RU2756611C1 - Block with multiple connections, final distribution system and method to control it, and distributor - Google Patents

Abstract

FIELD: instrumentation.SUBSTANCE: block with multiple connections, the final distribution system (100) and the method for controlling it and the distributor (110) are disclosed. The distributor (110) is made with the possibility of uniform distribution of the fluid and contains: a hollow housing (111) having an inlet pipe (112) and a set of exhaust pipes (113), respectively communicating with the inlet pipe (112); and the rotor (114), provided with the possibility of rotation inside the housing (111), and the rotor (114) has a distribution cavity (1141), a distribution inlet (1142) and a set of distribution outlets (1143), while the distribution inlet (1142) communicates with a set of distribution outlets (1143) through the distribution cavity (1141), the intake pipe (112) communicates with the distribution inlet (1142), the exhaust pipes (113) communicate with the distribution outlets (1143). The rotor (114) can rotate during the distribution of the fluid so that the fluid can flow evenly into each exhaust pipe (113) under the action of centrifugal force, to ensure the same amount of fluid released by each exhaust pipe (113), to achieve a uniform distribution of the fluid and then guarantee a uniform distribution of the fluid in the final distribution system (100), thereby improving the convenience of the final distribution system (100) when used and guaranteeing the reliability of the unit with multiple connections.EFFECT: expansion of the range of instruments.13 cl, 5 dwg

Description

CROSS-REFERENCES TO A RELATED APPLICATION

[001] This patent application claims the priority of Chinese Patent Application No. 201811092658.4, filed September 19, 2018, entitled "Multi-Connected Unit, Terminal Distribution System and Method for Controlling Same, and Distributor", the contents of which are incorporated herein in full. document by reference in its entirety.

FIELD OF TECHNOLOGY

[002] The present invention relates to the field of air conditioning equipment, and in particular to a multi-connection unit, an end distribution system and method for controlling it, and a distributor.

BACKGROUND OF THE INVENTION

[003] For a coupled multi-connection unit, that is, a multi-connection cold or hot water unit, the main unit usually produces chilled water or hot water first, and then the chilled water or hot water is piped to the final air conditioner. so that the user can adjust the air supply. Compared to a multi-connection unit of a fluorinated system, a multi-connection cold or hot water end unit exchanges heat with water and mainly consists of an outdoor unit with multiple indoor units or multiple outdoor units with multiple indoor units. However, when the final plumbing system of a multi-connection unit supplies water to multiple indoor units, the distribution of the water flow rate is uneven, which affects the comfortable operation of the indoor units.

BRIEF DESCRIPTION OF THE INVENTION

[004] In this regard, the present invention provides a multi-connection unit, a final distribution system and a control method for it, and a distributor capable of evenly distributing water flow to solve the current problem of uneven water flow distribution and thus improve the usability of the final distribution system. and to ensure the reliability of a multi-connection unit.

[005] The above object is achieved by the following technical solution.

[006] A distributor configured to evenly distribute a fluid comprises:

[007] a hollow body having an inlet pipe and a plurality of outlet pipes, respectively, communicating with the inlet pipe; and

[008] a rotor rotatable within a housing, the rotor having a distribution cavity, a distribution inlet, and a plurality of distribution outlets, the distribution inlet communicating with the plurality of distribution outlets through the distribution cavity, the intake pipe communicating with the distribution inlet, and the outlet pipes communicate with the distribution outlets.

[009] The final distribution system includes a plurality of final pipelines, an final heat exchanger provided in each of the final pipelines, and a distributor according to any of the aforementioned embodiments;

[0010] a plurality of end conduits are respectively connected to a plurality of distributor outlet pipes.

[0011] A method for controlling a target distribution system applied to a target distribution system according to any of the aforementioned embodiments includes:

[0012] driving the distributor rotor for a predetermined duration at an initial speed;

[0013] registering the temperature of the final environment in real time and calculating the final load of the final distribution system in accordance with the temperature of the final environment; and / or registering the actual flow rate in real time and calculating the difference in flow rates in the inlet pipe in accordance with the actual flow rate;

[0014] adjusting the rotor speed for each predetermined duration in accordance with the final load and / or the difference in flow rates in the current state.

[0015] The multi-connection unit comprises a main system and an end distribution system according to any of the aforementioned embodiments;

[0016] the main system includes a compressor, a four-way valve, a first heat exchanger, a throttle device, a second heat exchanger, and a water pump; the compressor is connected to a four-way valve; the four-way valve, the first heat exchanger, the throttling device and the second heat exchanger are cyclically connected; the second heat exchanger is further connected to the inlet of the distributor and the end pipes of the final distribution system, the water pump being located between the end pipes and the second heat exchanger.

[0017] After adopting the above technical solution, the present disclosure has at least the following technical effects.

[0018] Using a multi-connection unit, the final distribution system and its control method, and the distributor according to the present invention, when the distributor dispenses fluid, the fluid enters the housing through the inlet pipe and enters the rotor through the distribution inlet; after being distributed through the distribution cavity of the rotor, fluid flows out of the rotor through the distribution outlet and out of the distributor through the outlet pipe. The rotor can rotate during the fluid distribution process so that the fluid can evenly enter each outlet pipe by centrifugal force, which effectively solves the current problem of uneven water flow distribution, ensures the same amount of fluid discharged by each outlet pipe, realizes uniform distribution fluid, and then provides uniform fluid distribution of the final distribution system, improves the usability of the final distribution system, and ensures the reliability of the multi-connection unit.

BRIEF DESCRIPTION OF THE GRAPHIC MATERIALS

[0019] In order to more clearly describe the technical solutions in the embodiments of the present application or the prior art, below will be briefly presented accompanying graphics that should be used in describing the embodiments or the prior art. Obviously, the drawings in the following description are merely embodiments of the present application, and those skilled in the art can obtain other drawings based on the disclosed drawings without getting creative.

[0020] FIG. 1 is a schematic cross-sectional view of a distributor according to an embodiment of the present invention.

[0021] FIG. 2 is an external view of the distributor shown in FIG. 1.

[0022] FIG. 3 is a side view of the distributor shown in FIG. 1.

[0023] FIG. 4 is a schematic view of the distributor shown in FIG. 1 applied to a multi-connection block.

[0024] FIG. 5 is an illustration of the control time of the rotor in the distributor shown in FIG. 1.

[0025] List of reference positions:

[0026] 100, the ultimate distribution system;

[0027] 110, a distributor;

[0028] 111, housing;

[0029] 112, inlet pipe;

[0030] 113, outlet pipe;

[0031] 114, rotor;

[0032] 1141, a distribution cavity;

[0033] 1142, a distribution inlet;

[0034] 1143, a distribution outlet;

[0035] 115, drive element;

[0036] 120, final pipeline;

[0037] 130, final heat exchanger;

[0038] 140, a temperature recording element;

[0039] 150, a flow rate registration element;

[0040] 200, main system;

[0041] 210, compressor;

[0042] 220, four-way valve;

[0043] 230, the first heat exchanger;

[0044] 240, throttle device;

[0045] 250, second heat exchanger;

[0046] 260, water pump;

[0047] 270, main pipeline;

[0048] 280, heat exchange pipeline.

DETAILED DESCRIPTION

[0049] In order to clarify the purpose, technical solution and advantages of the present disclosure, the multi-connection unit, the final distribution system and its control method, and the distributor according to the present invention will be described in detail below by means of embodiments with reference to the accompanying drawings. It should be understood that the specific embodiments described herein are used only to explain the invention and not to limit the invention.

[0050] Ordinal numbers assigned to parts in this document, such as "first", "second", etc., are used only to distinguish the described objects and do not have any sequence or technical meaning. The terms "connection" and "attachment" in the invention, unless otherwise indicated, include direct and indirect connection (attachment). In the description of the invention, it should be understood that terms denoting orientation or positional relationship, such as "top", "bottom", "front", "back", "left", "right", "vertical", "horizontal", " top "," bottom "," inside "," outside "," clockwise "," counterclockwise ", etc., represent the orientations or positional relationships indicated on the drawings, and are intended only for the convenience of describing the invention and to simplify the description, instead of indicating or implying that the indicated device or element definitely has a specific orientation or is designed and operated in a specific orientation, and therefore such terms cannot be understood as limiting the present invention.

[0051] In the present invention, unless explicitly stated or defined otherwise, the first element is "on" or "below" the second element, which may mean that the first element is in direct contact with the second element or in indirect contact with the second element due to an intermediate agent. Moreover, the fact that the first element is "on" the second element, "above" and "above" it, may mean that the first element is directly above or diagonally above the second element, or simply means that the level of the first element is higher level of the second element. The fact that the first element is “below” the second element, “below” and “below” it, may mean that the first element is directly below or diagonally below the second element, or simply means that the level of the first element is below the level of the second element. ...

[0052] As shown in FIG. 1 and 4, the present invention provides a distributor 110. The distributor 110 is configured to evenly distribute a fluid. The distributor 110 according to the present invention is mainly used in the final distribution system 100 of the multi-connection unit, and it is configured to provide an even distribution of the final flow rate of water. Of course, in other embodiments of the present invention, the distributor 110 can also be used in other cases where a uniform distribution of the fluid is required. Moreover, the distributor 110 can distribute gas or other liquids in addition to water. In the embodiment, the distributor 110 is taken as an example for description only to realize even distribution of the water flow rate.

[0053] As shown in FIG. 1-4, in an embodiment, the distributor 110 comprises a housing 111 and a rotor 114. The housing 111 has a hollow structure and the rotor 114 is rotatable within the housing 111. The housing 111 has an inlet pipe 112 and a plurality of outlet pipes 113, respectively, communicating with the inlet pipe 112. The inlet pipe 112 is adapted to be connected to the heat exchange pipe 280 of the final distribution system 100, and the plurality of outlet pipes 113 are respectively connected to the plurality of final pipes 120 of the final distribution system 100. Water in the heat exchange pipe 280 enters the distributor 110 from the inlet pipe 112 of the housing 111, passes through the interior cavity of the housing 111, and then enters the respective end pipes 120 from the outlet pipes 113 of the housing 111 and outflows from the distributor 110.

[0054] Optionally, inlet pipe 112, outlet pipes 113, and body 111 are integrally formed to avoid water flow leakage and to ensure reliable operation of distributor 110. Of course, inlet pipe 112, outlet pipes 113, and body 111 may also be provided in a detachable form if the tightness of the hinges can be guaranteed. Optionally, the housing 111 has a cylindrical structure. Optionally, the opening of each outlet pipe 113 is the same, which may further provide the same flow rate of water discharged from each outlet pipe 113.

[0055] When the flow rate of the water supplied to the inlet pipe 112 is less or excessive, the distribution of the water flow rate of each inlet pipe 112 may be uneven. Therefore, the distributor 110 according to the present invention is provided with a rotating rotor 114 in the inner cavity of the housing 111 and ensures the same flow rate of water entering each outlet pipe 113 due to the centrifugal force, when the rotor 114 rotates, a uniform distribution of the water flow rate is accordingly achieved. For example, the rotor 114 has a distribution cavity 1141, a distribution inlet 1142, and a plurality of distribution outlets 1143. The distribution cavity 1141 communicates with a distribution inlet 1142 and a plurality of distribution outlets 1143, an inlet pipe 112 communicates with a distribution inlet 1142, and an outlet pipe 113 communicates with the distribution outlet 1143. Optionally, the rotor 114 is a rotatable cylinder that can smoothly rotate the rotor 114 within the housing 111 and prevent interference.

[0056] Water coming from the inlet pipe 112 enters the distribution cavity 1141 of the rotor 114 through the distribution inlet 1142 of the rotor 114; and the water in the distribution cavity 1141 can evenly flow out of the inlet pipe by the centrifugal force and enters the outlet pipes 113 of the housing 111 to flow out. Moreover, the distribution inlet 1142 is disposed adjacent to the inlet pipe 112, which can reduce the water ingress path. Preferably, the distribution inlet 1142 corresponds to the inlet 112, and the inlet 112 may extend into the distribution inlet 1142 so that the water in the heat exchange pipe 280 directly enters the distribution cavity 1141 through the inlet 112 to avoid water leakage. The distribution outlet 1143 is disposed adjacent to the outlet pipe 113 so that the water discharge path can be shortened and the uniform flow of water of each outlet pipe 113 can be ensured.

[0057] When the distributor 110 according to the present invention dispenses fluid, the fluid enters the housing 111 through the inlet pipe 112 and enters the rotor 114 through the distributor inlet 1142. After distribution through the distributor cavity 1141 of the rotor 114, the fluid flows out of the rotor 114 through the distribution outlet 1143 and outflows from the distributor 110 through the outlet pipe 113. The rotor 114 can rotate during the distribution of the fluid so that the fluid can evenly enter each outlet pipe 113 by centrifugal force, which effectively solves the current problem of uneven distribution of water flow and ensures the same amount of fluid discharged from each outlet pipe 113, whereby a uniform distribution of the fluid can be achieved accordingly, thereby ensuring uniform fluid distribution of the final distribution system 100, improving the convenience of 100% of the switchgear system in use and ensuring the reliability of the multi-connection unit.

[0058] In an embodiment, the inlet pipe 112 and a plurality of outlet pipes 113 are respectively provided on two opposite sides of the body 111. In other words, the inlet pipe 112 and the outlet pipes 113 are disposed on two non-adjacent surfaces of the body 111, and water may come from one end of the body 111 and flow out from the other end. In this way, problems such as a short water flow path and a large pressure loss can be avoided, and the distribution efficiency of the distributor 110 can be improved.

[0059] In an embodiment, a plurality of distribution outlets 1143 are located on the circumferential side of the axis of rotation of the rotor 114. Thus, when the rotor 114 rotates, water in the distribution cavity 1141 of the rotor 114 can flow uniformly to the inner wall of the distribution cavity 1141 under the action of centrifugal force and outflow from the distribution outlet 1143 on the outer circumferential side of the rotor 114, allowing water to flow evenly from the distribution outlet 1143 and out through the outlet pipe 113.

[0060] In an embodiment, a plurality of exhaust pipes 113 on the housing 111 are disposed outside the rotor 114 in the circumferential direction. In other words, a plurality of exhaust pipes 113 are distributed on the outer ring of the rotor 114 as shown in FIG. 1 and 3. Thus, water flowing out of the distribution outlet 1143 on the circumferential side of the rotor 114 can directly flow out through the outlet pipe 113, thereby ensuring sufficient water flow through the outlet pipe 113, reliable operation of the final distribution system 100, and the practicality of a unit with many connections. If the outlet pipe 113 is located inside the rotor 114 in the housing 111, at this time, the rotor 114 can block the flow of water into the outlet pipe 113, which affects the water flow rate in the outlet pipe 113.

[0061] In an embodiment, the valve 110 further comprises a drive element 115 that is provided outside the housing 111 and is connected to the rotor 114. The drive element 115 is a power source for rotating the rotor 114. Optionally, the drive element 115 is an electric motor. Of course, the actuator 115 may also be present in other structures that can implement rotational motion. In an embodiment, the drive element 115 is an induction motor. Rotor 114 is driven by an induction motor.

[0062] It should be understood that the drive element 115 is controlled by the control system of the multi-connection unit. In this way, the number of controllers can be reduced so that a multi-wired unit can centrally manage its components, which is convenient for operation. The control system of the multi-connection unit can control the starting and stopping of the induction motor, thereby controlling the rotation and stopping of the rotor 114. The control system of the multi-connection unit can also adjust the outlet speed of rotation of the induction motor, and then adjust the speed of rotation of the rotor 114 to control the flow rate of water. in the outlet pipe 113.

[0063] Moreover, the flow rate of water in the outlet pipe 113 of the distributor 110 is proportional to the speed r of rotation of the rotor 114 in the distributor 110. In other words, the speed r of rotation of the rotor 114 increases and accordingly the flow rate of water in the outlet pipe 113 also increases. In contrast, the speed r of rotation of the rotor 114 decreases and correspondingly also decreases the flow of water in the outlet pipe 113. Adjusting the speed of rotation of the rotor 114 will be described in detail later.

[0064] In an embodiment, the drive member 115 is disposed on the side of the housing 111 having the outlet pipe 113. Thus, it is convenient for the drive member 115 to be connected to the rotor 114 inside the housing 111, and it is convenient to control the rotation drive of the rotor 114. The pivot axis the drive member 115 coincides with the center line of rotation of the housing 111, which can smoothly rotate the rotor 114 within the housing 111.

[0065] As shown in FIG. 4, an embodiment of the present invention provides an end distribution system 100 that includes a plurality of end pipes 120, an end heat exchanger 130 provided in each of the end pipes 120, and a distributor 110 according to the aforementioned embodiment. The plurality of end pipes 120 are connected to a plurality of outlet pipes 113 of the distributor 110. The end distributor system 100 is configured to perform heat exchange at the end point, and the end point here refers to the interior space. The final distribution system 100 performs heat exchange in the interior and can cool or heat the interior to meet the needs of the user. The final distribution system 100 according to the present invention employs a distributor 110 to realize even distribution of the water flow rate in the inner hole so that hot and cold water in the main system of the multi-connection unit can be evenly distributed and the practicality of the final distribution system 100 is guaranteed.

[0066] Specifically, one end of the distributor 110 is connected to the main block system 200 with a plurality of connections through an inlet pipe 112, and the other end of the distributor 110 is respectively connected to a plurality of end pipes 120 through a plurality of outlet pipes 113, and each end pipe 120 is provided at least at least one end heat exchanger 130. The end heat exchanger 130 is located in the interior and the interior is cooled and heated by the end heat exchanger 130. Optionally, the interior heat exchanger can be a wind plate, finned tube heat exchanger, tubular heat exchanger, or other types of end indoor unit. In an embodiment, the distributor 110 is connected to four end pipes 120 and the end heat exchangers 130 are arranged in parallel on the four end pipes 120. Of course, in other embodiments of the present invention, the number of end pipes 120 may be more or less, and the number of end heat exchangers 130 is consistent with the number of end pipes 120.

[0067] In an embodiment, the target distribution system 100 further comprises a plurality of temperature sensing elements 140, respectively provided in the plurality of target pipes 120 and configured to record the temperature of the target environment. In other words, the temperature detection element 140 can record the ambient temperature of the interior space corresponding to the final heat exchanger 130 in real time. In addition, the temperature recording element 140 is electrically connected to the control system of the multi-connection unit for transmitting the target ambient temperature to the control system. The control system stores the preset temperature of the final environment. After comparing the temperature of the final environment with the predetermined temperature, the temperature difference of the final environment, i.e. the final load, can be determined. The control system controls the speed of rotation of the rotor 114 by means of the final load.

[0068] Specifically, the preset temperature of the final environment (ie, the target temperature) is indicated as T _{pre. target} , and the temperature of the final environment (i.e., the actual temperature of the interior space) is the temperature of the temperature recording element 140, which is denoted as T _{room temperature} , and the final load (i.e., the temperature difference in the final environment) is represented as ΔT = T _{room temperature} -T _{pre. given} . A high end load means a large temperature difference between the end ambient temperature and the preset temperature, and more chilled water or hot water is required for heat transfer. Conversely, with a small end load, the required amount of chilled water or hot water is also reduced accordingly.

[0069] As the final load increases, ie, ΔT increases, the water flow required by the final distribution system 100 increases and the speed of the rotor 114 in the distributor 110 must be increased accordingly to ensure sufficient water flow outlets. Therefore, there is a positive correlation between the speed r of rotation of the rotor 114 and ΔT. Thus, the speed r of rotation of the rotor 114 can be adjusted in accordance with the actual demand of the final load ΔT to control the water flow rate in the outlet pipe 113 of the distributor 110.

[0070] In an embodiment, the final distribution system 100 further comprises a flow detection element 150 that is provided on the inlet pipe 112 of the distributor 110 and configured to register the actual fluid flow in the inlet pipe 112. That is, the flow detection element 150 can register the incoming flow of the distributor 110. Since the cross-sectional area of the inlet pipe 112 is constant, the actual flow rate of the water in the inlet pipe 112 can be calculated. In addition, the flow detection element 150 is electrically coupled to the control system of the plurality of connections to transmit the actual flow rate of the water in the inlet pipe 112 to the control system. The control system maintains the nominal water flow rate in the inlet pipe 112 and the nominal water flow rate is determined by the nominal flow rate. By comparing the actual flow rate with the nominal flow rate, the difference in the flow rates of the water in the inlet pipe 112 can be determined. The control system controls the speed of the rotor 114 by the difference in flow rates. In this way, the phenomenon of overvoltage or blocking of the final distribution system 100 can be avoided.

[0071] Specifically, the nominal water flow rate in the inlet pipe 112 of the distributor 110 is denoted as Q _nominal , the actual water flow rate in the inlet pipe 112 is denoted by the flow detection element 150 as Q _actual , and the cross-sectional area of the inlet pipe 112 is denoted as S. Accordingly, the nominal the water flow rate in the inlet pipe 112 satisfies V _nominal = Q _nominal / S, and the actual water flow rate in the inlet pipe 112 satisfies V _actual = Q _actual / S. The flow velocity difference of the inlet pipe 112 satisfies ΔV = V _actual -V _nominal .

[0072] As the water flow rate in the inlet pipe 112 increases, i.e., the ΔV increases, the water flow rate in the outlet pipe 113 also increases correspondingly, which easily causes load fluctuations in the final distribution system 100. At this time, the rotational speed of the rotor 114 in distributor 110 is reduced to stabilize the water flow rate at the outlet. Therefore, there is a positive correlation between the speed r of rotation of the rotor 114 and ΔV. Thus, the speed r of rotation of the rotor 114 can be adjusted in accordance with the requirement of the difference ΔV in the flow rates to ensure reliable operation of the final distribution system 100.

[0073] Optionally, the temperature recording element 140 may be a thermometer ball or sensor. Of course, the temperature sensing element 140 may also be another temperature sensing element capable of realizing temperature sensing. The flow registration element 150 is a flow meter or the like.

[0074] It can be understood that the speed of the rotor 114 can only be controlled by the final load feedback, or the speed of the rotor 114 can only be controlled by the feedback of the difference in flow rates. Of course, the speed of the rotor 114 can also be controlled by the overall final load feedback and the difference in flow rates.

[0075] An embodiment of the present invention further provides a method for controlling a target distribution system, which is applied to the target distribution system 100 in the aforementioned embodiment, and which includes the following steps:

[0076] allowing the rotor 114 of the distributor 110 to operate for a predetermined duration at an initial speed;

[0077] registering the temperature of the target environment in real time and calculating the final load of the target distribution system 100 in accordance with the temperature of the target environment; and / or registering the actual flow rate in real time and calculating the difference in flow rates in the inlet pipe 112 in accordance with the actual flow rate;

[0078] adjusting the speed of rotation of the rotor 114 for each predetermined duration in accordance with the final load and / or the difference in flow rates in the current state.

[0079] When the target distribution system 100 is operating, the process may include a start-up phase and a control phase. During the starting phase, the induction motor starts and drives the rotor 114 of the distributor 110 at an initial speed r and runs for a predetermined duration t ₁ . During the control phase, the temperature registration element 140 registers the temperature T _{room temperature of the} final environment, and the control system calculates the final load ΔT of the final distribution system 100 in accordance with the temperature T _{room temperature of the} destination environment, and / or the flow registration element 150 registers the actual flow rate Q _{the actual} water in the inlet pipe 112, the control system calculates the difference ΔV of the flow rates of the final distribution system 100 in accordance with the actual flow rate Q _actual . The speed r of rotation of the rotor 114 is controlled during each predetermined duration. In particular, the speed r of rotation of the rotor 114 is controlled in accordance with the final load and / or the difference in flow rates in the current state. It should be understood that the predetermined duration can be several seconds or even tens of seconds, etc.

[0080] As shown in FIG. 5, when the distributor 110 is in the starting phase, the rotor 114 of the distributor 110 operates for a predetermined duration t ₁ at an initial speed r. In this process, the initial speed r is a constant speed. When the distributor 110 is in the control phase, the rotor 114 adjusts the rotation speed r of the rotor 114 for each predetermined duration in accordance with the actual situation so that the rotation speed r of the rotor 114 fluctuates around the _initial speed r to control the water flow rate in the outlet pipe 113. ...

[0081] In an embodiment, the step of registering the target ambient temperature in real time and calculating the final load of the target distribution system 100 in accordance with the target ambient temperature includes the following steps:

[0082] obtaining the temperature of the final environment related to the environment in which the final heat exchanger 130 is located;

[0083] comparing the final ambient temperature with a predetermined ambient temperature to determine the final load.

[0084] The control system receives the temperature T _{room temperature of the} final environment, the control system stores the preset temperature T pre _{. target} ambient temperature and compares the target ambient temperature with the predetermined ambient temperature, i.e. the final load satisfies ΔT = T _{room temperature} -T _{pre. given} . As the final load increases, ie, ΔT increases, the water flow required by the final distribution system 100 increases and the speed of rotation of the rotor 114 in the distributor 110 must be increased accordingly. Thus, the speed r of rotation of the rotor 114 can be adjusted in accordance with the actual final load demand ΔT for controlling the water flow rate in the outlet pipe 113 of the distributor 110.

[0085] In an embodiment, the step of registering the actual flow rate in real time and calculating the difference in flow rates in the inlet pipe 112 in accordance with the actual flow rate includes the following steps:

[0086] obtaining the actual flow rate in the inlet pipe 112 of the distributor 110;

[0087] determining the actual flow rate of the inlet pipe 112 in accordance with the actual flow rate;

[0088] determining the nominal flow rate of the inlet pipe 112 in accordance with the nominal flow rate in the inlet pipe 112;

[0089] comparing the actual flow rate with the nominal flow rate to determine the difference in flow rates.

[0090] The actual water flow rate in the intake pipe 112 obtained by the control system and registered by the flow registration element 150, designated as _{the actual} Q and the cross-sectional area in the intake tube 112 is designated as S. The control system determines the actual velocity V of _{the actual} flow inlet pipe 112 by means of actual flow, satisfying V _actual = Q _actual / S. The control system stores the nominal flow rate Q _nominal water in the inlet pipe 112 and determines the nominal speed V _nominal water flow by means of the nominal flow rate Q _nominal , satisfying V _nominal = Q _nominal / S. After comparing the actual flow rate with the nominal flow rate, the difference in flow rates ΔV of water in the inlet pipe 112 can be determined to satisfy the ΔV = V _actual -V _nominal , and the control system adjusts the rotor speed 114 through the difference in flow rates. In this way, the phenomenon of overvoltage or blocking of the final distribution system 100 can be avoided.

[0091] In an embodiment, the relationship between the rotational speed of the rotor 114, the final load, and the difference in flow rates satisfies the following equation:

[0092] r = α × ΔT-β × ΔV + r _initial , where α and β denote constants, ΔT denotes the final load, ΔV denotes the difference in flow rates, and r _initial denotes the initial speed of the rotor 114.

[0093] The control system can adjust the rotational speed of the rotor 114 in accordance with the overall feedback of the final load ΔT and the difference in flow rates ΔV. Thus, the water flow rate in the outlet pipe 113 can be adjusted according to the user's requirements and the actual water flow rate to match the actual water flow rate required by the end point; meanwhile, overvoltage or blocking of the final distribution system 100 can be prevented in order to ensure the practicality of the final distribution system 100 and improve the usability for users.

[0094] An embodiment of the present invention further provides a multi-connection unit comprising a main system 200 and an end distribution system 100 according to the aforementioned embodiment. The main system 200 includes a compressor 210, a four-way valve 220, a first heat exchanger 230, a throttle device 240, a second heat exchanger 250, and a water pump 260. Compressor 210 is connected to a four-way valve 220; the four-way valve 220, the first heat exchanger 230, the throttle device 240, and the second heat exchanger 250 are cyclically connected. The second heat exchanger 250 is further connected to the inlet of the distributor 110 and the end conduit 120 of the final distribution system 100; and a water pump 260 is located between the end ducts 120 and the second heat exchanger 250.

[0095] The main system 200 further comprises a main conduit 270 and a heat exchange conduit 280. The main conduit 270 cyclically connects the four-way valve 220, the first heat exchanger 230, the throttle device 240 and the second heat exchanger 250. The heat exchange conduit 280 cyclically connects the final distribution system 100, the water pump 260 and a second heat exchanger 250. Heat is exchanged in the second heat exchanger 250 by fluid in the main conduit 270 and water in the heat exchange conduit 280 so that heated or cooled water enters the final heat exchanger 130 to heat or cool the interior. After using the aforementioned final distribution system 100, the multi-connection unit according to the present invention can improve the usability for the user while ensuring an even distribution of the water flow rate. Optionally, the throttle device 240 is an electronic expansion valve.

[0096] The technical features in the above embodiments can be combined if desired. For the sake of brevity of description, all possible combinations of various technical features in the aforementioned embodiments are not described herein. However, as long as there is no conflict in the combinations of these technical features, everything should be considered the scope of this disclosure.

[0097] The above embodiments are only a few exemplary embodiments of the present invention, and their description is relatively specific and detailed, but should not be construed as limiting the protection scope of the present invention. It should be noted that several changes and improvements can be made by those skilled in the art without departing from the concept of the present invention, all of which fall within the protection scope of the invention. Therefore, the scope of protection of the present invention will be determined by the appended claims.

Claims (29)

1. A distributor made with the possibility of uniform distribution of the fluid, comprising: a hollow body (111) having an inlet pipe (112) and a plurality of outlet pipes (113), respectively, communicating with the inlet pipe (112); and a rotor (114) rotatable inside a housing (111), wherein the rotor (114) has a distribution cavity (1141), a distribution inlet (1142) and a plurality of distribution outlets (1143), wherein a distribution inlet (1142) communicates with the plurality of distribution outlets (1143) through the distribution cavity (1141), the inlet pipe (112) communicates with the distribution inlet (1142), and the outlet pipes (113) communicate with the distribution outlets (1143). 2. A distributor according to claim 1, characterized in that an inlet pipe (112) and a plurality of outlet pipes (113) are respectively provided on two opposite sides of the housing (111). 3. A distributor according to claim 1, characterized in that the positions of the plurality of outlet pipes (113) on the housing (111) are located outside the rotor (114) in the circumferential direction; and / or a plurality of distribution outlets (1143) are located on the circumferential side of the axis of rotation of the rotor (114). 4. Distributor (110) according to any one of paragraphs. 1-3, characterized in that it further comprises a drive element (115), which is provided outside the housing (111) and is connected to the rotor (114). 5. Distributor (110) according to claim 4, characterized in that the drive element (115) is located on the side of the housing (111) having outlet pipes (113); the axis of rotation of the drive element (115) coincides with the center line of rotation of the housing (111). 6. The final distribution system containing a plurality of final pipelines (120), the final heat exchanger (130) provided in each of the final pipelines (120), and a distributor according to any one of claims. 1-5; wherein the plurality of end ducts (120) are respectively connected to the plurality of outlet pipes (113) of the distributor (110). 7. The final distribution system according to claim 6, further comprising a plurality of temperature recording elements (140), which are respectively provided in the plurality of final conduits (120) and configured to record the temperature of the final environment. 8. The final distribution system according to claim 6 or 7, characterized in that it further comprises a flow registration element (150), which is provided on the inlet pipe (112) of the distributor (110) and is configured to register the actual flow rate of the fluid on the inlet pipe ( 112). 9. The method of controlling the final distribution system, applied to the final distribution system according to any one of paragraphs. 6-8, including: ensuring that the rotor (114) of the distributor (110) operates for a predetermined duration at an initial speed; recording the temperature of the final environment in real time and calculating the final load of the final distribution system (100) in accordance with the temperature of the final environment; and / or registering the actual flow rate in real time and calculating the difference in flow rates in the inlet pipe (112) in accordance with the actual flow rate; adjusting the speed of rotation of the rotor (114) for each predetermined duration in accordance with the final load and / or the difference in flow rates in the current state. 10. The method according to claim 9, characterized in that recording the final ambient temperature in real time and calculating the final load of the final distribution system (100) in accordance with the final ambient temperature include: obtaining the temperature of the final environment related to the environment in which the final heat exchanger (130) is located; comparing the final ambient temperature with a predetermined ambient temperature to determine the final load. 11. A method according to claim 9, characterized in that recording the actual flow rate in real time and calculating the difference in flow rates in the inlet pipe (112) in accordance with the actual flow rate include: obtaining the actual flow rate in the inlet pipe (112) of the distributor (110); determining the actual flow rate of the inlet pipe (112) in accordance with the actual flow rate; determining the nominal flow rate of the inlet pipe (112) in accordance with the nominal flow rate in the inlet pipe (112); comparing the actual flow rate with the nominal flow rate to determine the difference in flow rates. 12. A method according to claim 9, characterized in that the relationship between the rotational speed of the rotor (114), the final load and the difference in flow rates satisfies the following equation: r = α × ΔT-β × ΔV + r _initial , where α and β denote constant values, ΔT denotes the final load, ΔV denotes the difference in flow rates, and _initial r denotes the initial rotor speed (114). 13. Block with multiple connections, containing the main system (200) and the final distribution system (100) according to any one of claims. 6-8; the main system (200) comprises a compressor (210), a four-way valve (220), a first heat exchanger (230), a throttle device (240), a second heat exchanger (250) and a water pump (260); the compressor (210) is connected to the four-way valve (220); the four-way valve (220), the first heat exchanger (230), the throttle device (240) and the second heat exchanger (250) are cyclically connected; the second heat exchanger (250) is additionally connected to the inlet of the distributor (110) and the end pipes (120) of the final distribution system (100), and the water pump (260) is located between the end pipes (120) and the second heat exchanger (250).

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