CN214333101U - Super heat pump heat transfer device of quasi-tertiary compression - Google Patents

Abstract

The invention discloses a quasi-tertiary compression super heat pump heat exchange device and a cold and heat source temperature difference heat exchange method, belonging to the technical field of energy utilization. The quasi-tertiary compression super heat pump heat exchange device is a heat pump heat exchange device for realizing large temperature difference between a low-temperature cold source and a high-temperature heat source, and consists of a heat exchanger A, a steam compressor, a heat exchanger B, a tuner, a controller, a motor, a valve A, a valve B, a valve C, a phase-change heat exchange tube, blades, a circulating working medium, a cold source inlet and outlet and a heat source inlet and outlet; wherein, the heat exchanger A, the vapor compressor, the heat exchanger B, the valve B and the distributor 4 are connected in series to form a loop; the distributor is connected with the vapor compressor through the valve A respectively. The invention automatically adjusts the vapor compression process according to the cold source temperature, thereby realizing the active adjustment of the cycle process under the large-range strong load variable working condition to improve the operating efficiency of the heat pump. The high-efficiency heat exchange under the operating condition that the temperature difference between the low-temperature cold source and the high-temperature heat source is higher than 100 ℃ can be realized.

Description

Super heat pump heat transfer device of quasi-tertiary compression

Technical Field

The utility model belongs to the technical field of the energy utilization, in particular to super heat pump heat transfer device of quasi-tertiary compression. In particular to a heat pump device which extracts heat in a cold source to heat the heat source and automatically adjusts the operation mode according to the temperature of the cold source.

Background

In the field of energy utilization, a large number of heat exchange processes exist in various industrial and civil processes. According to Newton's second law, heat can be spontaneously transferred from a high-temperature object to a low-temperature object, and the heat exchange working condition can be realized only by using a common heat exchanger; if heat needs to be transferred from a low temperature object to a high temperature object, a certain amount of high grade energy, such as electricity, high temperature steam or hot water, needs to be consumed. In the prior art, the heat pump technology is accepted and applied in the market by the characteristics of high efficiency and reliability. The heat pump technology is divided into absorption heat pumps or compression heat pumps according to the principle. The absorption heat pump is divided into a first type absorption heat pump and a second type absorption heat pump. The first type of absorption heat pump needs to consume high-grade energy, transfers a large amount of heat from a low-temperature object to a high-temperature object, generates heat with a temperature lower than the temperature of a driving heat source, is called a heat increasing type heat pump, extracts a small amount of heat from the low-temperature object, generates heat with a temperature higher than the temperature of the driving heat source, and is called a heating type heat pump; the compression heat pump consumes mechanical work, and realizes heat transfer from a low-temperature object to a high-temperature object through an inverse Carnot cycle. The absorption heat pump is limited by thermal cycle and physical properties of working medium, while the compression heat pump is limited by thermal cycle and physical properties of working medium, and can only work in respective temperature range, and cannot realize large-scale temperature increase. Meanwhile, the low-temperature cold source is often accompanied with temperature change in the production process, and the heat pump device is designed according to a rated working condition, so that the performance of the heat pump device is greatly attenuated when the operation working condition deviates from the design working condition, for example, in the air source heat pump technology, air at minus 5 ℃ is taken as the design working condition, and if the actual operation working condition is minus 15 to 10 ℃, the operation efficiency is obviously reduced.

In order to solve the application problem, a quasi-tertiary compression super heat pump device is provided, and a novel compressor and an operation regulation and control method are adopted to maintain the higher efficiency of a heat pump under a large-range variable working condition.

Disclosure of Invention

The utility model aims at providing a super heat pump heat transfer device of quasi-tertiary compression to the deficiency of prior art, its characterized in that, super heat pump heat transfer device of quasi-tertiary compression is a heat pump heat transfer device who realizes the big difference in temperature of low temperature cold source and high temperature heat source, and this heat pump heat transfer device comprises A heat exchanger 1, vapor compressor 2, B heat exchanger 3, tuner 4, controller 5, motor 6, A valve 7, B valve 8, C valve 9, phase change heat transfer pipe 10, A blade 11, B blade 12, cycle fluid, cold source entry 13, cold source export 14, heat source export 15 and heat source entry 16; wherein, the heat exchanger A1, the vapor compressor 2, the heat exchanger B3, the valve B8 and the distributor 4 are connected in series to form a loop; the distributor 4 is respectively connected with the vapor compressor 2 through an A valve 7 and connected on a communicating pipeline of the A heat exchanger 1 and the vapor compressor 2 through a C valve 9; the controller 5 is respectively connected with the valve A7, the valve B8 and the cold source inlet 13 of the heat exchanger A1 through communicating pipes; the heat exchanger A1 is also connected with a cold source outlet 14; the heat exchanger B3 is respectively provided with a heat source outlet 15 and a heat source inlet 16; the vapor compressor 2 is divided into a low pressure chamber 2a, a mixing chamber 2b and a high pressure chamber 2 c; wherein, a rotating shaft is fixed horizontally in the middle of the three cavities, on the rotating shaft, the blade B12 is arranged in the low-pressure cavity 2a, and the blade A11 is arranged in the high-pressure cavity 2 c; the motor 6 is fixed outside the low-pressure cavity 2a and connected with the rotating shaft to drive the blade B and the blade A to rotate.

Phase change heat exchange tubes 10 are arranged in the heat exchanger A1 and the heat exchanger B3.

The driving mode of the motor is electric driving or steam driving; the circulating working medium is water.

The vanes are of piston, scroll, screw or centrifugal type.

The cold source inlet and the cold source outlet of the heat pump are both air, the hot water inlet is hot water, and the steam outlet is steam.

The circulating working medium returns to the heat exchanger A1 after sequentially passing through the heat exchanger A1, the steam compressor 2, the heat exchanger B3, the valve B8 and the distributor 4; the C valve 9 and the A valve 7 are controlled by opening or closing states to realize a gas compression process that a circulating working medium enters or leaves the interior of the steam compressor 2, the circulating working medium steam from the outlet of the A heat exchanger 1 is mixed with the working medium steam passing through the C valve 9 and then sequentially passes through the low-pressure cavity 2a, the mixing cavity 2b and the high-pressure cavity 2C of the steam compressor 2, the working medium steam is mixed with the working medium passing through the A valve 7 in the mixing cavity 2b or part of the working medium leaves through the A valve 7, and the controller 5 detects the temperature and flow control of the cold source inlet 13 and the opening or closing states of the A valve 7 and the C valve 9.

The beneficial effects of the utility model are that simple structure. The cost is low; can be according to cold source temperature automatically regulated vapor compression process, and then realize initiatively adjusting cycle process under the heavy load variable working condition on a large scale in order to promote heat pump operating efficiency. The high-efficiency heat exchange under the operating condition that the temperature difference between the low-temperature cold source and the high-temperature heat source is higher than 100 ℃ can be realized.

Drawings

FIG. 1 is a diagram of a quasi-tertiary compression super heat pump apparatus system.

Detailed Description

The utility model provides a super heat pump heat transfer device of quasi-tertiary compression. The working state of the cold source is automatically controlled to be different according to the temperature and the flow of the cold source, the running load of the cold source is different according to the temperature and the flow of the cold source, and the load is divided into a plurality of running working conditions of minimum load, secondary small load, smaller load, larger load, secondary large load and maximum load from small to large; the technical solution of the present invention will be described in more detail below with reference to the embodiments and the accompanying drawings. In fig. 1, the cold source inlet and outlet of the heat pump are both air, the heat source inlet is hot water, the heat source outlet is steam, and the circulating working medium is water.

FIG. 1 is a diagram of a quasi-three stage compression super heat pump apparatus. The quasi-tertiary compression super heat pump heat exchange device shown in the figure is a heat pump heat exchange device for realizing large temperature difference between a low-temperature cold source and a high-temperature heat source, and the heat pump heat exchange device is composed of a heat exchanger A1, a steam compressor 2, a heat exchanger B3, a tuner 4, a controller 5, a motor 6, a valve A7, a valve B8, a valve C9, a phase-change heat exchange tube 10, a blade A11, a blade B12, a circulating working medium, a cold source inlet 13, a cold source outlet 14, a heat source outlet 15 and a heat source inlet 16; wherein, the heat exchanger A1, the vapor compressor 2, the heat exchanger B3, the valve B8 and the distributor 4 are connected in series to form a loop, and the heat exchanger A1 and the heat exchanger B3 are internally provided with a phase change heat exchange tube 10. The distributor 4 is respectively connected with the vapor compressor 2 through an A valve 7 and connected on a communicating pipeline of the A heat exchanger 1 and the vapor compressor 2 through a C valve 9; the controller 5 is respectively connected with the valve A7, the valve B8 and the cold source inlet 13 of the heat exchanger A1 through communicating pipes; the heat exchanger A1 is also connected with a cold source outlet 14; the heat exchanger B3 is respectively provided with a heat source outlet 15 and a heat source inlet 16; the vapor compressor 2 is divided into a low pressure chamber 2a, a mixing chamber 2b and a high pressure chamber 2 c; wherein, a rotating shaft is fixed horizontally in the middle of the three cavities, on the rotating shaft, the blade B12 is arranged in the low-pressure cavity 2a, and the blade A11 is arranged in the high-pressure cavity 2 c; the motor 6 is fixed outside the low-pressure cavity 2a and connected with the rotating shaft to drive the blade B and the blade A to rotate.

The motor 6 is driven by electric power or steam. The circulating working medium is water.

The vanes are of piston, scroll, screw or centrifugal type.

The cold source inlet and the cold source outlet of the heat pump are both air, the hot water inlet is hot water, and the steam outlet is steam.

The circulating working medium returns to the heat exchanger A1 after sequentially passing through the heat exchanger A1, the steam compressor 2, the heat exchanger B3, the valve B8 and the distributor 4; the C valve 9 and the A valve 7 are controlled by opening or closing states to realize a gas compression process that a circulating working medium enters or leaves the interior of the steam compressor 2, the circulating working medium steam from the outlet of the A heat exchanger 1 is mixed with the working medium steam passing through the C valve 9 and then sequentially passes through the low-pressure cavity 2a, the mixing cavity 2b and the high-pressure cavity 2C of the steam compressor 2, the working medium steam is mixed with the working medium passing through the A valve 7 in the mixing cavity 2b or part of the working medium leaves through the A valve 7, and the controller 5 detects the temperature and flow control of the cold source inlet 13 and the opening or closing states of the A valve 7 and the C valve 9.

The utility model provides a super heat pump heat transfer device's of quasi-tertiary compression cold and hot source difference in temperature heat transfer process, its cold and hot source difference in temperature heat transfer includes following mode: firstly, dividing the load into a minimum load (a design load is 10-40%), a secondary small load (a design load is 40-70%), a small load (a design load is 70-100%), a large load (a design load is 100-130%), a secondary large load (a design load is 130-160%) and a maximum load (a design load is 160-200%), and specifically operating according to the following modes:

(1) maximum load condition

When the flow of the cold source is increased or the temperature is reduced, and the heat exchange amount of the heat exchanger A1 is higher than the maximum load set value, the valve C9 is opened, the valve A7 is opened, the circulating working medium is heated by the cold source in the heat exchanger A1 through the phase change heat exchange pipe 10 to be changed into circulating working medium steam, the circulation working medium steam and the circulation working medium passing through the C valve 9 are mixed and then enter the steam compressor 2, the mixed circulation working medium steam enters the mixing cavity 2b after being compressed by the low pressure cavity 2a, the mixed gas and the circulating working medium which passes through the valve 7A are mixed again and then enter the high-pressure cavity 2c to be compressed again, the circulating working medium steam enters the heat exchanger 3B to heat the heat source medium to be changed into liquid, the liquid circulating working medium passes through the valve 8B and then enters the regulator 4, in the distributor 4, part of the working medium enters into circulation through the valve A7 and the valve C9, and the rest of the working medium enters into the heat exchanger A1 to complete the circulation.

(2) Sub-heavy load condition

When the flow of the cold source is increased or the temperature is reduced, and the heat exchange amount of the heat exchanger A1 is higher than the secondary load and lower than the maximum load set value, the valve C9 is closed, and the valve A7 is opened. The circulating working medium is heated by a cold source through a phase change heat exchange tube 10 in a heat exchanger A1 to become circulating working medium steam, the circulating working medium steam enters a mixing chamber 2B after being compressed by a low-pressure chamber 2a, is mixed with the circulating working medium passing through a valve A7 again and then enters a high-pressure chamber 2c to be compressed again, the circulating working medium steam enters a heat exchanger B3 and then heats a heat source medium to become liquid, the liquid circulating working medium enters a distributor 4 after passing through a valve B8, part of the working medium in the distributor 4 enters circulation through the valve A7, and the rest of the working medium enters the heat exchanger A1 to complete circulation.

(3) Greater load operating mode

When the flow of the cold source is increased or the temperature is reduced, and the heat exchange capacity of the heat exchanger A1 is higher than the design load and lower than the set value of the secondary heavy load, the valve C9 is closed, and the valve A7 is closed; the circulating working medium is heated by a cold source through a phase change heat exchange pipe 10 in a heat exchanger A1 to become circulating working medium steam, the circulating working medium steam is compressed by a low-pressure cavity 2a, then enters a mixing cavity 2B, then enters a high-pressure cavity 2c, and then is compressed again, the circulating working medium steam enters a heat exchanger B3, then heats a heat source medium and becomes liquid, the liquid circulating working medium enters a distributor 4 after passing through a valve B8, and all working media in the distributor 4 enter the heat exchanger A1 to complete circulation.

(4) Less loaded condition

When the flow of the cold source is reduced or the temperature is increased, and the heat exchange quantity of the heat exchanger A is smaller than the design load and larger than a set value of a smaller load, the valve C9 is opened, and the valve A7 is closed; the cycle working medium is heated by a cold source through a phase change heat exchange pipe 10 in a heat exchanger A1 to become cycle working medium steam, the cycle working medium steam is mixed with the cycle working medium passing through a C valve 9 and then enters a steam compressor 2, the mixed cycle working medium steam is compressed by a low-pressure cavity 2a and then enters a mixing cavity 2B, the mixed cycle working medium steam enters a high-pressure cavity 2C and then is compressed again, the cycle working medium steam enters a heat source medium after entering a heat exchanger B3 and then becomes liquid, the liquid cycle working medium enters a tuner 4 after passing through a valve B8, part of the working medium in the tuner 4 enters circulation through the C valve 9, and the rest of the working medium enters the heat exchanger A1 to complete the cycle.

(5) Sub-low load condition

When the flow of a cold source is reduced or the temperature is increased, and the heat exchange amount of the heat exchanger A is smaller than a small load and larger than a secondary small load set value, the C valve 9 is opened, the A valve 7 is opened, a circulating working medium is heated by the cold source in the heat exchanger A1 through the phase change heat exchange tube 10 to be changed into circulating working medium steam, the circulating working medium steam is mixed with the circulating working medium passing through the C valve 9 and then enters the steam compressor 2, the mixed circulating working medium steam is compressed by the low-pressure cavity 2a and then enters the mixing cavity 2B, part of the circulating working medium steam leaves the steam compressor 2 through the A valve 7, the rest of the circulating working medium steam enters the high-pressure cavity 2C and then is compressed again, the circulating working medium steam enters the B heat exchanger 3 and then heats a heat source medium and then is changed into a liquid state, the liquid circulating working medium passes through the B valve 8 and then enters the distributor 4, and part of the circulating working medium from the B heat exchanger 3 in the distributor 4 after being mixed with the circulating working medium from the A valve 7 and then circulates through the C valve 9, and the rest working medium enters the heat exchanger A1 to complete circulation.

(6) Minimum load condition

When the flow of the cold source is reduced or the temperature is increased and the heat exchange quantity of the heat exchanger A is smaller than the second small load set value, the valve C9 is closed and the valve A7 is opened. The cycle working medium is heated by a cold source through a phase change heat exchange pipe 10 in a heat exchanger A1 to become cycle working medium steam, the cycle working medium steam enters a mixing cavity 2B after being compressed by a low-pressure cavity 2a, part of the cycle working medium steam leaves a steam compressor 2 through an A valve 7, the rest cycle working medium steam is compressed again after entering a high-pressure cavity 2c, the cycle working medium steam enters a heat exchanger B3 and then heats a heat source medium to become liquid, the liquid cycle working medium enters a distributor 4 after passing a B valve 8, and the cycle working medium passing the A valve 7 in the distributor 4 is mixed with the cycle working medium from the heat exchanger B3 and then enters the heat exchanger A1 to complete the cycle.

Claims (6)

1. The quasi-tertiary compression super heat pump heat exchange device is characterized by being a heat pump heat exchange device for realizing large temperature difference between a low-temperature cold source and a high-temperature heat source, and comprising an A heat exchanger (1), a steam compressor (2), a B heat exchanger (3), a tuner (4), a controller (5), a motor (6), an A valve (7), a B valve (8), a C valve (9), a phase-change heat exchange tube (10), an A blade (11), a B blade (12), a circulating working medium, a cold source inlet (13), a cold source outlet (14), a heat source outlet (15) and a heat source inlet (16); wherein, the heat exchanger A (1), the vapor compressor (2), the heat exchanger B (3), the valve B (8) and the distributor (4) are connected in series to form a loop; the distributor (4) is respectively connected with the vapor compressor (2) through an A valve (7) and connected to a communication pipeline between the A heat exchanger (1) and the vapor compressor (2) through a C valve (9); the controller (5) is respectively connected with the valve A (7), the valve B (8) and a cold source inlet (13) of the heat exchanger A (1) through communicating pipes; the heat exchanger A (1) is also connected with a cold source outlet (14); the heat exchanger B (3) is respectively provided with a heat source outlet (15) and a heat source inlet (16); the vapor compressor (2) is divided into a low pressure chamber (2a), a mixing chamber (2b) and a high pressure chamber (2 c); wherein, a rotating shaft is horizontally fixed in the middle of the three cavities, on the rotating shaft, the blade B (12) is arranged in the low-pressure cavity (2a), and the blade A (11) is arranged in the high-pressure cavity (2 c); the motor (6) is fixed outside the low-pressure cavity (2a) and is connected with the rotating shaft to drive the blade B (12) and the blade A (11) to rotate.

2. The heat exchange device of the quasi-tertiary compression super heat pump according to claim 1, characterized in that phase change heat exchange tubes (10) are installed in the A heat exchanger (1) and the B heat exchanger (3).

3. The heat exchanger of the quasi-tertiary compression super heat pump according to claim 1, wherein the motor is driven by electricity or steam; the circulating working medium is water.

4. The quasi-tertiary compression super heat pump heat exchange device of claim 1, wherein the vanes are piston, scroll, screw or centrifugal.

5. The heat exchange device of the quasi-tertiary compression super heat pump of claim 1, wherein the cold source inlet and the outlet of the heat pump are both air, the hot source inlet is hot water, and the hot source outlet is steam.

6. The quasi-tertiary compression super heat pump heat exchange device according to claim 1, wherein the circulating working medium returns to the heat exchanger A (1) after sequentially passing through the heat exchanger A (1), the vapor compressor (2), the heat exchanger B (3), the valve B (8) and the distributor (4); the C valve (9) and the A valve (7) are controlled through the opening or closing state to realize the gas compression process that the circulating working medium enters or leaves the interior of the steam compressor (2), the circulating working medium steam from the outlet of the A heat exchanger (1) is mixed with the working medium steam passing through the C valve (9) and then sequentially passes through the low-pressure cavity (2a), the mixing cavity (2b) and the high-pressure cavity (2C) of the steam compressor (2), the working medium steam is mixed with the working medium passing through the A valve (7) in the mixing cavity (2b) or part of the working medium leaves through the A valve (7), and the controller (5) detects the temperature and flow control of the cold source inlet (13) and the opening or closing state of the A valve (7) and the C valve (9).

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