CN210801539U

CN210801539U - Self-learning type co-frequency-conversion energy-saving control system for civil ground source heat pump air conditioner

Info

Publication number: CN210801539U
Application number: CN201920839109.2U
Authority: CN
Inventors: 周东林; 陆惠翔
Original assignee: Shanghai Miqing Intelligent Technology Co Ltd
Current assignee: Shanghai Miqing Intelligent Technology Co Ltd
Priority date: 2019-06-05
Filing date: 2019-06-05
Publication date: 2020-06-19
Anticipated expiration: 2029-06-05

Abstract

The utility model discloses a self-learning type co-frequency-conversion energy-saving control system of a civil ground source heat pump air conditioner, which comprises a base, a first shell and a second shell, the base is in a horizontal plate shape, the first casing and the second casing are both in a rectangular box shape and are respectively arranged at the front end and the rear end of the top surface of the base, an ice storage box is communicated with one side of the first machine shell, a water collecting tank is fixed in the middle of the top surface outside the first machine shell, a water inlet and a water outlet are respectively arranged at the top end of the water collecting tank, the water inlet is external to have water supply pipeline, and another port of water supply pipeline is connected with the second water pump, the water inlet of second water pump is passing through the pipeline and is being linked up the ice storage box, the utility model relates to a novelty has the energy-conserving function of deicing cyclic utilization, can make the water loss volume that the cooling tower exists reduce, has reduced the big and extravagant problem of energy consumption.

Description

Self-learning type co-frequency-conversion energy-saving control system for civil ground source heat pump air conditioner

Technical Field

The utility model belongs to the technical field of the air conditioner, concretely relates to civilian earth source heat pump air conditioner learns formula altogether and becomes frequency-conversion energy-saving control system.

Background

Air conditioners are air conditioners. The equipment is used for manually regulating and controlling parameters such as temperature, humidity, cleanliness, flow rate and the like of ambient air in a building/structure, and generally comprises a cold source/heat source device, a cold and hot medium transmission and distribution system, a tail end device and other major parts and other auxiliary devices. The system mainly comprises a refrigeration host, a water pump, a fan and a pipeline system. The end device is responsible for specifically processing the air state by utilizing the cold and heat quantity from the transmission and distribution so as to enable the air parameters of the target environment to meet the requirements.

At present, cooling towers are arranged in most air conditioners, the water loss of the cooling towers is not known to be large, the icing phenomenon can occur in cold winter, energy is consumed to carry out extra deicing measures, and the problems of large energy consumption and energy waste exist.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a civilian ground source heat pump air conditioner learns formula altogether and becomes frequency energy-saving control system, specifically realizes through following technical scheme:

the utility model provides a civilian ground source heat pump air conditioner is from study formula and is become frequency energy-saving control system altogether, includes base, first casing and second casing, its characterized in that: the base is in a horizontal plate shape, the first shell and the second shell are both in a rectangular box shape, the first shell and the second shell are respectively arranged at the front end and the rear end of the top surface of the base, an ice storage box is communicated with one side of the first shell, a water collecting tank is fixed in the middle of the top surface outside the first shell, and a water inlet and a water outlet are respectively formed in the top end of the water collecting tank;

the water inlet is externally connected with a water supplementing pipeline, the other port of the water supplementing pipeline is connected with a second water pump, and the water inlet of the second water pump is communicated with the ice storage box through a pipeline;

the water outlet is connected with a first water pump through an external pipeline, and a water outlet of the first water pump is connected with the top end of the first machine shell through a pipeline;

a strip-shaped plate-shaped scraping blade is longitudinally arranged on the inner bottom surface of the first machine shell, a hydraulic cylinder is arranged on the base on the other side of the first machine shell, and a telescopic rod of the hydraulic cylinder extends into the first machine shell and is fixedly connected with the scraping blade;

the base below the ice storage box is internally limited with an installation groove, heating wires are distributed in the installation groove, and external leads of the heating wires extend out of the installation groove and are connected with a power supply.

Furthermore, limiting strips are arranged on the front side and the rear side of the water collecting tank, a horizontal rod is arranged in the middle of each limiting strip, L-shaped rods are arranged at two ends of each limiting strip, and the L-shaped rods are fixedly connected with the top surface of the first shell; the horizontal rods in the middle of the limiting strips on the two sides are respectively contacted with the two opposite sides of the water collecting tank.

Furthermore, the bottom of the first casing is an inclined plane with a high end and a low end, and the high end of the inclined plane is close to the hydraulic cylinder.

Furthermore, the exhaust hole has been seted up on the base left side, and the exhaust hole is link up with the mounting groove, and the exhaust hole passes through exhaust duct and connects the suction fan, and suction fan fixed mounting is on the ice storage box top, and the air outlet of suction fan is located the ice storage box.

Furthermore, a motor is arranged on one side of the suction fan and fixedly connected with the middle part of the suction fan through a motor shaft, the motor is fixedly connected to one side of a fixed plate, and the fixed plate is fixedly connected to the top end of the ice storage box.

Furthermore, a water level sensor is fixedly connected to the inner wall of the top surface of the first casing, a single chip microcomputer is fixedly connected to the inner wall of the second casing, an information output end of the water level sensor is electrically connected with an output end of the single chip microcomputer, and an output end of the single chip microcomputer is connected with a buzzer.

The utility model has the advantages that: the self-learning type co-variable frequency energy-saving control system of the ground source heat pump air conditioner extracts water in the water collecting tank through the first water pump, the water flows into the first machine shell from the water outlet pipeline, the scraper is repeatedly driven by the telescopic rod of the hydraulic cylinder to push ice residues accumulated at the bottom of the second machine shell into the ice storage box, the ice residues are melted by the electric heating wire, the melted water in the ice storage chamber is extracted through the second water pump and the water replenishing pipeline and enters the water collecting tank, the effect of deicing cyclic utilization and energy conservation is achieved, the water loss of the cooling tower is reduced, even if the freezing phenomenon can occur in cold winter, energy consumption is saved, extra deicing measures are additionally carried out, and the problems of high energy consumption and energy waste are solved.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this application, illustrate embodiment(s) of the invention and together with the description serve to explain the invention without limitation. In the drawings:

FIG. 1 is a schematic structural view of the present invention;

fig. 2 is a schematic structural view of the suction fan of the present invention;

fig. 3 is a schematic view of the first housing structure of the present invention

In the figure: 1. a water replenishing pipeline; 2. a motor; 3. a suction fan; 4. a buzzer; 5. a water level sensor; 6. A telescopic rod; 7. a limiting strip; 8. scraping a blade; 9. an exhaust duct; 10. an ice bank; 11. a first outlet conduit; 12. an electric heating wire; 13. a first water pump; 14. a water collection tank; 15. a base; 16. a hydraulic cylinder; 17. A single chip microcomputer; 18. a fixing plate; 19. a second housing; 20. a first housing; 21 water inlet; 22. a water outlet; 23. a second outlet conduit; 24. and a second water pump.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1, a self-learning common frequency conversion energy-saving control system for a civil ground source heat pump air conditioner comprises a base 15, a first casing 20 and a second casing 19, wherein the base 15 is in a horizontal plate shape, the first casing 20 and the second casing 19 are both in a rectangular box shape, the first casing 20 and the second casing 19 are respectively arranged at the front end and the rear end of the top surface of the base 15, an ice storage box 10 is communicated with one side of the first casing 20, a water collection box 14 is fixed at the middle part of the top surface of the outside of the first casing 20, a water inlet 21 and a water outlet 22 are respectively arranged at the top end of the water collection box 14, a water supplementing pipeline 1 is externally connected to the water inlet 21, a second water pump 24 is connected to the other end of the water supplementing pipeline 1, the water inlet of the second water pump 24 is communicated with the ice storage box 10 through a pipeline, the water outlet 22 is connected with a first water pump 13 through an external pipeline, and, the interior bottom surface of first casing 20 vertically is equipped with the slabby doctor-bar 8 of bar, is equipped with pneumatic cylinder 16 on the base 15 of first casing 20 opposite side, the telescopic link 6 of pneumatic cylinder 16 stretches into in first casing 20 and with doctor-bar 8 rigid coupling, the bottom of first casing 20 is the high inclined plane of one end height, and the high-end department on inclined plane is close to pneumatic cylinder 16, the base 15 internal limit of ice-storage box 10 below has the mounting groove, and the distribution has heating wire 12 in the mounting groove, and heating wire 12 external conductor stretches out the mounting groove and is connected with the power.

The water pump 13 is used for extracting water in the water collecting tank 14, the water flows into the second machine shell 20 from the water pipeline, the telescopic rod 6 of the hydraulic cylinder 16 is used for repeatedly driving the scraping blade 8 to push ice slag accumulated at the bottom of the second machine shell 19 into the ice storage box 10, the heating wire 12 is used for melting the ice slag, the second water pump 24 and the water supplementing pipeline 1 are used for extracting water melted in the ice storage box 10, and the water enters the water collecting tank 14, so that the effect of deicing, circulation and energy conservation is achieved.

Referring to fig. 1, 2 and 3, a water inlet 21 and a water outlet 22 at the water collection tank 14 are respectively connected with a first water outlet pipeline and a water replenishing pipeline 1 in a threaded detachable manner, so that the water collection tank is convenient to maintain and clean, the front side and the rear side of the water collection tank 14 are respectively provided with a limiting strip 7, the middle part of each limiting strip 7 is a horizontal rod, the two ends of each limiting strip 7 are respectively provided with an L-shaped rod, the L-shaped rods are fixedly connected with the top surface of the first housing 20, the horizontal rods at the middle parts of the limiting strips 7 at the two sides are respectively contacted with the two opposite sides of the water collection tank 14, so that the shaking of the water collection tank 14 caused by a water pump in the use process is reduced, the stability of the water collection tank is improved, the buzzer 4 is a KEN001 buzzer, the water level sensor 5 is a DJ17-GDSL552 water level sensor, the suction fan 3 is, suction fan 3 fixed mounting is on ice storage box 10 top, and the air outlet of suction fan 3 is located ice storage box 10, 3 one side of suction fan is equipped with motor 2, and motor 2 passes through motor shaft and 3 middle part rigid couplings of suction fan, 2 rigid couplings of motor are in one side of fixed plate 18, and fixed plate 18 rigid coupling in ice storage box 10 top, have further accelerated the speed of melting of the inside ice residue of

ice storage box

10, 20 top surface inner wall rigid couplings of first casing have level sensor 5, the rigid coupling has singlechip 17 in the second casing 19, and level sensor 5's information output end links to each other with singlechip 17's input electrical property, and singlechip 17 output is connected with bee calling organ 4.

The single chip microcomputer 17 is electrically connected with the water level sensor 5 and the buzzer 4 respectively, the single chip microcomputer 17 sets a water level threshold value in the first machine shell 20, the water level sensor 5 transmits water level information in the first machine shell 20 to the single chip microcomputer in real time, when the water level is lower than the set threshold value, the single chip microcomputer 17 controls the buzzer 4 to sound to give an alarm, a user can know the water level information in the first machine shell 20 in time, the water level is sensed, and the safety of the ground source heat pump air conditioner in the using process is improved.

During operation, water in the water collecting tank is extracted through the water pump, the water flows into the second machine shell from the water outlet pipeline, the telescopic rod on the hydraulic cylinder drives the scraping piece repeatedly to push ice slag accumulated at the bottom of the second machine shell into the ice storage chamber, the electric heating wire is used for melting the ice slag, then the water melted in the ice storage box is extracted through the second water pump and the water replenishing pipeline and enters the water collecting tank, and therefore the effect of energy conservation of deicing cyclic utilization is achieved, and the water loss of the cooling tower is reduced.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims

1. The utility model provides a civilian ground source heat pump air conditioner is from study formula and is changeed frequency energy-saving control system altogether, includes base (15), first casing (20) and second casing (19), its characterized in that: the base (15) is in a horizontal plate shape, the first shell (20) and the second shell (19) are both in a rectangular box shape, the first shell (20) and the second shell (19) are respectively arranged at the front end and the rear end of the top surface of the base (15), an ice storage box (10) is communicated and arranged on one side of the first shell (20), a water collecting tank (14) is fixed in the middle of the top surface of the outer part of the first shell (20), and a water inlet (21) and a water outlet (22) are respectively arranged at the top end of the water collecting tank (14);

the water inlet (21) is externally connected with a water supplementing pipeline (1), the other port of the water supplementing pipeline (1) is connected with a second water pump (24), and the water inlet of the second water pump (24) is communicated with the ice storage box (10) through a pipeline;

the water outlet (22) is connected with a first water pump (13) through an external pipeline, and a water outlet of the first water pump (13) is connected with the top end of the first shell (20) through a pipeline;

a strip-shaped plate-shaped scraping blade (8) is longitudinally arranged on the inner bottom surface of the first shell (20), a hydraulic cylinder (16) is arranged on the base (15) on the other side of the first shell (20), and a telescopic rod (6) of the hydraulic cylinder (16) extends into the first shell (20) and is fixedly connected with the scraping blade (8);

an installation groove is limited in the base (15) below the ice storage box (10), heating wires (12) are distributed in the installation groove, and external leads of the heating wires (12) extend out of the installation groove and are connected with a power supply.

2. The self-learning type co-frequency-conversion energy-saving control system of the civil ground source heat pump air conditioner as claimed in claim 1, wherein: the front side and the rear side of the water collecting tank (14) are respectively provided with a limiting strip (7), the middle part of each limiting strip (7) is a horizontal rod, two ends of each limiting strip (7) are respectively provided with an L-shaped rod, and the L-shaped rods are fixedly connected with the top surface of the first shell (20); the horizontal rods in the middle of the limiting strips (7) at the two sides are respectively contacted with the two opposite sides of the water collecting tank (14).

3. The self-learning type co-frequency-conversion energy-saving control system of the civil ground source heat pump air conditioner as claimed in claim 1, wherein: the bottom of the first shell (20) is an inclined plane with a high end and a low end, and the high end of the inclined plane is close to the hydraulic cylinder (16).

4. The self-learning type co-frequency-conversion energy-saving control system of the civil ground source heat pump air conditioner as claimed in claim 1, wherein: exhaust holes are formed in the left side of the base (15) and are communicated with the mounting groove, the exhaust holes are connected with the suction fan (3) through an exhaust pipeline (9), the suction fan (3) is fixedly mounted on the top end of the ice storage box (10), and an air outlet of the suction fan (3) is located in the ice storage box (10).

5. The self-learning type co-frequency-conversion energy-saving control system of the civil ground source heat pump air conditioner as claimed in claim 4, wherein: suction fan (3) one side is equipped with motor (2), and motor (2) pass through motor shaft and suction fan (3) middle part rigid coupling, motor (2) rigid coupling is in one side of fixed plate (18), and fixed plate (18) rigid coupling in ice-storage box (10) top.

6. The self-learning type co-frequency-conversion energy-saving control system of the civil ground source heat pump air conditioner as claimed in claim 1, wherein: the water level sensor is fixedly connected to the inner wall of the top face of the first casing (20), the single chip microcomputer (17) is fixedly connected to the inner wall of the second casing (19), the information output end of the water level sensor (5) is electrically connected with the output end of the single chip microcomputer (17), and the output end of the single chip microcomputer (17) is connected with the buzzer (4).