CN218991841U - Energy-saving control system for medical air compression equipment - Google Patents

Abstract

The utility model discloses an energy-saving control system for medical air compression equipment, relates to the technical field of medical air compression equipment, solves the problem that the medical air compression equipment in the current market has larger energy consumption during working, and can not perform temperature adjustment and energy saving operation on the medical air compression equipment according to the existence of personnel in a ward, so that a large amount of electric power resources are wasted; the device comprises a compressor, wherein an arc-shaped groove is formed in the top of the side surface of the compressor, a supporting piece is movably arranged on the inner side of the arc-shaped groove, a tooth block is welded on the inner side of the arc-shaped groove, a water tank is fixedly arranged at the bottom of the compressor, and a drain hole is formed in the side surface of the water tank; the wireless smoke sensor and the wireless temperature and humidity sensor are arranged, so that the temperature and humidity change of a ward can be monitored at any time, and the information is sent to the singlechip, so that the wireless communication capacity of the ward is improved, and the wireless centralized temperature and humidity control of the heating ventilation air conditioner in the ward is realized.

Description

Energy-saving control system for medical air compression equipment

Technical Field

The utility model relates to the technical field of medical air compression equipment, in particular to an energy-saving control system for medical air compression equipment.

Background

The air compressor serves to compress a driving refrigerant in an air conditioning refrigerant circuit. The air conditioner compressor is generally installed in an outdoor unit, and the air conditioner compressor extracts a refrigerant from a low pressure area, compresses the refrigerant, sends the compressed refrigerant to a high pressure area for cooling and condensing, and emits heat to the air through a cooling fin, so that the refrigerant is changed from a gaseous state to a liquid state, and the pressure is increased.

However, the medical air compression equipment in the current market has the problem of larger energy consumption during working, and can not be subjected to temperature adjustment and energy saving operation according to the existence of personnel in a ward, so that a large amount of electric power resources are wasted.

Disclosure of Invention

The utility model provides an energy-saving control system for medical air compression equipment, which solves the technical problems that the medical air compression equipment in the current market has larger energy consumption during working, and cannot be subjected to temperature adjustment and energy saving operation according to the existence of personnel in a ward, so that a large amount of electric power resources are wasted.

In order to solve the technical problems, the energy-saving control system for the medical air compression equipment comprises a compressor, wherein an arc-shaped groove is formed in the top of the side face of the compressor, a supporting piece is movably arranged on the inner side of the arc-shaped groove, a tooth block is welded on the inner side of the arc-shaped groove, a water tank is fixedly arranged at the bottom of the compressor, a drain hole is formed in the side face of the water tank, a ventilation assembly is fixedly arranged on the front side of the top of the compressor, and a wireless temperature and humidity sensor and a wireless smoke sensor are respectively arranged below the air groove in the front of the compressor.

Preferably, the support piece comprises a support plate, a driver, a cross rod, a fixed block, a half gear and a mounting hole, wherein the driver is fixedly mounted on the side face of the support plate, an output shaft of the driver penetrates through the side face of the support plate and is fixedly connected with the cross rod, the top end of the cross rod is provided with the fixed block fixedly connected with the side face of the mounting plate, the top of the support plate is provided with the mounting hole, the bottom of the support plate is fixedly connected with the half gear, and the half gear is in meshed transmission connection with the inner side of the arc-shaped groove through the tooth block.

Preferably, the side of the compressor is provided with a through groove at the middle part of the inner side of the arc-shaped groove, and the inner side of the through groove is movably connected with the cross rod.

Preferably, the ventilation assembly comprises a ventilation window, a connecting barrel, a locating plate, a limiting rod, blades, an electrostatic dust collection net and a pull groove, wherein the connecting barrel is fixedly connected with the inner side of the ventilation window, the locating plate and the limiting rod are respectively welded at the bottom of the connecting barrel, the blades are movably installed on the inner side of the ventilation window, the electrostatic dust collection net positioned on the outer side of the blades is installed on the outer side of the ventilation window, and the arc-shaped pull groove is formed in the side face of the ventilation window.

Preferably, a positioning groove is formed in the bottom of the wind tank on the front face of the compressor, and the inner side of the positioning groove is movably connected with a positioning plate at the bottom of the connecting cylinder.

Preferably, the front surface of the compressor is fixedly provided with a singlechip, and the side surface of the singlechip is respectively and fixedly provided with an infrared camera, a buzzer and a display.

Compared with the related art, the energy-saving control system for the medical air compression equipment has the following beneficial effects:

the utility model provides an energy-saving control system for medical air compression equipment, which is characterized in that a singlechip is fixedly arranged on the front side of a compressor, an infrared camera and a buzzer are respectively arranged on the front side of the singlechip, the infrared camera can monitor whether the inner side of a ward is in a safe state or not at all times, a wireless smoke sensor and a wireless temperature and humidity sensor can monitor the temperature and humidity change of the ward at all times, and the information is sent to the singlechip, so that the wireless communication capacity of the ward is improved, and the wireless centralized temperature and humidity control of heating ventilation and air conditioning in the ward is realized.

The utility model provides an energy-saving control system for medical air compression equipment, which is characterized in that a supporting piece is movably arranged in an arc-shaped groove formed in the top of the side surface of a compressor, a half gear meshed and driven with a tooth block at the inner side of the arc-shaped groove is arranged at the bottom of a supporting plate in the supporting piece, a driver fixedly connected with the side surface is arranged at the side surface of the supporting plate, and the driver rotates to drive the supporting plates at the two ends of a cross rod to rotate, so that the angle of the compressor can be adjusted to enlarge the monitoring area of an infrared camera, thereby judging whether personnel exist in a room or not, the compressor is dormant, a ventilation assembly is arranged at the inner side of an air groove formed in the front of the compressor, and a positioning plate and a limiting rod are respectively welded at the bottom of a connecting cylinder connected with the inner side of an air window in the ventilation assembly, so that the air window can be quickly installed and detached from the inner side of the air groove, thereby being convenient for regularly treating dust on an electrostatic dust removing net and avoiding dust from entering into a ward to cause dust to corrode electrical elements.

Drawings

FIG. 1 is a front elevational view of the structure of the present utility model;

FIG. 2 is a front cut-away view of the structure of the present utility model;

FIG. 3 is a view of a structural support of the present utility model;

FIG. 4 is a diagram of a structural ventilation assembly of the present utility model;

reference numerals in the drawings: 1. a compressor; 2. an arc-shaped groove; 3. a support; 31. a support plate; 32. a driver; 33. a cross bar; 34. a fixed block; 35. a half gear; 36. a mounting hole; 4. tooth blocks; 5. a water tank; 6. a drain hole; 7. a through groove; 8. a ventilation assembly; 81. a ventilation window; 82. a connecting cylinder; 83. a positioning plate; 84. a limit rod; 85. a blade; 86. an electrostatic dust collection net; 87. drawing a groove; 9. a wind groove; 10. a positioning groove; 11. a wireless temperature and humidity sensor; 12. a wireless smoke sensor; 13. a single chip microcomputer; 14. an infrared camera; 15. a buzzer; 16. a display.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the utility model; all other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

An embodiment I is given by fig. 1-4, the energy-saving control system for medical air compression equipment of the utility model comprises a compressor 1, wherein an arc-shaped groove 2 is formed in the top of the side surface of the compressor 1, a supporting piece 3 is movably arranged on the inner side of the arc-shaped groove 2, a tooth block 4 is welded on the inner side of the arc-shaped groove 2, a water tank 5 is fixedly arranged at the bottom of the compressor 1, a water drain hole 6 is formed in the side surface of the water tank 5, a ventilation assembly 8 is fixedly arranged on the front side of the top of the compressor 1, and a wireless temperature and humidity sensor 11 and a wireless smoke sensor 12 are respectively arranged below an air duct 9 on the front surface of the compressor 1.

In the second embodiment, based on the first embodiment, the supporting member 3 includes a supporting plate 31, a driver 32, a cross bar 33, a fixed block 34, a half gear 35 and a mounting hole 36, the driver 32 is fixedly mounted on the side surface of the supporting plate 31, an output shaft of the driver 32 penetrates through the side surface of the supporting plate 31 and is fixedly connected with the cross bar 33, a fixed block 34 fixedly connected with the side surface of the mounting plate is mounted on the top end of the cross bar 33, the mounting hole 36 is formed in the top of the supporting plate 31, the half gear 35 is fixedly connected with the bottom of the supporting plate 31, and the half gear 35 is in meshed transmission connection with the inner side of the arc-shaped groove 2 through the tooth block 4; the driver 32 fixedly connected with the side surface is arranged on the side surface of the supporting plate 31, and the driver 32 can rotate to drive the supporting plates 31 at the two ends of the cross rod 33 to rotate, so that the angle of the compressor 1 can be adjusted to increase the monitoring area of the infrared camera 14, and whether personnel exist in a room or not can be judged, and the compressor 1 is dormant.

In the third embodiment, on the basis of the first embodiment, a through groove 7 is formed in the middle of the side surface of the compressor 1, which is located inside the arc-shaped groove 2, and the inside of the through groove 7 is movably connected with a cross bar 33.

Embodiment four, on the basis of embodiment one, ventilation subassembly 8 includes ventilation window 81, connecting cylinder 82, locating plate 83, gag lever post 84, blade 85, electrostatic precipitator net 86 and draw groove 87, the inboard fixed connection connecting cylinder 82 of ventilation window 81, the bottom of connecting cylinder 82 welds locating plate 83 and gag lever post 84 respectively, the inboard movable mounting blade 85 of ventilation window 81, just the outside installation of ventilation window 81 is located the electrostatic precipitator net 86 in the blade 85 outside, arc-shaped draw groove 87 is seted up to the side of ventilation window 81.

In the fifth embodiment, on the basis of the first embodiment, a positioning groove 10 is formed at the bottom of the air duct 9 on the front side of the compressor 1, and the inner side of the positioning groove 10 is movably connected with a positioning plate 83 at the bottom of the connecting cylinder 82.

In a sixth embodiment, on the basis of the first embodiment, a single-chip microcomputer 13 is fixedly installed on the front surface of the compressor 1, and an infrared camera 14, a buzzer 15 and a display 16 are respectively and fixedly installed on the side surface of the single-chip microcomputer 13; the front of the compressor 1 is fixedly provided with the singlechip 13, the front of the singlechip 13 is respectively provided with the infrared camera 14 and the buzzer 15, the infrared camera 14 can monitor whether the inner side of a ward is in a safe state or not at all times, the wireless smoke sensor 12 and the wireless temperature and humidity sensor 11 can monitor the temperature and humidity change of the ward at all times, and the information is sent to the singlechip 13, so that the wireless communication capacity of the ward is improved, and the wireless temperature and humidity centralized control of the heating ventilation air conditioner in the ward is realized.

Working principle:

firstly, the front fixed mounting of compressor 1 has singlechip 13, infrared camera 14 and bee calling organ 15 are installed respectively in the front of singlechip 13, whether infrared camera 14 can monitor the ward inboard constantly and be in safe state, wireless smoke transducer 12 and wireless temperature and humidity transducer 11 can monitor the humiture change in ward constantly, and send these information to singlechip 13, the wireless communication ability in ward has been increased, realize the wireless humiture centralized control of warm ventilation air conditioner in the ward, movable mounting support piece 3 in the arc wall 2 of seting up at compressor 1 side top, the installation of backup pad 31 bottom in support piece 3 and the inboard tooth piece 4 meshing transmission of arc wall 2 semi-gear 35, and backup pad 31 side mounting side fixed connection's driver 32, the rotation of driver 32 can drive the backup pad 31 at horizontal pole 33 both ends and rotate, thereby can adjust the angle to compressor 1 and make infrared camera 14 monitoring area increase, thereby judge whether personnel in the room, carry out dormancy to compressor 1, and the fan duct 9 inboard installation subassembly 8 of air duct, the connecting tube 82 and the inside connection of fan duct 81 bottom in the subassembly 8, can make the fan duct 81 and the fan-out the fixed position-stop lever 83, thereby the dust removal device is convenient for the dust removal from the fan 81 is carried out to the fan-shaped, the dust is carried out to the dust removal device is convenient for the inner side-handling, the dust removal device is fixed to the dust is fixed from the fan 81.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. An energy-saving control system for medical air compression equipment, comprising a compressor (1), characterized in that: the utility model discloses a compressor, including compressor (1), arc wall (2) have been seted up at the side top of compressor (1), the inboard movable mounting of arc wall (2) has support piece (3), just the inboard welding of arc wall (2) has tooth piece (4), the bottom fixed mounting of compressor (1) has water tank (5), wash port (6) have been seted up to the side of water tank (5), the top front side fixed mounting of compressor (1) has ventilation unit (8), wireless temperature and humidity sensor (11) and wireless smoke transducer (12) are installed respectively below wind groove (9) in the front of compressor (1).

2. An energy efficient control system for a medical air compression device according to claim 1, wherein: support piece (3) are including backup pad (31), driver (32), horizontal pole (33), fixed block (34), half gear (35) and mounting hole (36), the side fixed mounting driver (32) of backup pad (31), the output shaft of driver (32) runs through the side of backup pad (31) and fixed connection horizontal pole (33), fixed block (34) with mounting panel side fixed connection is installed on the top of horizontal pole (33), mounting hole (36) are seted up at backup pad (31) top, the bottom fixed connection half gear (35) of backup pad (31), half gear (35) are connected through the inboard meshing transmission of tooth piece (4) with arc groove (2).

3. An energy efficient control system for a medical air compression device according to claim 1, wherein: the side of compressor (1) is located arc wall (2) inboard middle part and has seted up logical groove (7), the inboard and horizontal pole (33) swing joint of logical groove (7).

4. An energy efficient control system for a medical air compression device according to claim 1, wherein: the utility model provides a ventilation subassembly (8) is including ventilation window (81), connecting cylinder (82), locating plate (83), gag lever post (84), blade (85), electrostatic precipitator net (86) and draw groove (87), inboard fixed connection connecting cylinder (82) of ventilation window (81), welding locating plate (83) and gag lever post (84) respectively are connected to the bottom of connecting cylinder (82), inboard movable mounting blade (85) of ventilation window (81), just electrostatic precipitator net (86) that are located the blade (85) outside are installed in the outside of ventilation window (81), arc shape draw groove (87) are seted up to the side of ventilation window (81).

5. An energy efficient control system for a medical air compression device according to claim 1, wherein: the air duct type air compressor is characterized in that a positioning groove (10) is formed in the bottom of an air duct (9) on the front face of the compressor (1), and the inner side of the positioning groove (10) is movably connected with a positioning plate (83) at the bottom of the connecting cylinder (82).

6. An energy efficient control system for a medical air compression device according to claim 1, wherein: the front of the compressor (1) is fixedly provided with a singlechip (13), and the side surface of the singlechip (13) is respectively and fixedly provided with an infrared camera (14), a buzzer (15) and a display (16).

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