagram of a first gasket according to some embodiments of the utility model.

Fig. 5 is a schematic view of a first gasket of some embodiments of the present invention after assembly with an evaporator.

Fig. 6 is a schematic view of another angle after the gasket assembly and the evaporator are assembled according to some embodiments of the present invention.

Fig. 7 is a side view of a second gasket of some embodiments of the present invention after assembly with an evaporator.

Reference numerals:

1000. transporting and packaging the tooling;

100. a liner assembly;

110. a positioning area;

120. a first liner;

121. an end wall; 1211. an avoidance zone;

122. a first limit protrusion; 1221. a first lightening hole;

123. a first side wall; 1231. an avoidance groove; 1232. a first weight-reduction groove;

124. a second side wall;

125. a limiting area;

126. a second limit bulge;

130. a second liner;

131. a limiting groove;

132. a weight-reduction region; 1321. a second lightening hole; 1322. a second weight-reduction groove;

140. a handle recessed area;

2000. air conditioning components;

2100. an evaporator; 2110. a pipeline;

2200. and (7) a face frame.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the accompanying drawings are illustrative only for the purpose of explaining the present invention, and are not to be construed as limiting the present invention.

In the description of the present invention, it is to be understood that the terms "width," "thickness," "upper," "lower," "front," "rear," "left," "right," "top," "bottom," "inner," "outer," and the like are used in an orientation or positional relationship indicated in the drawings only for the convenience of description and simplicity of description, and do not indicate or imply that the device or element so referred to must have a particular orientation, be constructed in a particular orientation, and be operated in a particular manner, and therefore, are not to be construed as limiting the utility model.

The transport package tooling 1000 for the air conditioning part 2000 according to the embodiment of the present invention will be described with reference to the drawings attached to the specification.

As shown in fig. 1 and 2, according to a transport package assembly 1000 for an air-conditioning part 2000 according to an embodiment of the present invention, the air-conditioning part 2000 includes an evaporator 2100 and a face frame 2200, and the transport package assembly 1000 includes a gasket assembly 100 and an outer packing case (not shown).

The gasket assembly 100 is provided with a positioning area 110, and the positioning area 110 is used for positioning the installation position of the evaporator 2100, so that the evaporator 2100 and the gasket assembly 100 can be quickly assembled, and the packaging efficiency of the air conditioner component 2000 can be improved. In a specific example, the positioning region 110 can also be understood as a stopper region 125 and a stopper groove 131 hereinafter.

At least a portion of the evaporator 2100 cooperates with the positioning region 110 such that the gasket assembly 100 fits over the exterior of the evaporator 2100, and both the gasket assembly 100 and the evaporator 2100 fit within the bezel 2200.

The outer package is adapted to be wrapped around the exterior of the face frame 2200.

As can be seen from the above structure, after the gasket assembly 100 and the evaporator 2100 are quickly assembled through the positioning area 110, the gasket assembly 100 can be sleeved on the evaporator 2100, so that the gasket assembly 100 can be used to limit the evaporator 2100, and prevent the evaporator 2100 from being scratched by the shake of the evaporator 2100 in the packaging or transportation process, and in the subsequent process of assembling the evaporator 2100, the gasket assembly 100 can be assembled in the face frame 2200 together with the evaporator 2100, so that the gasket assembly 100 does not occupy the space outside the face frame 2200.

By assembling both the pad assembly 100 and the evaporator 2100 in the face frame 2200, the pad assembly 100 can be disposed near the evaporator 2100, ensuring that the pad assembly 100 can always support the evaporator 2100 during transportation of the air conditioner component 2000 to prevent damage to the evaporator 2100 during transportation, and at the same time, the above arrangement can also achieve full use of the space in the face frame 2200, disposing the evaporator 2100 in the face frame 2200, and then disposing the face frame 2200 together with the evaporator 2100 in the outer packaging box to fully improve the space utilization in the outer packaging box, and thus the outer packaging box packaging evaporator 2100 does not need to be separately disposed, thereby reducing the number of outer packaging boxes and reducing the packaging cost of the air conditioner component 2000.

In the specific packaging process of the air conditioner component 2000, the packaging steps are as follows: firstly, the gasket assembly 100 is sleeved on the evaporator 2100, after the sleeving is completed, the evaporator 2100 and the gasket assembly 100 are assembled together in the face frame 2200, after the assembling is completed, the face frame 2200 is assembled in the outer packaging box, and at this time, the gasket assembly 100, the evaporator 2100 and the face frame 2200 are all located in the same outer packaging box, so that the air conditioner part 2000 is packaged.

By providing the outer packing case and covering the outer packing case on the outside of the face frame 2200, the outer packing case can protect the face frame 2200 and the evaporator 2100 in the transportation process of the packaged air conditioner component 2000, thereby preventing the face frame 2200 and the evaporator 2100 from being damaged in the transportation process.

Therefore, the present application provides a new packaging method for the air conditioner components 2000, in which each evaporator 2100 is assembled with the face frame 2200, so as to reasonably utilize the internal structure of the face frame 2200, avoid the waste of the space in the face frame 2200, reduce the number of used outer packaging boxes, and reduce the packaging cost.

It should be noted that, after the air conditioner is installed, the width of the evaporator 2100 does not exceed the face frame 2200, so the packaging method of the present application can protect the pipeline 2110 on the evaporator 2100 by using the structure of the face frame 2200, and does not need to add a honeycomb panel or a protection bag to protect the pipeline 2110, thereby further reducing the packaging cost. The bezel 2200 and the evaporator 2100 are well known in the art, and are not described herein.

It can be understood that, compared to the prior art in which the face frame 2200 and the evaporator 2100 are packaged separately, the present application rationalizes and utilizes the inner space of the face frame 2200, and the face frame 2200 and the evaporator 2100 are assembled together in the packaging process, so that the evaporator 2100 can be completely hidden in the volume of the face frame 2200, thereby saving the packaging space of the evaporator 2100, reducing the number of outer packaging boxes and the use cost, and at the same time, the packaging method can utilize the face frame 2200 to protect the evaporator 2100 without arranging a honeycomb plate or a protection bag of the protection pipe 2110, thereby further reducing the packaging cost.

Optionally, the pad assembly 100 may be made of pearl wool, foam, or the like, in order to reduce the hardness of the pad assembly 100, prevent the pad assembly 100 from scratching the evaporator 2100 or the face frame 2200, and ensure that the pad assembly 100 can effectively limit the evaporator 2100; the second aspect can reduce the weight of the pad assembly 100, thereby reducing the weight of the air conditioner component 2000 after packaging, and facilitating handling, moving and transporting; the third aspect provides the pad assembly 100 with a cushioning effect to effectively shield the evaporator 2100.

Alternatively, a face frame 2200 may be disposed in an outer package, and it is also understood that a face frame 2200, a vaporizer 2100, and a gasket assembly 100 may be disposed in an outer package, in which the side walls of the face frame 2200 may contact the inner wall surface of the outer package, and the outer package serves to define the position of the face frame 2200, thereby preventing the face frame 2200 from shaking during transportation, and thus, preventing damage to the face frame 2200 and the vaporizer 2100.

In other examples, a plurality of face frames 2200 may be disposed in one outer package box, and at this time, the volume of the outer package box may be increased, and it should be noted that when a plurality of face frames 2200 are disposed in the outer package box, a partition board, pearl wool, or the like may be disposed between the plurality of face frames 2200, so as to avoid collision between adjacent face frames 2200 during transportation.

In the description of the present invention, "a plurality" means two or more unless otherwise specified.

In some embodiments of the present invention, as shown in fig. 3, the gasket assembly 100 includes a first gasket 120 and a second gasket 130, and the first gasket 120 and the second gasket 130 are respectively fitted over both ends of the evaporator 2100. The first gasket 120 and the second gasket 130 are used for protecting the evaporator 2100, and at the same time, the position of the evaporator 2100 is limited, so that the evaporator 2100 is prevented from shaking during transportation, and in addition, because the first gasket 120 and the second gasket 130 have a certain thickness, when the first gasket 120 and the second gasket 130 are sleeved on the evaporator 2100 and are arranged in the face frame 2200 at the same time, the side wall of the evaporator 2100 and the side wall of the face frame 2200 are arranged at intervals, so that mutual friction between the evaporator 2100 and the face frame 2200 is avoided, and the evaporator 2100 and the face frame 2200 are prevented from being damaged during transportation.

In the description of the present invention, the features defined as "first" and "second" may explicitly or implicitly include one or more of the features for distinguishing between the described features, whether they are sequential or not.

Alternatively, as shown in fig. 4, the first gasket 120 includes an end wall 121 and a first stopper protrusion 122, and the first stopper protrusion 122 is coupled to the end wall 121. The end wall 121 serves to support the first stopper protrusion 122 to improve structural stability of the first stopper protrusion 122.

Alternatively, as shown in fig. 5 and 6, one end of the evaporator 2100 is supported on the first stopper protrusion 122. The first limiting protrusion 122 can support the evaporator 2100, and meanwhile, the contact area between the evaporator 2100 and the first gasket 120 can be increased, so that the first gasket 120 can effectively support the evaporator 2100, the position stability of the packaged evaporator 2100 can be improved, and the evaporator 2100 can be prevented from shaking in the transportation process, so that the evaporator 2100 is prevented from being damaged.

Optionally, as shown in fig. 4, the first gasket 120 further includes a first sidewall 123 and a second sidewall 124. The first and second sidewalls 123 and 124 are each connected to the end wall 121, and the end wall 121 may function to support the first and second sidewalls 123 and 124 to improve the structural stability of the first and second sidewalls 123 and 124, thereby improving the structural stability of the first gasket 120 as a whole.

Alternatively, as shown in fig. 4, the first sidewall 123 and the second sidewall 124 are connected to each other, and at this time, the first sidewall 123 and the second sidewall 124 support each other, so as to further improve the structural stability of the first sidewall 123 and the second sidewall 124.

Therefore, the first limiting protrusion 122, the first side wall 123 and the second side wall 124 of the first gasket 120 are all connected to the end wall 121, and the end wall 121, the first limiting protrusion 122, the first side wall 123 and the second side wall 124 are supported in a matching manner, so as to improve the overall structural stability of the first gasket 120.

Alternatively, as shown in fig. 4, the first side wall 123, the second side wall 124 and the first limiting protrusion 122 extend in the same direction, a limiting region 125 is defined between the first side wall 123, the second side wall 124 and the first limiting protrusion 122, and one end of the evaporator 2100 is limited in the limiting region 125. The limiting region 125 mainly functions to avoid the evaporator 2100, and because the limiting region 125 is formed between the first sidewall 123, the second sidewall 124 and the first limiting protrusion 122, when a part of the structure of the evaporator 2100 is limited in the limiting region 125, as shown in fig. 5 and 6, all the sidewalls of the evaporator 2100 can abut against the first sidewall 123, the second sidewall 124 and the first limiting protrusion 122, respectively, and at this time, the first sidewall 123, the second sidewall 124 and the first limiting protrusion 122 are mutually matched to limit the position of the evaporator 2100 in multiple directions, so as to fix the evaporator 2100, prevent the evaporator 2100 from shaking during transportation, and further improve the structural stability of the evaporator 2100.

Alternatively, as shown in fig. 4 and 5, an avoiding groove 1231 is provided on the first sidewall 123, and the partial evaporator 2100 abuts in the avoiding groove 1231. The avoidance groove 1231 is provided to mainly serve as a structure for avoiding the evaporator 2100, a partial structure of the evaporator 2100 is provided in the avoidance groove 1231, the avoidance groove 1231 is used for limiting the position of the evaporator 2100, so that the evaporator 2100 is prevented from shaking, and meanwhile, the avoidance groove 1231 can increase the contact area between the first side wall 123 and the evaporator 2100, so that the structural stability of the evaporator 2100 is further improved.

Optionally, as shown in fig. 4, a second limiting protrusion 126 is disposed on an end of the first limiting protrusion 122 close to the first sidewall 123, an end of the evaporator 2100 is limited in the limiting region 125, and an end of the evaporator 2100 abuts on the second limiting protrusion 126. Because the tube 2110 is disposed on the evaporator 2100, and a part of the structure of the tube 2110 extends toward a direction away from the evaporator 2100, in a process that the first gasket 120 is fitted with the evaporator 2100, the tube 2110 abuts against the end wall 121 of the first gasket 120, so that the end side wall of the evaporator 2100 cannot contact with the end wall 121, and thus a contact area between the evaporator 2100 and the first gasket 120 is reduced, and structural stability of the evaporator 2100 cannot be effectively ensured.

That is, when the first gasket 120 is sleeved on the end of the evaporator 2100 and one end of the evaporator 2100 is limited in the limiting region 125, the end sidewall of one end of the evaporator 2100 can abut against the second limiting protrusion 126 to increase the contact area between the evaporator 2100 and the first gasket 120.

Optionally, a second limiting protrusion 126 is connected to the end wall 121 to increase the structural stability of the second limiting protrusion 126 and ensure that the second limiting protrusion 126 can effectively abut against the evaporator 2100.

Optionally, as shown in fig. 4, an avoidance area 1211 is further disposed on a side surface of the end wall 121 close to the first limiting protrusion 122, and the avoidance area 1211 is used for avoiding the pipeline 2110 on the evaporator 2100. It is ensured that during the process of fitting the first gasket 120 to the evaporator 2100, the pipe 2110 will not obstruct the fitting of the first gasket 120 to the evaporator 2100, i.e. it is ensured that the first gasket 120 can be accurately fitted over the end of the evaporator 2100.

Optionally, the duct 2110 is located in the avoiding region 1211, and one side of the duct 2110 is adapted to abut against the end wall 121, so as to further increase a contact area between the evaporator 2100 and the first gasket 120, thereby improving the structural stability of the evaporator 2100, and meanwhile, the end wall 121 and the avoiding region 1211 cooperate to further increase a contact area between the duct 2110 and the first gasket 120, thereby improving the structural stability of the duct 2110 and preventing the duct 2110 from shaking relative to the evaporator 2100 during transportation.

Alternatively, as shown in fig. 5 and 6, the first limiting protrusion 122 is provided with a first weight-reducing hole 1221, and the outer surfaces of the first side wall 123 and the second side wall 124 are provided with a first weight-reducing groove 1232. The first weight-reducing holes 1221 and the first weight-reducing grooves 1232 are used for reducing the weight of the first gasket 120, so that after the air conditioner component 2000 is packaged, the overall weight of the packaged air conditioner component can be reduced, and the air conditioner component is convenient to transport, and in addition, the first weight-reducing holes 1221 and the first weight-reducing grooves 1232 can also reduce the material consumption of the first gasket 120, so that the production cost of the first gasket 120 is reduced, namely the production cost of the transport package tool 1000 of the air conditioner component 2000 is reduced.

Optionally, the first gasket 120 is formed as an integral piece. It can also be understood that the first gasket 120 is manufactured by using an integrated molding process, and the integrated molding process can ensure that the end wall 121, the first side wall 123, the second side wall 124 and the like do not need to be welded, polished, ground and the like in the early stage in the assembly process of the first gasket 120, thereby effectively simplifying the assembly process, improving the production efficiency of the first gasket 120, and simultaneously ensuring the connection strength among the end wall 121, the first side wall 123, the second side wall 124 and the like, thereby improving the structural stability of the first gasket 120.

Alternatively, as shown in fig. 3 and 7, the second gasket 130 is provided with a limiting groove 131, and the other end of the evaporator 2100 is limited in the limiting groove 131. The other end of the evaporator 2100 is the end of the evaporator 2100 away from the first gasket 120, the other end of the evaporator 2100 is limited on the second gasket 130 by the limiting groove 131, and the second gasket 130 is matched with the first gasket 120 to further limit the position of the evaporator 2100, so that after the positions of the first gasket 120 and the second gasket 130 are effectively fixed, the evaporator 2100 can be fixed, the position of the evaporator 2100 is limited, and the structural stability of the evaporator 2100 is improved.

Optionally, the shape of the limiting groove 131 is adapted to the structural shape of the other end of the evaporator 2100, so as to ensure that the other end of the evaporator 2100 can be limited in the limiting groove 131, and at the same time, ensure that the limiting groove 131 can fix the evaporator 2100.

In a specific example, the first gasket 120 and the second gasket 130 are assembled in the face frame 2200, and the face frame 2200 can effectively fix the first gasket 120 and the second gasket 130, so as to effectively fix the position of the evaporator 2100.

Optionally, the volumes of the first and second gaskets 120 and 130 and the external shapes of the first and second gaskets 120 and 130 are adapted to the internal structure of the face frame 2200, so as to ensure that the first and second gaskets 120 and 130 can be assembled in the face frame 2200, and ensure that the outer side walls of the first and second gaskets 120 and 130 can abut against the inner side walls of the face frame 2200, so as to effectively fix the first and second gaskets 120 and 130, and thus ensure that the evaporator 2100 can be fixedly assembled in the face frame 2200.

It should be noted that, by providing the limiting region 125 on the first gasket 120 and the limiting groove 131 on the second gasket 130, the limiting region 125 enables the first gasket 120 to form an interference fit with one end of the evaporator 2100, and the limiting groove 131 enables the second gasket 130 to form an interference fit with the other end of the evaporator 2100, so as to implement the interference fit between the gasket assembly 100 and the evaporator 2100, so as to effectively limit the position of the evaporator 2100, improve the structural stability of the evaporator 2100, and ensure that the evaporator 2100 can be stably disposed in the bezel 2200.

In a specific example, the interference fit between the gasket assembly 100 and the evaporator 2100 may be an interference fit of 1-2 mm, which ensures that the gasket assembly 100 is limited to the full-wrapping of the evaporator 2100, thereby defining the position of the evaporator 2100.

Optionally, as shown in fig. 6, a weight-reduced area 132 is provided on the second pad 130. The weight reduction region 132 is used for reducing the weight of the second gasket 130, so as to facilitate transportation, and simultaneously, the material consumption of the second gasket 130 can be reduced, so that the production cost of the second gasket 130, that is, the production cost of the transportation packaging tool 1000 of the air conditioner part 2000, is reduced.

In a specific example, as shown in fig. 6 and 7, a second lightening hole 1321 and a second lightening recess 1322 may be formed in the second gasket 130, so as to form the lightening region 132 on the second gasket 130, which facilitates reducing the production cost of the second gasket 130.

Optionally, the second gasket 130 is also formed as an integrally molded piece. That is, the first gasket 120 and the second gasket 130 in the gasket assembly 100 of the present application are formed as an integral molding member to reduce the difficulty in producing the second gasket 130, improve the structural stability of the second gasket 130, and thus ensure the structural stability of the gasket assembly 100.

In some embodiments of the present invention, as shown in conjunction with fig. 3 and 6, a handle depression 140 is provided on a side of the pad assembly 100 remote from the evaporator 2100. In this case, the handle recessed regions 140 are formed on the side surfaces of the first pad 120 and the second pad 130 away from the evaporator 2100, and the handle recessed regions 140 facilitate the user to draw the pad assembly 100, so that after transportation is completed, the pad assembly 100 and the evaporator 2100 can be drawn out from the face frame 2200 through the handle recessed regions 140, thereby improving the assembly and disassembly efficiency.

Optionally, a side of the cushion assembly 100 remote from the evaporator 2100 is spaced from a side wall of the bezel 2200 to provide a clearance fit of the cushion assembly 100 with the bezel 2200, which facilitates access to the handle recessed area 140 by a user during removal of the cushion assembly 100 and removal of the cushion assembly 100 through the handle recessed area 140.

In a specific example, the distance between the pad assembly 100 and the face frame 2200 is not excessively long as the pad assembly 100 is not closely attached to the side wall of the face frame 2200, and the position of the pad assembly 100 can be effectively defined by the face frame 2200.

To sum up, this application adopts liner subassembly 100, the packing of air conditioner spare part 2000 is carried out to the combination form of evaporimeter 2100 and face frame 2200, in order to realize the common vanning between evaporimeter 2100 and face frame 2200, only need occupy the volume space of face frame 2200, can promote the space utilization in the outer packing box by a wide margin, thereby reduce the quantity of outer packing box, can realize reliable inseparable cooperation between evaporimeter 2100 and face frame 2200 simultaneously, reliable high, no quality hidden danger, evaporator 2100 takes place the phenomenon of rocking for face frame 2200 can not appear, and the packing is accomplished the back, easy dismounting, guarantee that dismouting man-hour is not influenced, thereby realize the space utilization maximize in the outer packing box, cost reduction maximize, the vanning volume promotes, and the reliability does not receive the loss.

An embodiment of a transport package assembly 1000 for an air conditioner component 2000 according to the present invention will be described with reference to the accompanying drawings.

As shown in fig. 1 to 7, the transport package assembly 1000 of the air-conditioning part 2000 includes a cushion assembly 100 and an outer package case, and the air-conditioning part 2000 includes an evaporator 2100 and a face frame 2200.

The gasket assembly 100 includes a first gasket 120 and a second gasket 130, the first gasket 120 includes an end wall 121, a first limiting protrusion 122, a second limiting protrusion 126, a first side wall 123 and a second side wall 124 are disposed on the end wall 121, the first side wall 123 and the second side wall 124 are consistent with the extending direction of the first limiting protrusion 122, a limiting region 125 is defined between the first side wall 123 and the first limiting protrusion 122, one end of the evaporator 2100 is limited in the limiting region 125 and can be supported on the first limiting protrusion 122, and meanwhile, one end of the evaporator 2100 can also abut against the second limiting protrusion 126.

An avoidance area 1211 is further disposed on a side surface of the end wall 121 close to the first limiting protrusion 122, and the avoidance area 1211 is used for avoiding the pipeline 2110 on the evaporator 2100.

The first limiting protrusion 122 is provided with a first weight-reducing hole 1221, and the outer surfaces of the first side wall 123 and the second side wall 124 are provided with a first weight-reducing groove 1232.

The second gasket 130 is provided with a limiting groove 131, and the other end of the evaporator 2100 is limited in the limiting groove 131, so that the first gasket 120 and the second gasket 130 are respectively sleeved at two ends of the evaporator 2100.

The second gasket 130 is provided with a weight-reducing region 132 formed by the combination of the second weight-reducing holes 1321 and the second weight-reducing recesses 1322.

A handle depression 140 is provided on a side of the first and second gaskets 120, 130 remote from the evaporator 2100.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted" and "connected" are to be interpreted broadly, e.g., as being either fixedly connected, detachably connected, or integrally connected; either mechanically or electrically. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Other configurations of the transport package assembly 1000 for the air-conditioning part 2000 according to the embodiment of the present invention, such as the structures of the evaporator 2100 and the face frame 2200, are known to those skilled in the art and will not be described in detail herein.

In the description herein, references to the description of the terms "embodiment," "example," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the utility model. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

While embodiments of the utility model have been shown and described, it will be understood by those of ordinary skill in the art that: various changes, modifications, substitutions and alterations can be made to the embodiments without departing from the principles and spirit of the utility model, the scope of which is defined by the claims and their equivalents.

Claims (12)

1. The utility model provides a transportation packing frock of air conditioner spare part, its characterized in that, air conditioner spare part includes evaporimeter and face frame, transportation packing frock includes:

the gasket assembly is provided with a positioning area, and at least one part of the evaporator is matched with the positioning area so that the gasket assembly is sleeved outside the evaporator and assembled in the face frame together with the evaporator;

an outer packaging case adapted to be wrapped around the face frame.

2. The air conditioner part transporting and packaging tool as claimed in claim 1, wherein the gasket assembly comprises a first gasket and a second gasket, and the first gasket and the second gasket are respectively sleeved at two ends of the evaporator.

3. The air conditioner part transporting and packaging tool as claimed in claim 2, wherein the first gasket includes an end wall and a first stopper protrusion, the first stopper protrusion is connected to the end wall, and one end of the evaporator is supported by the first stopper protrusion.

4. The air conditioner part transporting and packaging tool as claimed in claim 3, wherein the first gasket further comprises a first side wall and a second side wall connected to the end wall, the first side wall and the second side wall extend in the same direction as the first limiting protrusion, a limiting region is defined between the first side wall and the first limiting protrusion, and one end of the evaporator is limited in the limiting region.

5. The air conditioner part transporting and packaging tool as claimed in claim 4, wherein an avoiding groove is formed in the first side wall, and part of the evaporator abuts against the inside of the avoiding groove.

6. The air conditioner part transporting and packaging tool as claimed in claim 4, wherein a second limiting protrusion is arranged at one end, close to the first side wall, of the first limiting protrusion, one end of the evaporator is limited in the limiting area, and the end of the evaporator abuts against the second limiting protrusion.

7. The air conditioner part transporting and packaging tool as claimed in claim 3, wherein an avoiding area is further arranged on one side face, close to the first limiting protrusion, of the end wall, and the avoiding area is used for avoiding a pipeline on the evaporator.

8. The air conditioner part transporting and packaging tool as claimed in claim 4, wherein the first limiting protrusion is provided with a first weight reducing hole, and outer surfaces of the first side wall and the second side wall are provided with a first weight reducing groove.

9. The air conditioner part transporting and packaging tool as claimed in claim 2, wherein a limiting groove is formed in the second gasket, and the other end of the evaporator is limited in the limiting groove.

10. The air conditioner part transporting and packaging tool as claimed in claim 9, wherein a weight reduction area is provided on the second pad.

11. The air conditioner part transporting and packaging tool as claimed in claim 2, wherein the first gasket and the second gasket are both integrally formed parts.

12. The air conditioner part transporting and packaging tool as claimed in claim 1, wherein a handle depression is formed in a side surface of the gasket assembly away from the evaporator.

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