CN109990392B

CN109990392B - Air conditioner refrigeration equipment

Info

Publication number: CN109990392B
Application number: CN201910262386.6A
Authority: CN
Inventors: 丁自立
Original assignee: Zhejiang Maizhi Network Technology Co ltd
Current assignee: Jiaxing Zhuoshi Biotechnology Co ltd
Priority date: 2019-04-02
Filing date: 2019-04-02
Publication date: 2022-12-06
Anticipated expiration: 2039-04-02
Also published as: CN109990392A

Abstract

The invention discloses an air-conditioning refrigeration device, which comprises a wall body, wherein a power cavity is arranged in the wall body, a power device is arranged in the power cavity, the power device comprises a lifting motor, and the lower end of a small fan is arranged; this device can accomplish the function to indoor refrigeration and heating, and this device can control reciprocating of air conditioner host computer, according to the problem of air quality, can be faster more energy saving must make the temperature in room can ensure, also can adjust the height of air conditioner position simultaneously, and this device passes through mechanical transmission cooperation, has improved the work efficiency of device, uses the bi-motor to realize multi-functionally simultaneously, has reduced the cost of device and has practiced thrift the energy consumption.

Description

Air conditioner refrigeration equipment

Technical Field

The invention relates to the field of household appliances, in particular to an air-conditioning refrigeration device.

Background

At present, with the development of society and the progress of human beings, the appearance of the air conditioner greatly improves the daily life of people, people can get warm in winter and can enjoy cool in summer, so that people can feel more comfortable in a room.

Disclosure of Invention

The invention aims to provide an air-conditioning refrigeration device to solve the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme: an air-conditioning refrigeration device comprises a wall body, wherein a power cavity is arranged in the wall body, a power device is arranged in the power cavity and comprises a lifting motor, a driving cavity is arranged below the power cavity, a driving device is arranged in the driving cavity, connecting grooves are symmetrically arranged on the left end wall and the right end wall of the driving cavity and communicated with the driving cavity, an inner sliding cavity is arranged on the left end wall of the connecting groove at the left end and communicated with the connecting grooves, an inner device is arranged in the inner sliding cavity and comprises an inner device body, an outer sliding cavity is arranged on the right end wall of the connecting groove at the right end and communicated with the outside, an outer device is arranged in the outer sliding cavity and comprises an outer device body, the power device controls the inner device and the outer device to move up and down and rotate, the driving device controls the inner device and the outer device to rotate, a connecting pipe groove is arranged on the lower end wall of the inner sliding cavity, the upper end wall of the left end of the connecting pipe groove is communicated with the sliding cavity, the upper end wall of the connecting pipe groove is communicated with the lower end wall of the sliding cavity, and the outer device is communicated with the outer device and used for heating or cooling the room.

Preferably, the power device comprises the lifting motor, a lifting motor shaft is connected to the lower end of the lifting motor in a power connection mode, the lifting motor shaft is connected with the lower end wall of the power cavity in a rotating fit mode, an upper lifting motor belt pulley is arranged at the upper end of the lifting motor shaft, a lower lifting motor belt pulley is arranged at the lower end of the lifting motor shaft, an inner machine lead screw and an outer machine lead screw are connected to the upper end wall and the lower end wall of the power cavity in a rotating fit mode respectively, the inner machine lead screw extends downwards to penetrate through the lower end wall of the power cavity to enter the inner machine sliding cavity and is connected with the upper end wall and the lower end wall of the inner machine sliding cavity in a rotating fit mode, an inner machine belt pulley is arranged at the upper end of the inner machine lead screw, the inner machine belt pulley is connected with the lower lifting motor belt pulley through a belt, the outer machine lead screw extends downwards to penetrate through the lower end wall of the power cavity to enter the outer machine sliding cavity and is connected with the upper end wall and the lower end wall of the outer machine sliding cavity in a rotating fit mode, an outer machine belt pulley is arranged at the upper end of the outer machine lead screw, and the outer machine lead screw is connected with the outer machine pulley through a screw, and the outer machine lead screw is used for driving the portion in the outer machine sliding cavity to move up and down.

Preferably, the driving device comprises a first driving mechanism, the first driving mechanism is located at the left end of the driving cavity and comprises a driving shaft, the driving shaft is connected with the upper end wall and the lower end wall of the driving cavity in a rotating fit mode, a long sliding key is arranged at the right end of the driving shaft, a driving belt pulley is arranged at the upper end of the driving shaft, a sliding bevel gear is connected to the lower end of the driving shaft in a sliding fit mode, the sliding bevel gear rotates through the long sliding key, a T-shaped annular groove with an upward opening is formed in the upper end face of the sliding bevel gear, a T-shaped rod is connected in the T-shaped annular groove in a sliding fit mode, the upper end of the T-shaped rod is fixedly connected with the inner machine body, a second driving mechanism identical to the first driving mechanism is symmetrically arranged at the right end of the driving cavity, the upper end of the T-shaped rod of the second driving mechanism is fixedly connected with the outer machine body, the two driving belt pulleys are connected, and a driving motor is arranged at the upper end of the driving shaft at the left end and is used for providing power for the inner machine.

Preferably, the inner machine device comprises an inner machine main body, an inner machine power cavity is arranged in the inner machine main body, the left end wall and the right end wall of the inner machine power cavity are connected with an inner machine driving shaft in a rotating matching way, a driving bevel gear is arranged on the inner machine driving shaft, the inner machine driving shaft extends rightwards to penetrate through the right end wall of the inner machine power cavity to enter the driving cavity, an inner machine driving bevel gear meshed with the sliding bevel gear is arranged at the right end of the driving cavity, a driving bevel gear is arranged at the left end of the inner machine driving shaft, the lower end wall of the inner machine power cavity is connected with a big fan shaft in a rotating fit manner, the upper end of the big fan shaft is provided with a big fan bevel gear meshed with the driving bevel gear, the lower end of the inner machine power cavity is provided with a second heat exchange cavity communicated with the outside, the large fan shaft extends downwards to penetrate through the lower end wall of the inner machine power cavity to enter the second heat exchange cavity, and is connected with the upper end wall of the second heat exchange cavity in a rotating fit manner, the lower end of the large fan shaft is provided with a large fan, the lower end of the second heat exchange cavity is provided with an inner machine protective cover, a second heat exchanger is also arranged in the second heat exchange cavity, one end of the second heat exchanger is connected with the fifth flow groove, the other end of the second heat exchanger is connected with the sixth flow groove, two identical connecting pipes are symmetrically arranged in the connecting pipe grooves in the front and back direction, the left ends of the two connecting pipes are respectively connected with the sixth flowing groove and the fifth flowing groove, the lower end of the second heat exchange cavity is provided with an outer machine filter cover, the inner machine body is in threaded fit connection with the inner machine screw rod, the upper end and the lower end of the inner machine sliding cavity are also provided with inner machine sliding rods, and the inner machine main body is connected with the inner machine sliding rods in a sliding fit manner and used for lowering or raising the temperature indoors.

Preferably, the outer machine device comprises an outer machine main body, the left end wall of the outer machine main body is connected with an outer machine driving shaft in a rotating fit manner, the outer machine driving shaft extends leftwards and penetrates through the left end wall of the outer machine main body to enter the driving cavity, the left end of the outer machine driving shaft is provided with an outer machine driving bevel gear meshed with the sliding bevel gear, the right end of the outer machine driving shaft is provided with a connecting bevel gear, the upper end wall and the lower end wall of the inner machine power cavity are connected with a compressor power shaft in a rotating fit manner, the middle end of the compressor power shaft is provided with a compressor power bevel gear meshed with the connecting bevel gear, the upper end of the compressor power shaft is provided with a compressor, the lower end of the inner machine power cavity is provided with a first heat exchange groove with a downward opening, the compressor power shaft extends downwards to enter the first heat exchange groove and is connected with the upper end wall of the first heat exchange groove in a rotating fit manner, the lower end of the power shaft of the compressor is provided with a transmission gear, the upper end wall of the first heat exchange groove is connected with a fan shaft in a front-back symmetrical and matched manner, the middle end of the fan shaft is provided with a fan gear meshed with the transmission gear, the lower end of the fan shaft is provided with a small fan, the lower end of the first heat exchange groove is provided with an outer machine filter cover, the first heat exchange groove is also internally provided with a first heat exchanger, the rear end of the first heat exchange groove is provided with a reversing valve sliding groove, the front end wall and the rear end wall of the reversing valve sliding groove are connected with a reversing lead screw in a rotating and matched manner, the reversing lead screw is connected with a reversing valve in a threaded manner, the lower end of the reversing valve is provided with a reversing valve cavity, the front end and the rear end of the reversing valve sliding groove are centrally and symmetrically provided with a belt pulley space, and the reversing valve cavity extends through the front end wall and the rear end wall of the reversing valve sliding groove to enter the belt pulley space, the front end of the reversing lead screw is provided with a first ventilation mechanism which comprises a ratchet shaft, the ratchet shaft is connected with the front end wall and the rear end wall of the belt pulley space in a rotating fit manner, the front end of the ratchet shaft is provided with a ratchet belt pulley, the front end of the reversing lead screw is provided with a reversing belt pulley, a belt is connected between the reversing belt pulley and the ratchet belt pulley, the rear end of the belt pulley space is provided with a reversing rack groove with an upward opening, a ratchet chute is arranged in the reversing rack groove, the ratchet shaft extends backwards to penetrate through the front end wall and the rear end wall of the ratchet chute in a rotating fit manner and is connected with the front end wall and the rear end wall of the ratchet chute, a gear ring is arranged in the ratchet chute in a rotating fit manner and is connected with the gear ring, the inner ring of the gear ring is provided with four poking rods, the front end of the ratchet shaft is provided with a pawl rotator, and the pawl rotator is provided with four poking head chutes, a toggle head is connected in a sliding groove of the toggle head in a sliding fit manner, a toggle head sliding spring is connected between the toggle head and the toggle head sliding groove, the pawl rotator can be driven to rotate by the forward rotation of the toggle rod, the pawl rotator can not be driven to rotate by the reverse rotation of the toggle rod, a second air exchange mechanism is arranged in the center of the reversing valve sliding groove in a symmetrical manner, a fourth flow groove is arranged at the upper end of the reversing valve sliding groove, a compressor is arranged in the fourth flow groove, the other end of the fourth flow groove is connected with the first heat exchanger, a first flow groove is arranged at the other end of the first heat exchanger, the other end of the first flow groove is connected with the lower end surface of the reversing valve sliding groove, a second flow groove and a third flow groove are arranged at the lower end of the reversing valve sliding groove, an expansion valve is arranged in the second flow groove, and the third flow groove and the second flow groove are respectively arranged at the other end of the connecting pipe, the outer machine main body is in threaded fit connection with the outer machine lead screw, outer machine slide bars are further arranged on the upper end wall and the lower end wall of the outer machine sliding cavity and in sliding fit connection with the outer machine main body, reversing racks meshed with the gear ring are symmetrically arranged on the upper end wall and the lower end wall of the outer machine sliding cavity, and the reversing racks are used for controlling heat release and cooling of the inner machine.

In conclusion, the beneficial effects of the invention are as follows: this device can accomplish the function to indoor refrigeration and heating, the reciprocating of air conditioner host computer can be controlled to this device, problem according to the air quality, can be faster more energy saving must make the temperature in room can be ensured, the height of air conditioner position also can be adjusted simultaneously, this device passes through mechanical transmission cooperation, the work efficiency of device has been improved, it is multi-functional to use the bi-motor to realize simultaneously, the cost of device has been reduced and the energy consumption has been practiced thrift, this equipment has adopted the spring, the gear, bevel gear, the rack, belt and lead screw etc., it also makes the variety of device function increase simultaneously to have increased air conditioner stability, adopt the spring to cushion and reset equipment moving part, the equipment operating stability has effectively been improved and the life of equipment.

Drawings

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

FIG. 1 is a schematic overall sectional front view of an air conditioning and refrigerating apparatus according to the present invention;

FIG. 2 is a front cross-sectional view of the air conditioner of FIG. 1 in accordance with the present invention;

fig. 3 is a front cross-sectional view of the air conditioning apparatus of fig. 1 in accordance with the present invention;

FIG. 4 is an enlarged view of a portion of the invention at A in FIG. 1;

fig. 5 is a cross-sectional view taken along the line B-B of fig. 2 in accordance with the present invention.

Detailed Description

All of the features disclosed in this specification, or all of the steps of any method or process so disclosed, may be combined in any combination, except combinations of features and/or steps that are mutually exclusive.

Any feature disclosed in this specification (including any accompanying claims, abstract and drawings), may be replaced by alternative features serving equivalent or similar purposes, unless expressly stated otherwise. That is, unless expressly stated otherwise, each feature is only an example of a generic series of equivalent or similar features.

Referring to fig. 1-5, an embodiment of the present invention is shown: an air-conditioning refrigeration device comprises a wall body 100, wherein a power cavity 21 is arranged in the wall body 100, a power device 101 is arranged in the power cavity 21, the power device 101 comprises a lifting motor 22, a driving cavity 94 is arranged below the power cavity 21, a driving device 102 is arranged in the driving cavity 94, connecting grooves 32 are symmetrically arranged on the left end wall and the right end wall of the driving cavity 94, the connecting grooves 32 are communicated with the driving cavity 94, an inner sliding cavity 40 is arranged on the left end wall of the connecting groove 32 on the left end, the inner sliding cavity 40 is communicated with the connecting groove 32, an inner device 103 is arranged in the inner sliding cavity 40, the inner device 103 comprises an inner device main body 43, an outer sliding cavity 33 is arranged on the right end wall of the connecting groove 32 on the right end, the right end wall of the outer sliding cavity 33 is communicated with the outside, an outer device 104 is arranged in the outer sliding cavity 33, the outer device 104 comprises an outer device main body 57, the power device 101 controls the inner device 103 and the outer device 104 to move up and down and rotate, the driving device 102 controls the rotation of the inner device 103 and the connecting groove 104, the lower end wall of the outer sliding cavity 40, the sliding cavity is connected with an upper end wall of the outer sliding tube 37, the outer sliding cavity is connected with the upper end wall of the outer sliding cavity 37, and the upper end wall of the outer sliding device 37, and the upper end wall of the outer sliding cavity is connected with the outer sliding device 37, and the upper end wall of the outer sliding device for heating room.

Beneficially, the power device 101 includes the lifting motor 22, a lifting motor shaft 23 is dynamically connected to a lower end of the lifting motor 22, the lifting motor shaft 23 is connected to a lower end wall of the power cavity 21 in a rotationally matched manner, an upper lifting motor belt pulley 24 is arranged at an upper end of the lifting motor shaft 23, a lower lifting motor belt pulley 25 is arranged at a lower end of the lifting motor shaft 23, an upper end wall and a lower end wall of the power cavity 21 are respectively connected to an inner machine lead screw 46 and an outer machine lead screw 27 in a rotationally matched manner, the inner machine lead screw 46 extends downward to penetrate through the lower end wall of the power cavity 21 to enter the inner machine sliding cavity 40 and is connected to the upper end wall and the lower end wall of the inner machine sliding cavity 40 in a rotationally matched manner, an inner machine belt pulley 45 is arranged at an upper end of the lead screw 46, the inner machine belt pulley 45 is connected to the lower lifting motor belt pulley 25 through a belt, the outer machine lead screw 27 extends downward to penetrate through the lower end wall of the power cavity 21 to enter the outer machine sliding cavity 33 and is connected to the upper end wall and the lower end wall of the outer machine sliding cavity 33 in a rotationally matched manner, an upper end and an outer machine belt pulley 26 is arranged at an upper end of the outer machine lead screw 27, the outer machine pulley 26 is connected to drive the outer machine pulley 24 through a screw, and the outer machine pulley 24, and the outer machine pulley 27, and the outer machine pulley is connected to drive the outer machine pulley 27 to move up and to the outer machine pulley to the outer machine sliding cavity in a screw thread.

Advantageously, the driving device 102 includes a first driving mechanism, which is located at the left end of the driving cavity 94, and includes a driving shaft 30, the driving shaft 30 is connected with the upper and lower end walls of the driving cavity 94 in a rotating fit manner, the right end of the driving shaft 30 is provided with a long sliding key 31, the upper end of the driving shaft 30 is provided with a driving pulley 29, the lower end of the driving shaft 30 is connected with a sliding bevel gear 86 in a sliding fit manner, the sliding bevel gear 86 rotates through the long sliding key 31, the upper end face of the sliding bevel gear 86 is provided with a T-shaped ring slot 87 which is opened upwards, a T-shaped rod 88 is connected in a sliding fit manner in the T-shaped ring slot 87, the upper end of the T-shaped rod 88 is fixedly connected with the inner machine body 43, the right end of the driving cavity 94 is symmetrically provided with a second driving mechanism which is the same as the first driving mechanism, wherein the upper end of the T-shaped rod 88 of the second driving mechanism is fixedly connected with the outer machine body 57, the two driving pulleys 29 are connected through a belt, and the upper end of the driving shaft 30 at the left end is provided with a driving motor 44 which is used for providing power.

Beneficially, the inner machine device 103 includes the inner machine main body 43, an inner machine power cavity 79 is arranged in the inner machine main body 43, the left and right end walls of the inner machine power cavity 79 are connected with an inner machine driving shaft 41 in a rotating fit manner, a driving bevel gear 78 is arranged on the inner machine driving shaft 41, the inner machine driving shaft 41 extends rightwards to penetrate through the right end wall of the inner machine power cavity 79 to enter the driving cavity 94, an inner machine driving bevel gear 39 meshed with the sliding bevel gear 86 is arranged at the right end of the driving cavity 94, a driving bevel gear 78 is arranged at the left end of the inner machine driving shaft 41, a big fan shaft 75 is connected with the lower end wall of the inner machine power cavity 79 in a rotating fit manner, a big fan bevel gear 76 meshed with the driving bevel gear 78 is arranged at the upper end of the big fan shaft 75, a second heat exchange cavity 84 communicated with the outside is arranged at the lower end of the inner machine power cavity 79, the large fan shaft 75 extends downwards to penetrate through the lower end wall of the inner machine power cavity 79 to enter the second heat exchange cavity 84 and is connected with the upper end wall of the second heat exchange cavity 84 in a rotating matching manner, the large fan 74 is arranged at the lower end of the large fan shaft 75, the inner machine protective cover 42 is arranged at the lower end of the second heat exchange cavity 84, a second heat exchanger 85 is further arranged in the second heat exchange cavity 84, one end of the second heat exchanger 85 is connected with a fifth flow groove 81, the other end of the second heat exchanger 85 is connected with a sixth flow groove 82, two identical connecting pipes 38 are symmetrically arranged in the connecting pipe grooves 37 in a front-back manner, the left ends of the two connecting pipes 38 are respectively connected with the sixth flow groove 82 and the fifth flow groove 81, the outer machine filter cover 36 is arranged at the lower end of the second heat exchange cavity 84, the inner machine main body 43 is connected with the inner machine 46 in a threaded matching manner, and slide bars 80 are further arranged at the upper end and the lower end of the inner machine sliding cavity 40, the inner machine main body 43 is connected with the inner machine sliding rod 80 in a sliding fit mode, and the inner machine main body is used for lowering or raising the temperature indoors.

Advantageously, the outer machine device 104 comprises the outer machine body 57, the left end wall of the outer machine body 57 is connected with an outer machine driving shaft 35 in a rotating fit manner, the outer machine driving shaft 35 extends leftwards and penetrates through the left end wall of the outer machine body 57 to enter the driving cavity 94, the left end of the outer machine driving shaft 35 is provided with an outer machine driving bevel gear 34 engaged with the sliding bevel gear 86, the right end of the outer machine driving shaft 35 is provided with a connecting bevel gear 96, the upper end and the lower end wall of the inner machine power cavity 49 are connected with a compressor power shaft 51 in a rotating fit manner, the middle end of the compressor power shaft 51 is provided with a compressor power bevel gear 48 engaged with the connecting bevel gear 96, the upper end of the compressor power shaft 51 is provided with a compressor 58, the lower end of the inner machine power cavity 49 is provided with a first heat exchange groove 50 with a downward opening, and the compressor power shaft 51 extends downwards to enter the first heat exchange groove 50, the first heat exchange tank 50 is connected with the upper end wall of the first heat exchange tank 50 in a rotationally matched manner, the lower end of a compressor power shaft 51 is provided with a transmission gear 55, the upper end wall of the first heat exchange tank 50 is connected with a fan shaft 52 in a rotationally matched manner in a front-back symmetrical manner, the middle end of the fan shaft 52 is provided with a fan gear 53 meshed with the transmission gear 55, the lower end of the fan shaft 52 is provided with a small fan 54, the lower end of the first heat exchange tank 50 is provided with an outer machine filter cover 36, the first heat exchanger 56 is also arranged in the first heat exchange tank 50, the rear end of the first heat exchange tank 50 is provided with a reversing valve chute 68, the front end wall and the rear end wall of the reversing valve chute 68 are connected with a reversing screw 77 in a rotationally matched manner, the reversing screw 77 is connected with a reversing valve 69 in a threaded manner, the lower end of the reversing valve 69 is provided with a reversing valve cavity 70, and the front end and rear end centers of the reversing valve chute 68 are symmetrically provided with belt pulley spaces 59, the reversing valve cavity 70 extends forwards and backwards to penetrate through the front end wall and the rear end wall of the reversing valve sliding groove 68 to enter the belt pulley space 59 and is connected with the front end wall and the rear end wall of the belt pulley space 59 in a rotating fit manner, the front end of the reversing lead screw 77 is provided with a first ventilation mechanism which comprises a ratchet shaft 62, the ratchet shaft 62 is connected with the front end wall and the rear end wall of the belt pulley space 59 in a rotating fit manner, the front end of the ratchet shaft 62 is provided with a ratchet pulley 61, the front end of the reversing lead screw 77 is provided with a reversing pulley 67, a belt is connected between the reversing pulley 67 and the ratchet pulley 61, the rear end of the belt pulley space 59 is provided with a reversing rack groove 65 with an upward opening, a ratchet sliding groove 90 is arranged in the reversing rack groove 65, the ratchet shaft 62 extends backwards to penetrate through the front end wall and the rear end wall of the ratchet sliding groove 90 in a rotating fit manner to be connected with a gear ring 64, the inner ring of the gear ring 64 is provided with four poke rods 91, the front end of the ratchet shaft 62 is provided with a pawl rotator 66, four poke head sliding chutes 92 are arranged in the pawl rotator 66, poke heads 63 are connected in the poke head sliding chutes 92 in a sliding fit manner, poke head sliding springs 93 are connected between the poke heads 63 and the poke head sliding chutes 92, the poke rods 91 rotate forwards to drive the pawl rotator 66 to rotate, the poke rods 91 rotate backwards to drive the pawl rotator 66 not to rotate, a second air exchange mechanism is symmetrically arranged in the center of the reversing valve sliding chutes 68, the upper end of the reversing valve sliding chutes 68 are provided with fourth flow grooves 60, compressors 58 are arranged in the fourth flow grooves 60, the other ends of the fourth flow grooves 60 are connected with the first heat exchanger 56, and the other ends of the first heat exchanger 56 are provided with first flow grooves 73, the other end of the first flow groove 73 is connected with the lower end face of the reversing valve sliding groove 68, the lower end of the reversing valve sliding groove 68 is provided with a second flow groove 72 and a third flow groove 71, an expansion valve 89 is arranged in the second flow groove 72, the third flow groove 71 and the second flow groove 72 are respectively connected with the other end of the connecting pipe 38, the outer machine main body 57 is in threaded fit connection with the outer machine lead screw 27, the upper end wall and the lower end wall of the outer machine sliding cavity 33 are also provided with outer machine sliding rods 47, the outer machine sliding rods 47 are in sliding fit connection with the outer machine main body 57, the upper end wall and the lower end wall of the outer machine sliding cavity 33 are symmetrically provided with reversing racks 28 meshed with the gear ring 64, and the reversing racks are used for controlling heat release and cold release of the inner machine.

In the following, the applicant will describe in detail a method for using an air-conditioning and refrigerating apparatus of the present application with reference to the accompanying fig. 1 to 5 and the specific components of the air-conditioning and refrigerating apparatus of the present application described above: first, in the initial state, the inner unit body 43 is located at the upper end of the inner unit sliding chamber 40, and the outer unit body 57 is located at the lower end of the outer unit sliding chamber 33.

When the cold air conditioner is used, firstly, the driving motor 44 is turned on, so that the driving bevel gear 78, the big fan bevel gear 76, the big fan shaft 75 and the big fan 74 of the inner machine are driven to rotate by the rotation of the driving belt pulley 29, the driving shaft 30, the long sliding key 31, the outer machine driving bevel gear 34, the outer machine driving shaft 35, the inner machine driving bevel gear 39, the inner machine driving shaft 41 and the sliding bevel gear 86, so that the outer machine connecting bevel gear 96, the outer machine driving shaft 35, the compressor power bevel gear 48 and the compressor power shaft 51 are driven to rotate, so that the transmission gear 55, the fan shaft 52, the fan gear 53 and the small fan 54 are driven to rotate, the compressor power shaft 51 is driven to rotate, so that the compressor 58 is turned on, the low-pressure gas at the right end of the compressor 58 enters the high-temperature and high-pressure gas from the left end of the compressor 58, then enters the first heat exchanger 56, then the high-temperature and high-temperature liquid is discharged from the first heat exchanger 56 by the rotation of the small fan 54, then the high-temperature and high-pressure liquid is gasified by the expansion valve 89, so that the low-temperature gas is changed into low-temperature gas of the low-temperature gas in the compressor 58, the process, so that the upper and the outer machine 24 and the lifting motor shaft 23 are driven to move up and down, so that the lifting motor shaft 23 and the lifting motor shaft 23 move, the lifting motor shaft 23 and the lifting motor shaft 23 are driven to move, so that the lifting motor shaft 23, the lifting pawl 23, so that the lifting motor shaft 23 moves up and the lifting pawl 23 moves, so that the lifting motor shaft 23 moves, and the lifting pawl 23 moves, and the lifting motor shaft 23, so that the lifting motor shaft 23 moves up and the lifting pawl 23 moves up and the lifting motor 24 moves up and the lifting pawl 23 moves, thereby drive ratchet pulley 61, switching-over pulley 67 and switching-over lead screw 77 rotate, thereby make switching-over valve 69 turn right and move, make the wind channel switching-over, open driving motor 44 this moment again, the left and right sides state of compressor 58 changes, make indoor blowing hot-blast, outdoor blowing cold wind, because the quality of steam is lower, it is heavy up-going, heating effect and speed can be faster like this, the quality of air conditioning is higher, it is heavy up-down moving, make refrigerated effect and speed can be faster.

The invention has the beneficial effects that: this device can accomplish the function to indoor refrigeration and heating, and this device can control reciprocating of air conditioner host computer, according to the problem of air quality, can be faster more the energy saving must make the temperature in room can ensure, also can adjust the height of air conditioner position simultaneously, and this device passes through mechanical transmission cooperation, has improved the work efficiency of device, uses the bi-motor to realize multi-functionally simultaneously, has reduced the cost of device and has practiced thrift the energy consumption.

The above description is only an embodiment of the invention, but the scope of the invention is not limited thereto, and any changes or substitutions that are not thought of through the inventive work should be included in the scope of the invention. Therefore, the protection scope of the invention should be subject to the protection scope defined by the claims.

Claims

1. An air conditioner refrigeration plant, includes the wall body, its characterized in that: the wall body is internally provided with a power cavity, a power device is arranged in the power cavity, the power device comprises a lifting motor, a driving cavity is arranged below the power cavity, a driving device is arranged in the driving cavity, connecting grooves are symmetrically arranged on the left end wall and the right end wall of the driving cavity, the connecting grooves are communicated with the driving cavity, an inner sliding cavity is arranged on the left end wall of the connecting groove at the left end, the inner sliding cavity is communicated with the connecting grooves, an inner device is arranged in the inner sliding cavity, the inner device comprises an inner device body, the right end wall of the connecting groove at the right end is provided with an outer sliding cavity, the right end wall of the outer sliding cavity is communicated with the outside, an outer device is arranged in the outer sliding cavity, the outer device comprises an outer device body, the power device controls the inner device and the outer device to move up and down and rotate, the driving device controls the inner device and the outer device to rotate, a connecting pipe groove is arranged on the lower end wall of the inner sliding cavity, the upper end wall of the left end of the inner connecting pipe groove is communicated with the sliding cavity, the upper end wall of the connecting pipe groove is communicated with the outer sliding cavity, and the upper end wall of the connecting pipe groove is communicated with the lower end wall of the outer sliding cavity, and the outer device is used for cooling or heating the outer device.

2. An air conditioning refrigeration unit as set forth in claim 1 wherein: the power device comprises the lifting motor, the lower end of the lifting motor is in power connection with a lifting motor shaft, the lifting motor shaft is in rotating fit connection with the lower end wall of the power cavity, an upper lifting motor belt pulley is arranged at the upper end of the lifting motor shaft, a lower lifting motor belt pulley is arranged at the lower end of the lifting motor shaft, an inner machine screw and an outer machine screw are respectively in rotating fit connection with the upper end wall and the lower end wall of the power cavity, the inner machine screw extends downwards to penetrate through the lower end wall of the power cavity to enter the inner machine sliding cavity and are in rotating fit connection with the upper end wall and the lower end wall of the inner machine sliding cavity, an inner machine belt pulley is arranged at the upper end of the inner machine screw, the inner machine belt pulley is connected with the lower lifting motor belt pulley through a belt, the outer machine screw extends downwards to penetrate through the lower end wall of the power cavity to enter the outer machine sliding cavity and is in rotating fit connection with the upper end wall and the lower end wall of the outer machine sliding cavity, an outer machine belt pulley is arranged at the upper end of the outer machine screw, the outer machine screw is connected with the upper lifting motor belt pulley through a belt pulley, and the inner machine screw and the outer machine screw are in opposite threads, and are used for driving the outer machine to move up and down.

3. An air conditioning refrigeration unit as set forth in claim 2 wherein: the driving device comprises a first driving mechanism, the first driving mechanism is located at the left end of the driving cavity and comprises a driving shaft, the driving shaft is connected with the upper end wall and the lower end wall of the driving cavity in a rotating fit mode, a long sliding key is arranged at the right end of the driving shaft, a driving belt pulley is arranged at the upper end of the driving shaft, the lower end of the driving shaft is connected with a sliding bevel gear in a sliding fit mode, the sliding bevel gear rotates through the long sliding key, a T-shaped annular groove with an upward opening is formed in the upper end face of the sliding bevel gear, a T-shaped rod is connected in the T-shaped annular groove in a sliding fit mode, the upper end of the T-shaped rod is fixedly connected with the inner machine body, a second driving mechanism identical to the first driving mechanism is symmetrically arranged at the right end of the driving cavity, the upper end of the T-shaped rod of the second driving mechanism is fixedly connected with the outer machine body, the two driving belt pulleys are connected through a belt, a driving motor is arranged at the upper end of the driving shaft at the left end, and the driving mechanism is used for providing power for the outer machine.

4. An air conditioning refrigeration unit as set forth in claim 3 wherein: the inner machine device comprises an inner machine main body, an inner machine power cavity is arranged in the inner machine main body, the left end wall and the right end wall of the inner machine power cavity are connected with an inner machine driving shaft in a rotating matching way, a driving bevel gear is arranged on the inner machine driving shaft, the inner machine driving shaft extends rightwards to penetrate through the right end wall of the inner machine power cavity to enter the driving cavity, the right end of the driving cavity is provided with an inner machine driving bevel gear meshed with the sliding bevel gear, the left end of the inner machine driving shaft is provided with a driving bevel gear, the lower end wall of the inner machine power cavity is connected with a big fan shaft in a rotating fit way, the upper end of the big fan shaft is provided with a big fan bevel gear which is meshed with the driving bevel gear, the lower end of the inner machine power cavity is provided with a second heat exchange cavity communicated with the outside, the large fan shaft extends downwards to penetrate through the lower end wall of the inner machine power cavity to enter the second heat exchange cavity, and is connected with the upper end wall of the second heat exchange cavity in a rotating fit manner, the lower end of the large fan shaft is provided with a large fan, the lower end of the second heat exchange cavity is provided with an inner machine protective cover, a second heat exchanger is also arranged in the second heat exchange cavity, one end of the second heat exchanger is connected with the fifth flow groove, the other end of the second heat exchanger is connected with the sixth flow groove, two identical connecting pipes are symmetrically arranged in the connecting pipe grooves in the front and back direction, the left ends of the two connecting pipes are respectively connected with the sixth flowing groove and the fifth flowing groove, the lower end of the second heat exchange cavity is provided with an outer machine filter cover, the inner machine body is in threaded fit connection with the inner machine screw rod, the upper end and the lower end of the inner machine sliding cavity are also provided with inner machine sliding rods, and the inner machine main body is connected with the inner machine sliding rods in a sliding fit manner and used for lowering or raising the temperature indoors.

5. An air conditioning refrigeration unit as set forth in claim 4 wherein: the outer machine device comprises an outer machine main body, wherein an outer machine driving shaft is connected to the left end wall of the outer machine main body in a rotating fit manner, extends leftwards and penetrates through the left end wall of the outer machine main body to enter the driving cavity, an outer machine driving bevel gear meshed with the sliding bevel gear is arranged at the left end of the outer machine driving shaft, a connecting bevel gear is arranged at the right end of the outer machine driving shaft, a compressor power shaft is connected to the upper end wall and the lower end wall of the inner machine power cavity in a rotating fit manner, a compressor power bevel gear meshed with the connecting bevel gear is arranged at the middle end of the compressor power shaft, a compressor is arranged at the upper end of the compressor power shaft, a first heat exchange groove with a downward opening is arranged at the lower end of the inner machine power cavity, the compressor power shaft extends downwards to enter the first heat exchange groove and is connected with the upper end wall of the first heat exchange groove in a rotating fit manner, the lower end of the power shaft of the compressor is provided with a transmission gear, the upper end wall of the first heat exchange groove is symmetrically connected with a fan shaft in a front-back rotation matching manner, the middle end of the fan shaft is provided with a fan gear meshed with the transmission gear, the lower end of the fan shaft is provided with a small fan, the lower end of the first heat exchange groove is provided with an outer machine filter cover, the first heat exchange groove is also internally provided with a first heat exchanger, the rear end of the first heat exchange groove is provided with a reversing valve sliding groove, the front end wall and the rear end wall of the reversing valve sliding groove are connected with a reversing lead screw in a rotation matching manner, the reversing lead screw is connected with a reversing valve in a thread matching manner, the lower end of the reversing valve is provided with a reversing valve cavity, the front end and the rear end of the reversing valve sliding groove are symmetrically provided with belt pulley spaces, and the reversing valve cavity extends through the front end wall and the rear end wall of the reversing valve sliding groove to enter the belt pulley spaces, the front end of the reversing lead screw is provided with a first ventilation mechanism which comprises a ratchet shaft, the ratchet shaft is connected with the front end wall and the rear end wall of the belt pulley space in a rotating fit manner, the front end of the ratchet shaft is provided with a ratchet belt pulley, the front end of the reversing lead screw is provided with a reversing belt pulley, a belt is connected between the reversing belt pulley and the ratchet belt pulley, the rear end of the belt pulley space is provided with a reversing rack groove with an upward opening, a ratchet chute is arranged in the reversing rack groove, the ratchet shaft extends backwards to penetrate through the front end wall and the rear end wall of the ratchet chute in a rotating fit manner and is connected with the front end wall and the rear end wall of the ratchet chute, a gear ring is arranged in the ratchet chute in a rotating fit manner and is connected with the gear ring, the inner ring of the gear ring is provided with four poking rods, the front end of the ratchet shaft is provided with a pawl rotator, and the pawl rotator is provided with four poking head chutes, a toggle head is connected in a sliding chute of the toggle head in a sliding fit manner, a toggle head sliding spring is connected between the toggle head and the toggle head sliding chute, the pawl rotator can be driven to rotate by forward rotation of the toggle rod, the pawl rotator can not be driven to rotate by reverse rotation of the toggle rod, a second ventilation mechanism is symmetrically arranged at the center of the reversing valve sliding chute, a fourth flow groove is arranged at the upper end of the reversing valve sliding chute, a compressor is arranged in the fourth flow groove, the other end of the fourth flow groove is connected with the first heat exchanger, a first flow groove is arranged at the other end of the first heat exchanger, the other end of the first flow groove is connected with the lower end surface of the reversing valve sliding chute, a second flow groove and a third flow groove are arranged at the lower end of the reversing valve sliding chute, an expansion valve is arranged in the second flow groove, and the third flow groove and the second flow groove are respectively connected with the other end of the connecting pipe, the outer machine main body is in threaded fit connection with the outer machine lead screw, outer machine slide bars are further arranged on the upper end wall and the lower end wall of the outer machine sliding cavity and in sliding fit connection with the outer machine main body, reversing racks meshed with the gear ring are symmetrically arranged on the upper end wall and the lower end wall of the outer machine sliding cavity, and the reversing racks are used for controlling heat release and cooling of the inner machine.