High-efficiency hydraulic mechanical turbulent flow heat exchange water tank
Technical Field
The utility model relates to a heat exchange water tank technical field, concretely relates to high-efficient hydraulic machinery formula vortex heat exchange water tank.
Background
The internal structure of current vortex heat transfer water tank is simple, and when the heat exchanger was exchanged with the rivers that are located the inner bag, often can only carry out the heat transfer to the water that the inner bag surface is close to heat exchanger department, and the water that is located the inner bag inside can't realize the heat transfer for the heat transfer of the medium water of the flow in the heat transfer water tank is inhomogeneous, leads to finally to save the temperature degree inhomogeneous in the hot-water tank, leads to heat exchange efficiency not high.
SUMMERY OF THE UTILITY MODEL
An object of the utility model is to the not enough among the prior art, and provide a high-efficient hydraulic machinery formula vortex heat exchange water tank that heat exchange efficiency is high.
The purpose of the utility model is realized through the following technical scheme:
the utility model provides a high-efficient hydraulic machinery formula vortex heat transfer water tank, which comprises an outer shell, install the inner bag in the shell inside, the peripheral parcel of inner bag has the heat exchanger, be equipped with the delivery port pipeline on the inner bag, be equipped with first pipeline of refrigerant and refrigerant second pipeline on the heat exchanger, inner bag internally mounted has the impeller of roof and diapire in connecting it, be connected with the water inlet pipeline on the impeller, first pipeline of refrigerant and delivery port pipeline all are located the one end of inner bag, refrigerant second pipeline and water inlet pipeline all are located the other end of inner bag.
And a bearing is arranged on the top wall in the inner container, and a wheel rod of the impeller is connected with the bearing.
The impeller comprises a first impeller and a second impeller, the first impeller is arranged on the bottom wall inside the inner container, one end of the second impeller is clamped with the first impeller, and the other end of the second impeller is connected with the bearing.
Wherein, the peripheral cladding of first impeller has the casing, and the casing is fixed in the inside of inner bag, and first impeller includes first wheel pole, a plurality of first wheel vanes of equipartition on the wheel pole, and the central axis of first wheel pole coincides with the central axis of casing, is equipped with on the outer wall of casing the water inlet pipeline, the water inlet pipeline intercommunication inside the outside and the casing of casing, the second wheel includes second wheel pole, the diapire of the one end rotatable coupling inner bag of first wheel pole, the other end and second wheel pole joint.
Wherein a foaming heat-insulating layer is arranged between the shell and the inner container.
The utility model has the advantages that: the high-efficiency hydraulic mechanical turbulence heat exchange water tank of the utility model has the advantages that water enters the impeller from the water inlet pipeline, and the impeller is driven to rotate by the flowing power of the water, so that the static water in the liner generates disturbance; and because the refrigerant and water have the temperature difference, the heat in the refrigerant is clung to the inner container through heat exchanger, transfers the heat to the water through the wall thickness of the inner container, because the diameter of the inner container is big, the heat is very poor through the natural transfer effect, at this moment, as long as the water flows and will rotate through the impeller, make the stationary water draw together and move, force the water flow to exchange heat disorderly, raise the heat exchange efficiency.
Drawings
The present invention is further explained by using the drawings, but the embodiments in the drawings do not constitute any limitation to the present invention, and for those skilled in the art, other drawings can be obtained according to the following drawings without any inventive work.
Fig. 1 is the utility model discloses a high-efficient hydraulic mechanical type vortex heat transfer water tank's decomposition structure schematic diagram.
Fig. 2 is a schematic view of a connection structure of the first impeller and the housing in fig. 1.
Fig. 1 to 2 include:
the device comprises a shell 1, an inner container 2, a water outlet pipeline 20, a water inlet pipeline 21, a bearing 22, a heat exchanger 3, a first refrigerant pipeline 30, a second refrigerant pipeline 31, an impeller 4, a first impeller 40, a second impeller 41, a shell 42, a first wheel rod 43, a first wheel blade 44, a second wheel rod 45 and a foaming heat-insulating layer 5.
Detailed Description
The invention will be further described with reference to the following examples.
The utility model discloses a high-efficient hydraulic machinery formula vortex heat exchange water tank's embodiment, as shown in fig. 1-fig. 2, including shell 1, install at 1 inside inner bag 2 of shell, the peripheral parcel of inner bag 2 has heat exchanger 3, be equipped with delivery port pipeline 20 on the inner bag 2, be equipped with refrigerant first pipeline 30 and refrigerant second pipeline 31 on the heat exchanger 3, 2 internally mounted of inner bag have connect its interior roof and diapire impeller 4, be connected with water inlet pipeline 21 on impeller 4, refrigerant first pipeline 30 and delivery port pipeline 20 all are located the one end of inner bag 2, refrigerant second pipeline 31 and water inlet pipeline 21 all are located inner bag 2's the other end, then the refrigerant working process: high-temperature and high-pressure refrigerant enters from a first refrigerant pipeline 30, flows through a heat exchanger to transfer heat (condense), and then exits from a second refrigerant pipeline 31 (hot water); or the working process of the refrigerant is as follows: the low-temperature and low-pressure refrigerant enters the second line 31, passes through the heat exchanger to transfer heat (evaporate), and then exits the first line 30 (cold water).
A bearing 22 is arranged on the top wall in the inner container 2, and a wheel rod of the impeller 4 is connected with the bearing 22; the impeller 4 comprises a first impeller 40 and a second impeller 41, the first impeller 40 is arranged on the bottom wall inside the inner container 2, one end of the second impeller 41 is clamped with the first impeller 40, and the other end of the second impeller 41 is connected with the bearing 22; the periphery of the first impeller 40 is coated with a shell 42, the shell 42 is fixed in the inner container 2, the first impeller 40 comprises a first wheel rod 43 and a plurality of first wheel blades 44 which are evenly distributed on the wheel rod, the central axis of the first wheel rod 43 is coincident with the central axis of the shell 42, the outer wall of the shell 42 is provided with the water inlet pipeline 21, the water inlet pipeline 21 is communicated with the outside of the shell 42 and the inside of the shell 42, the second impeller 41 comprises a second wheel rod 45, one end of the first wheel rod 43 is rotatably connected with the bottom wall of the inner container 2, the other end of the first wheel rod 43 is clamped with the second wheel rod 45, and the water channel of the embodiment realizes the disturbance process: water enters the first impeller 40 from the water inlet pipeline 21, flows out of the inner container through a gap between the shell 42 and the second impeller 41, and simultaneously drives the first impeller 40 to rotate through the flowing power of the water, and the first wheel rod 43 of the first impeller 40 is clamped with the second wheel rod 45 of the second impeller 41, so that the second impeller 41 is driven to rotate, and the static water in the inner container 2 is disturbed; and because the refrigerant and water have the temperature difference, the heat in the refrigerant is clung to the inner container 2 through heat exchanger, transmit the heat to the water through the wall thickness of the inner container 2, because the diameter of the inner container 2 is large, the heat is very poor through the natural transmission effect, at this moment, as long as the water flows and will rotate through the impeller 4, make the static water draw together and move, force the water flow to disorder the heat exchange, raise the heat exchange efficiency, the heat exchange is even, and the structure is applied simply, the manufacturing cost is low, the manufacturing process is simple.
And a foaming heat-insulating layer 5 is arranged between the shell 1 and the inner container 2.
It should be finally noted that the above embodiments are only intended to illustrate the technical solutions of the present invention, and not to limit the scope of the present invention, and although the present invention has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that the technical solutions of the present invention can be modified or replaced with equivalents without departing from the spirit and scope of the technical solutions of the present invention.