CN211146645U - Air energy system with energy storage chamber - Google Patents

Abstract

The utility model discloses an air can system with energy storage chamber, including air ability changes in temperature unit, still include load, surge chamber, energy storage chamber, circulating water pump, filter, surge chamber, air ability changes in temperature unit, energy storage chamber, load loop through the pipeline and connect. The utility model relates to a rationally, increased the energy storage room, the circulating water temperature reaches the highest temperature that the air can the unit of changes in temperature set for in the system, and the air can the unit of changes in temperature stop heating, and at this moment the indoor circulating water of energy storage is full system's highest temperature, and furthest has prolonged unit dead time.

Description

Air energy system with energy storage chamber

Technical Field

The utility model belongs to the energy-saving equipment field, concretely relates to air can system with energy storage room.

Background

In order to reduce the PM value in the north and reduce the using amount of fire coal, China proposes a coal-to-electricity project, and uses an air energy unit to replace the fire coal for heating.

In the current coal-to-electricity equipment system, the big system and the small system only have one water tank, and the water tank is a buffer water tank. In fact, the buffer tank is not required to be large according to the size of the system, and 200 liters of the buffer tank of a household cooling and heating system is enough. However, people can find that the buffer water tank can achieve 2 tons, even 5 tons in a household coal-to-electricity heating and cooling system, and the reason is as follows: it is also desirable to increase the water capacity for energy storage.

The water tank is large, when the unit reaches the set temperature in the heating process and stops heating, the water tank can contain a large amount of water with higher temperature so as to maintain the prolonged shutdown time and realize the purpose of energy conservation. This certainly has an energy saving effect, but is not a very desirable effect.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model is: overcome prior art's not enough, provide an air can system with energy storage room, the utility model relates to a rationally, increased the energy storage room, the circulating water temperature reaches the highest temperature that air can the cooling and heating unit and set for in the system, and air can the cooling and heating unit stop heating, and at this moment the inside circulating water of energy storage room is full system maximum temperature, and furthest has prolonged the unit dead time.

The utility model provides a technical scheme that the problem that its exists adopted is:

the air energy system with the energy storage chamber comprises an air energy cooling and heating unit, a load, a buffer chamber, the energy storage chamber, a circulating water pump and a filter, wherein the buffer chamber, the air energy cooling and heating unit, the energy storage chamber and the load are connected in sequence through pipelines.

The circulating water pump is arranged between the buffer chamber and the air energy cooling and heating unit, a filter is arranged between the circulating water pump and the buffer chamber, and the circulating water pump pumps water in the buffer chamber into the air energy cooling and heating unit.

The buffer chamber on be equipped with buffer chamber outlet pipe and buffer chamber inlet tube, the buffer chamber outlet pipe is located the buffer chamber lower part, the buffer chamber inlet tube is located the buffer chamber top, the buffer chamber outlet pipe and filter through connection, the buffer chamber inlet tube is connected with the load delivery port.

The air energy cooling and heating unit is characterized in that an energy storage chamber water inlet pipe and an energy storage chamber water outlet pipe are arranged on the energy storage chamber, the energy storage chamber water inlet pipe is located at the lower portion of the energy storage chamber, the energy storage chamber water outlet pipe is located at the upper portion of the energy storage chamber, the energy storage chamber water inlet pipe is connected with the air energy cooling and heating unit, and the energy storage chamber water outlet pipe is connected with the load water.

Preferably, the buffer chamber and the energy storage chamber are located in the same water tank, a partition plate is arranged in the water tank and divides the interior of the water tank into two independent areas, one area is the buffer chamber, and the other area is the energy storage chamber.

Preferably, the capacity of the buffer chamber is smaller than that of the energy storage chamber.

Preferably, the lower terminal surface of buffer room be equipped with drain I, be equipped with the blowoff valve on the drain I, the buffer room up end be equipped with water filling port and discharge valve I.

Preferably, the lower end face of the energy storage chamber is provided with a drain outlet II, the drain outlet II is provided with a drain valve, and the upper end face of the energy storage chamber is provided with an exhaust valve II.

Preferably, the bottom surface of the inner part of the buffer chamber is funnel-shaped, and the drain outlet I is positioned at the lowest position of the bottom surface.

Preferably, the bottom surface of the inner part of the energy storage chamber is funnel-shaped, and the drain outlet II is positioned at the lowest part of the bottom surface.

Preferably, the buffer chamber and the energy storage chamber are internally provided with anode magnesium rods, the anode magnesium rods in the buffer chamber are in contact with the inner wall of the buffer chamber, and the anode magnesium rods in the energy storage chamber are in contact with the inner wall of the energy storage chamber.

Preferably, the buffer chamber and the energy storage chamber are wrapped by insulating layers.

Compared with the prior art, the utility model discloses beneficial effect who has:

the energy storage chamber is added, the temperature of circulating water in the system reaches the highest temperature set by the air energy cooling and heating unit, the air energy cooling and heating unit stops heating, and at the moment, the circulating water in the energy storage chamber is the highest temperature of the whole system, so that the unit stopping time is prolonged to the maximum extent. Because the energy storage chamber reflects the highest temperature of the system, the part of the triple system for supplying hot water can be directly obtained in a heat exchange mode from the energy storage box, so that the stability of the unit can be enhanced, and faults are reduced. Meanwhile, the anode magnesium rods are arranged in the energy storage chamber and the buffer chamber, so that the generation of water scales in the energy storage chamber and the buffer chamber is effectively reduced, and the energy storage chamber and the buffer chamber are prevented from being corroded.

Drawings

The present invention will be further explained with reference to the drawings and examples.

FIG. 1 is a diagram of a split chamber system of an air energy system with an energy storage chamber of the present invention,

FIG. 2 is a diagram of a fit room system of the present invention,

fig. 3 is a structure view of the interior of the fit room of the present invention.

In the figure, 1-an air energy cooling and heating unit, 2-a load, 3-a buffer chamber, 3 a-a buffer chamber water outlet pipe, 3 b-a buffer chamber water inlet pipe, 3 c-a water injection port, 3 d-an exhaust valve I and 3 e-a sewage outlet I are arranged;

4-energy storage chamber, 4 a-energy storage chamber water inlet pipe, 4 b-energy storage chamber water outlet pipe, 4 c-sewage outlet II, 4 d-exhaust valve II, 5-circulating water pump, 6-filter, 7-ball valve, 8-anode magnesium rod and 9-insulating layer.

Detailed Description

The accompanying drawings illustrate a preferred embodiment of the air energy system with an energy storage chamber, and the present invention will be described in further detail with reference to the accompanying drawings.

Example 1:

as shown in fig. 1 and fig. 3, an air energy system with an energy storage chamber comprises an air energy cooling and heating unit 1, and further comprises a load 2, a buffer chamber 3, an energy storage chamber 4, a circulating water pump 5 and a filter 6. The buffer chamber 3, the air energy cooling and heating unit 1, the energy storage chamber 4 and the load 2 are connected in sequence through pipelines.

The circulating water pump 5 is arranged between the buffer chamber 3 and the air energy cooling and heating unit 1, the filter 6 is arranged between the circulating water pump 5 and the buffer chamber 3, and the circulating water pump 5 pumps water in the buffer chamber 3 into the air energy cooling and heating unit 1.

The buffer chamber 3 on be equipped with buffer chamber outlet pipe 3a and buffer chamber inlet tube 3b, buffer chamber outlet pipe 3a is located the 3 lower parts of buffer chamber, buffer chamber inlet tube 3b is located the 3 tops of buffer chamber, buffer chamber outlet pipe 3a and 6 through connections of filter, buffer chamber inlet tube 3b is connected with 2 delivery ports of load. Buffer 3 terminal surface be equipped with drain I3 e down, be equipped with the blowoff valve on the drain I3 e, 3 inside bottom surfaces of buffer be the infundibulate, drain I3 e is located the bottom surface minimum. The upper end surface of the buffer chamber 3 is provided with a water filling port 3c and an exhaust valve I3 d, and the water filling port 3c is provided with a plug to block the valve.

The energy storage chamber 4 is provided with an energy storage chamber water inlet pipe 4a and an energy storage chamber water outlet pipe 4b, the energy storage chamber water inlet pipe 4a is positioned at the lower part of the energy storage chamber 4, the energy storage chamber water outlet pipe 4b is positioned at the upper part of the energy storage chamber 4, the energy storage chamber water inlet pipe 4a is connected with the air energy cooling and heating unit 1, and the energy storage chamber water outlet pipe 4b is connected with a water inlet of the load 2. Establish the energy storage room inlet tube 4a of energy storage room 4 in energy storage room 4 lower part, energy storage room outlet pipe 4b is located energy storage room 4 upper portion, if gaseous in the circulating water that gets into energy storage room 4 inside, gaseous can not bring into the end through the discharge of energy storage room outlet pipe 4b, and the circulating water can move in order like this, has formed energy-conserving effect by a wide margin.

Energy storage chamber 4 under the terminal surface be equipped with drain II 4c, drain II 4c on be equipped with the blowoff valve, the inside bottom surface of energy storage chamber 4 be the infundibulate, drain II 4c is located the bottom surface minimum. And an exhaust valve II 4d is arranged on the upper end surface of the energy storage chamber 4.

The capacity of the buffer chamber 3 is smaller than that of the energy storage chamber 4. And the outside of the buffer chamber 3 and the outside of the energy storage chamber 4 are both wrapped with insulating layers 9.

As shown in fig. 1, the circulating water flows in a direction that the buffer chamber 3 flows into the air energy cooling and heating unit 2, then flows into the energy storage chamber 4, flows into the load 2 from the energy storage chamber 4, and finally returns to the buffer chamber 3 after flowing out of the load 2.

Example 2:

the other contents of this embodiment are the same as embodiment 1, except that: as shown in fig. 2, the buffer chamber 3 and the energy storage chamber 4 are located in the same water tank, a partition board is arranged in the water tank, the partition board divides the interior of the water tank into two independent areas, one area is the buffer chamber 3, and the other area is the energy storage chamber 4. After the buffer chamber 3 and the energy storage chamber 4 are integrated into a water tank, the air energy cooling and heating unit 1 is connected to two ports at the front end of the integrated water tank. Two ports at the rear end of the integrated water tank are connected with a load 2. The connecting pipelines of the air energy cooling and heating unit 1, the water tank and the load 2 are obviously reduced, and the right-angle bends among the pipelines are obviously reduced.

Example 3:

the other contents of this embodiment are the same as those of embodiment 1 or embodiment 2, except that: buffer chamber 3 and energy storage chamber 4 inside all be equipped with positive pole magnesium stick 8, the inside positive pole magnesium stick 8 and the 3 inner walls contact of buffer chamber 3, the inside positive pole magnesium stick 8 and the contact of 4 inner walls of energy storage chamber 4.

Energy-saving effect comparison table

The embodiments of the present invention have been described in detail with reference to the accompanying drawings, but the present invention is not limited to the above embodiments, and various changes can be made without departing from the gist of the present invention within the knowledge of those skilled in the art.

Claims (9)

1. The utility model provides an air can system with energy storage room, includes air can changes in temperature unit (1), its characterized in that:

the air energy cooling and heating unit also comprises a load (2), a buffer chamber (3), an energy storage chamber (4), a circulating water pump (5) and a filter (6), wherein the buffer chamber (3), the air energy cooling and heating unit (1), the energy storage chamber (4) and the load (2) are sequentially connected through a pipeline,

the circulating water pump (5) is arranged between the buffer chamber (3) and the air energy cooling and heating unit (1), a filter (6) is arranged between the circulating water pump (5) and the buffer chamber (3), the circulating water pump (5) pumps water in the buffer chamber (3) into the air energy cooling and heating unit (1),

the buffer chamber (3) is provided with a buffer chamber water outlet pipe (3a) and a buffer chamber water inlet pipe (3b), the buffer chamber water outlet pipe (3a) is positioned at the lower part of the buffer chamber (3), the buffer chamber water inlet pipe (3b) is positioned above the buffer chamber (3), the buffer chamber water outlet pipe (3a) is communicated with the filter (6), the buffer chamber water inlet pipe (3b) is connected with the water outlet of the load (2),

the energy storage chamber (4) is provided with an energy storage chamber water inlet pipe (4a) and an energy storage chamber water outlet pipe (4b), the energy storage chamber water inlet pipe (4a) is located on the lower portion of the energy storage chamber (4), the energy storage chamber water outlet pipe (4b) is located on the upper portion of the energy storage chamber (4), the energy storage chamber water inlet pipe (4a) is connected with the air energy cooling and heating unit (1), and the energy storage chamber water outlet pipe (4b) is connected with a water inlet of a load (2).

2. An air energy system with an energy storage chamber according to claim 1, characterized in that:

buffer chamber (3) and energy storage room (4) be located same water tank inside, the inside baffle that is equipped with of water tank, the baffle is divided into two independent regions with water tank inside, a region is buffer chamber (3), another region is energy storage room (4).

3. An air energy system with an energy storage chamber according to claim 1, characterized in that:

the capacity of the buffer chamber (3) is smaller than that of the energy storage chamber (4).

4. An air energy system with an energy storage chamber according to claim 1, characterized in that:

buffer (3) lower terminal surface be equipped with drain I (3e), be equipped with the blowoff valve on drain I (3e), buffer (3) up end be equipped with water filling port (3c) and discharge valve I (3 d).

5. An air energy system with an energy storage chamber according to claim 1, characterized in that:

energy storage room (4) lower terminal surface be equipped with drain II (4c), drain II (4c) on be equipped with the blowoff valve, energy storage room (4) up end be equipped with discharge valve II (4 d).

6. An air energy system with an energy storage chamber according to claim 4, characterized in that:

the bottom surface of the interior of the buffer chamber (3) is funnel-shaped, and the drain outlet I (3e) is positioned at the lowest position of the bottom surface.

7. An air energy system with an energy storage chamber according to claim 5, characterized in that:

the bottom surface in energy storage room (4) be the infundibulate, drain II (4c) are located the bottom surface minimum.

8. An air energy system with an energy storage chamber according to claim 1, characterized in that:

buffer chamber (3) and energy storage room (4) inside all be equipped with positive pole magnesium stick (8), inside positive pole magnesium stick (8) and the contact of buffer chamber (3) inner wall of buffer chamber (3), inside positive pole magnesium stick (8) and the contact of energy storage room (4) inner wall of energy storage room (4).

9. An air energy system with an energy storage chamber according to claim 1, characterized in that:

the buffer chamber (3) and the energy storage chamber (4) are wrapped with heat insulation layers (9).

Images