JP6106049B2 - Automatic flow control system - Google Patents

Description

  The present invention relates to an automatic flow rate adjustment system that automatically adjusts the flow rate of the heat medium to be circulated through each flow path in a heating system having a plurality of flow paths through which the heat medium flows.

  Conventionally, a central heating system has been adopted as one of the heating systems. This central heating system supplies a heat medium such as water or oil heated by a boiler to a plurality of flow paths connected to a plurality of rooms, and dissipates the heat of the heat medium in each room. Heating.

  Further, in the conventional central heating system, the supply of the heat medium to the flow path may be interrupted when the temperature becomes higher than the temperature set for each room for economic efficiency and energy saving.

  For example, in Japanese Patent Laid-Open No. 2001-304603, when the room temperature is lower than a set value, the valve is automatically opened and hot water is allowed to flow through the radiator, and when the room temperature is higher than the set value, the valve is automatically closed to shut off the hot water. An invention relating to an electric hot water heater provided with a valve has been proposed (Patent Document 1). Moreover, in such an electric water heater, since pressure loss differs for every flow path, it is necessary to adjust so that the heat medium of a required flow volume may flow for each flow path. Up to now, the installer has manually operated the valves provided in the respective flow paths to adjust the required flow rate.

JP 2001-304603 A

  However, in the conventional inventions such as the invention described in Patent Document 1, the flow rate adjustment of each flow path is often set by relying on the sense of the installer, and the flow rate inspection is rarely performed. However, there is a problem that the required flow rate may not flow in the flow path.

  In addition, when one or a plurality of flow paths are blocked for economic efficiency or energy saving, there is a problem that more than necessary heat medium flows into other flow paths. As described above, since the pressure loss differs for each channel, even if the required flow rate is flowing at the time of construction, the pressure balance is lost due to the blockage of the flow channel, and the flow rate more than the required flow rate or the required flow rate The following flow paths are generated.

  In a flow path that flows more than the necessary flow rate, there is a problem that so-called overshoot, which is an excessive temperature rise, occurs, and energy is wasted, and noise caused by running water noise increases.

  In addition, in the flow path that flows below the required flow rate, there is a problem that the room is not warmed up and the room is not used. The variation in room temperature in each room is also a health problem because it causes a so-called heat shock in which the blood pressure rapidly increases or decreases when exposed to a rapid temperature change. Furthermore, since the room which is not warmed is warmed, the boiler is operated for a long time, leading to a decrease in durability.

  The present invention has been made to solve such problems, and an object thereof is to provide an automatic flow rate adjustment system capable of automatically adjusting a heat medium having a predetermined flow rate in each flow path. It is said.

  An automatic flow rate adjustment system according to the present invention is an automatic flow rate adjustment system that automatically adjusts a flow rate of a heat medium when circulating a heat medium through a plurality of flow paths, and circulates the heat medium through the plurality of flow paths. A circulation pump, a supply pipe that is connected to the circulation pump and connected to the inlet of each of the flow paths, distributes and supplies the heat medium to each of the flow paths, and an outlet of each of the flow paths And a reduction pipe that joins the heat medium flowing out from the outlet and reduces it to the circulation pump, and a flow rate of the heat medium in each flow path that is provided for each flow path. A plurality of flow sensors, a plurality of electric valves provided for each of the flow paths to adjust the flow rate of the heat medium in each of the flow paths, and a flow rate measured by the flow sensor are set for each of the flow paths. Specified flow rate And a valve control box said to drive the electric valve to be within range.

  Further, as one aspect of the present invention, a bypass flow sensor that is connected to be circulated between the supply pipe and the reduction pipe, and that measures the flow rate of the heat medium in the middle of the flow path, and a flow rate thereof. The valve control box has a bypass flow path including a bypass electric valve to be adjusted, and the flow rate for each of the flow paths controlled within a set predetermined flow rate range is measured by the bypass flow path. The bypass electric valve may be driven such that a total flow rate obtained by adding the flow rates is equal to or greater than a preset minimum total flow rate.

  Furthermore, as one aspect of the present invention, the valve control box determines that the flow rate measured by the flow rate sensor is outside the range of the flow rate set for each of the flow paths, If the flow rate is not adjusted within a predetermined flow rate range, the flow rate adjustment may be terminated.

  According to the present invention, a heat medium having a predetermined flow rate can be automatically adjusted in each flow path.

It is a mimetic diagram showing one embodiment of an automatic flow control system concerning the present invention. It is a block diagram which shows the flow volume automatic adjustment system of this embodiment. It is sectional drawing which shows the flow sensor in this embodiment. It is an electric valve in this embodiment, and is a sectional view showing (a) the drive part and (b) valve part. It is a flowchart which shows the flow of the various data and electric power in the flow volume automatic control system of this embodiment. It is a flowchart which shows the flow volume adjustment process by the valve control box in this embodiment. It is a flowchart which shows the flow volume adjustment process by the valve control box in other embodiment.

  Hereinafter, an embodiment of an automatic flow rate adjustment system according to the present invention will be described with reference to the drawings. As shown in FIG. 1, the automatic flow control system 1 of the present embodiment is used for a heating system that heats a first room, a second room, and a third room of a building.

  In FIGS. 1 and 2, a solid line with an arrow indicates a pipe connecting the components and the direction in which the heat medium flows in the pipe. Moreover, the broken line has shown the signal line 11 which connects each structure.

  Hereinafter, the automatic flow rate adjustment system 1 of the present embodiment will be described in detail.

  As shown in FIGS. 1 and 2, the automatic flow rate control system system 1 of the present embodiment includes a boiler 2 that heats a heat medium, a circulation pump 3 that circulates the heat medium through a plurality of flow paths 5, For each of the flow paths 5, a supply pipe 4 that distributes and supplies the heat medium to the flow paths 5, a reduction pipe 6 that combines the heat media from the flow paths 5 and returns to the circulation pump 3, and A flow rate sensor 7 provided; an electric valve 8 provided for each flow path 5; a bypass flow path 9 connected to be able to flow between the supply pipe 4 and the reduction pipe 6; And a valve control box 10 for driving the electric valve 8 and the like according to the flow rate of each path 5.

  The boiler 2 is a device that heats the heat medium. In the present embodiment, the boiler 2 is installed in a boiler room as shown in FIG. Moreover, the boiler 2 in this embodiment incorporates the storage tank 21 which stores the said heated heat medium, as shown in FIG. The storage tank 21 has a predetermined volume corresponding to the supply amount of the heat medium, and is connected to the inlet 31 of the circulation pump 3 through a pipe made of metal, resin, or the like so as to be able to circulate.

  The heat source for heating the heat medium is not particularly limited, and can be appropriately selected from electric heat such as a heating wire, combustion heat such as gas or petroleum. Further, the heated heat medium may be supplied to each flow path 5 without being stored in the storage tank 21.

  The heat medium is a liquid that circulates in each flow path 5 and is not particularly limited, and is appropriately selected from water, a synthetic heat medium oil, a mineral oil heat medium oil, and the like.

  Next, the circulation pump 3 will be described. As described above, the circulation pump 3 has the inlet 31 connected to the storage tank 21 of the boiler 2 so as to be able to circulate, and sucks the heated heat medium in the storage tank 21 from the inlet 31 and discharges it to the outlet 32. It is supposed to be. As shown in FIG. 1, the circulation pump 3 in the present embodiment is installed in a boiler chamber.

  The type of the circulation pump 3 is not particularly limited, and is appropriately selected from a rotary pump and a positive displacement pump. Further, in the present embodiment, the boiler 2 and the circulation pump 3 are separated, but a pump built in the boiler 2 may be used as the circulation pump 3.

  As shown in FIG. 2, the supply pipe 4 has an inlet 41 connected to the outlet 32 of the circulation pump 3 by a pipe made of metal or resin, and an inlet 51 of each flow path 5. Yes. That is, the supply pipe 4 is configured to distribute and supply the heat medium discharged from the circulation pump 3 to the respective flow paths 5.

  The flow path 5 is a pipe made of metal or resin. As shown in FIG. 2, the inlet 51 is connected to the supply pipe 4 and the outlet 52 is connected to the reduction pipe 6. In this embodiment, the three flow paths 5 are connected to the reduction pipe 6 from the supply pipe 4 through the radiator 53 provided in each room.

  The radiator 53 radiates the heat of the supplied heat medium to each room and warms each room. The type of the radiator 53 is appropriately selected according to the size of the room and the natural environment. As shown in FIG. 1, the radiator 53 in the present embodiment has a floor heating 53a in the first chamber, a fan con vector 53b in the second chamber, and a radiator 53c in the third chamber. ing.

  In addition, the flow rate or flow rate range of the heat medium to be supplied to the radiator 53 is determined according to the type and necessary heat amount. As will be described later, in the valve control box 10 in the present embodiment, a predetermined flow rate range in each flow path 5 is set based on the flow rate or flow rate range of the heat medium supplied to the radiator 53.

  Further, each radiator 53 includes a sub-control panel 54 as shown in FIGS. The fan convector 53b provided in the second chamber incorporates a sub-control panel 54.

  As shown in FIG. 5, the sub-control panel 54 has a temperature sensor 55, and measures the temperature of each room. The sub-control panel 54 includes an input unit 56 and a display unit 57. The sub-control panel 54 inputs the set temperature of each room, displays the temperature of each room, the flow rate of the heat medium flowing through the radiator 53, and the like. It is supposed to be.

  Further, as shown in FIG. 2, the sub-control panel 54 is connected to the valve control box 10 by the signal line 11, and the temperature data of the room measured by the temperature sensor 55 through the signal line 11 The set temperature data or the like input by the input unit 56 is transmitted to the valve control box 10.

  As shown in FIG. 2, the reducing pipe 6 is connected to the outlet 52 of each flow path 5 so as to be able to flow therethrough. The outlet 61 of the reduction pipe 6 is connected to the boiler 2 through a pipe made of metal or resin so as to be able to circulate. That is, the reducing pipe 6 joins the heat medium distributed to each flow path 5, supplies the joined heat medium to the boiler 2, and reduces it to the circulation pump 3 connected to the boiler 2. It has become.

  The flow rate sensor 7 measures the flow rate of the flow path, and is provided for each flow path 5. In the present embodiment, as shown in FIG. 2, it is provided in the flow path 5 between the radiator 53 and the reduction pipe 6. Further, as shown in FIG. 3, the flow sensor 7 in the present embodiment incorporates a propeller 71 that rotates in the flow path 5 through which the heat medium passes, and the propeller 71 rotates by the hydraulic force of the heat medium. The flow rate is measured by detecting the number as an electrical signal.

  The flow rate sensor 7 is connected to the valve control box 10 by a signal line 11, and the flow rate data of each flow path 5 measured by the flow rate sensor 7 is sent to the valve control box via the signal line 11. 10 is transmitted.

  The flow rate sensor 7 is not particularly limited, and is appropriately selected from, for example, a differential pressure type flow rate sensor, a flow rate sensor using electromagnetic waves, a flow rate sensor using ultrasonic waves, and the like.

  The electric valve 8 is for adjusting the flow rate of the heat medium flowing through each flow path 5, and is provided for each flow path 5. As shown in FIG. 4, the electric valve 8 includes a drive unit 81 and a valve unit 82 as a set. Moreover, the electric valve 8 in this embodiment is provided between the flow sensor 7 and the reduction pipe 6 as shown in FIG.

  As shown in FIG. 4A, the drive unit 81 includes a plurality of gears 83 that open and close the flow path 5 by displacing a valve 85 provided in the valve unit 82, and a stepping motor that rotates the gear 83. 84. As shown in FIG. 2, the stepping motor 84 is connected to the valve control box 10 by a signal line 11, and is driven by receiving low-voltage power from the valve control box 11 through the signal line 11. It is supposed to be.

  As shown in FIG. 4B, the valve portion 82 is provided with a valve 85 that is displaced by the drive portion 81, and is opened and closed by the drive portion 81.

  In addition, although the flow sensor 7 and the electric valve 8 in this embodiment are provided between each heat radiator 53 and the reduction | restoration pipe | tube 6, it is not specifically limited, In any place of each flow path 5 It may be provided.

  The bypass passage 9 is connected between the supply pipe 4 and the reduction pipe 6 so as to be able to flow, and has a bypass flow sensor 93 and a bypass electric valve 94 in the middle of the flow path. As shown in FIG. 2, the bypass channel 9 in the present embodiment has an inlet 91 provided in the vicinity of the inlet 41 of the supply pipe 4 and an outlet 92 provided in the vicinity of the outlet 61 of the reducing pipe 6. It has been. Therefore, the heat medium flowing through the bypass flow path 9 is reduced to the circulation pump 3 without passing through the flow paths 5 and the radiator 53. Further, as will be described later, by providing the bypass flow path 9 separately, the load applied to the circulation pump 3 along with the flow rate control in each flow path 5 is reduced.

  The bypass flow rate sensor 93 measures the flow rate of the heat medium flowing through the bypass flow path 9. The bypass flow sensor 93 in this embodiment is the same as the flow sensor 7 provided in each flow path 5 and is connected to the valve control box 10 by a signal line 11 as shown in FIG. Has been.

  The bypass electric valve 94 adjusts the flow rate of the heat medium flowing through the bypass flow path 5. The bypass electric valve 94 in the present embodiment is the same as the electric valve 8 provided in each flow path 5 and is connected to the valve control box 10 by a signal line 11 as shown in FIG. Has been.

  Some types of boiler 2 have a built-in bypass, but the bypass channel 9 in this embodiment is provided separately from the one built in the boiler 2.

  The valve control box 10 controls the electric valve 8 based on the flow rate of each flow path 5 measured by the flow sensor 7 and adjusts the flow rate of each flow path 5. As shown in FIG. 5, the valve control box 10 in the present embodiment has a signal transmission / reception unit 101 that transmits / receives various data to / from the sub-control panel 54 and a flow rate that receives flow rate data measured by the flow rate sensor 7. Based on a signal receiving unit 102, a timer 103 that measures time, a driving power output unit 104 that outputs driving power to the electric valve 8, a power source unit 105 that manages electric power supplied to each electric valve 8, and various data And a control unit 106 that controls the electric valve 8 and the like. In addition, a main control panel 107 for inputting set values, displaying measured values, and the like is connected to the valve control box 10 in the present embodiment.

  The signal transmission / reception unit 101 is an interface for transmitting / receiving various data, and is connected to each sub-control panel 54 via the signal line 11 so as to be communicable. As shown in FIG. 5, the signal transmission / reception unit 101 receives the temperature data and the set temperature data transmitted from the sub-control panel 54 and transmits them to the control unit 106 and the set temperature transmitted from the control unit 106. Data is received and transmitted to the sub-control panel 54.

  The flow rate signal receiving unit 102 is an interface that receives flow rate data, and is connected to each flow rate sensor 7 and the bypass flow rate sensor 93 through a signal line 11 so as to be communicable. As shown in FIG. 5, the flow rate signal receiving unit 102 receives the flow rate data of each flow channel 5 and bypass flow channel 9 received from the flow rate sensor 7 and the bypass flow rate sensor 93 and transmits the flow rate data to the control unit 106. It is like that.

  The timer 103 measures time. When the measurement start signal is received from the control unit 106, the timer 103 starts measuring time. When the request signal transmitted from the control unit 106 is received, the timer 103 receives the measured time data. 106 is transmitted.

  The driving power output unit 104 is an interface for supplying driving power to each electric valve 8 and the bypass electric valve 94, and is connected to each electric valve 8 and the bypass electric valve 94 through the signal line 11 so as to be energized. .

  In the present embodiment, the power supply to each electric valve 8 and the bypass electric valve 94 uses the signal line 11, but a power supply conductor or the like may be provided separately.

  The power supply unit 105 supplies power to the control unit 106, the drive power output unit 104, and the like, and is connected to an external outlet, although not shown.

  The control unit 106 includes a microcomputer or a CPU (integrated circuit) and a storage device such as a ROM or a RAM, processes various data received from the signal transmission / reception unit 101, the flow rate signal reception unit 102, and the timer 103, and supplies power. The electric power supplied from the unit 105 is supplied to each electric valve 8 and the bypass electric valve 94 via the drive power output unit 104 to control the flow rate of each flow path 5.

  Details of processing of various data by the control unit 106 and control of each electric valve 8 and the like will be described later with reference to flowcharts.

  Next, the main control panel 107 includes an input unit and a display unit, and inputs the set temperature of each room, the temperature of each room, the flow rate of the heat medium flowing through each flow path and the bypass flow path 9, and the like. It is supposed to be displayed. The main control panel 107 in this embodiment has a touch panel 108, and an input unit and a display unit are integrally formed. Further, as shown in FIG. 2, the main control panel 107 is communicably connected to the valve control box 10 through a signal line 11.

  Note that the input method of various settings on the main control panel 107 is not particularly limited, and a separate button or the like may be provided. The communication connection between the main control 107 and the valve control box 10 is not limited to a wired connection, and may be wireless.

  Next, the operation of each component in the automatic flow rate adjustment system 1 of the present embodiment will be described.

  First, using the main control panel 107, the setting of the temperature of each room, the setting of the range of the flow rate of each flow path 5, and the setting of the minimum total flow rate are input. It should be noted that the setting of the temperature of each room can also be performed by the sub-control panel 54 provided on the side of each radiator 53.

  The range of the flow rate of each flow path 5 is determined based on the flow rate or the range of the heat medium supplied according to the type of the radiator 53 and the required amount of heat. In this embodiment, the range of the flow rate of each flow path 5 is set to a range of −0.1 liter to +0.2 liter with respect to a predetermined flow rate required for the radiator 53. In addition, the determination method of the range of the flow volume of each flow path 5 is not specifically limited, It selects suitably.

  The minimum total flow rate is determined based on the rated flow rate discharged by the circulation pump 3. The minimum total flow rate in the present embodiment is 50% of the rated flow rate of the circulation pump 3. The determination of the minimum total flow rate is not particularly limited, and is appropriately selected.

  Next, the flow of the heat medium accompanying the operation of the heating system using the automatic flow rate adjustment system 1 of the present embodiment will be described.

  First, when the operation of the heating system is started, the heat medium is warmed by the boiler 2 and stored in the storage tank 21. When the heated heat medium is stored in the storage tank 21 at the start of operation, the stored heat medium may be used.

  Next, the heat medium in the storage tank 21 is supplied to the supply pipe 4 by the circulation pump 3 as shown in FIG. The heat medium in the supply pipe 4 is distributed to each flow path 5 and the bypass flow path 9.

  The heat medium distributed to each flow path 5 is sent to a radiator 53 in the middle of the flow path 5. The heat medium sent to the radiator 53 dissipates heat and warms each room. In the floor heating 53a of the first room, the room is warmed by heat conduction and radiant heat from a pipe provided under the floor. In the fan con vector 53b in the second chamber, the room is warmed by blowing air warmed by the heat medium into the room with a fan. Further, in the radiator 53c of the third chamber, the air heated by the heat medium circulates in the room by natural convection and warms the room.

  As shown in FIG. 2, the heat medium radiated by each radiator 53 is sent to the reduction pipe 6 and merges.

  Further, the heat medium distributed to the bypass flow path 9 is sent to the reduction pipe 6 and merges without passing through the radiator 53 and the like. Therefore, the heat medium that has passed through the bypass channel 9 can be sent to the reduction pipe while maintaining a high temperature.

  As shown in FIG. 2, the heat medium joined in the reduction pipe 6 is sent to the boiler 2, warmed again, stored in the storage tank 21, and reduced to the circulation pump 3.

  Next, processing by the valve control box 10 in the present embodiment will be described using the flowchart shown in FIG.

  First, the valve control box 10 measures the temperature of each room using the temperature sensor 55 of the sub-control panel 54 when the operation of the heating system is started by an instruction from the main control panel 107 or an operation switch (not shown). (Temperature measurement step S1). The measured temperature data is transmitted to the control unit 106 via the signal transmission / reception unit 101.

  Next, the control unit 106 compares the transmitted temperature of each room with the set temperature of each set room, and monitors the temperature (temperature monitoring step S2). Here, when the temperature of each room is lower than the set temperature (S2: YES), the flow rate of each flow path 5 is not controlled, and the process proceeds to the next step to determine whether or not to end the operation ( End determination step S3). In the present embodiment, it is determined whether or not the operation end is instructed by the main control panel 107 or the operation switch. If it is determined that the operation is to be terminated (S3: YES), the operation is terminated.

  On the other hand, if it is determined not to end the operation (S3: NO), the process returns to the temperature measurement step S1 and continues to monitor the temperature of each room.

  Returning to the temperature monitoring step S2, if the temperature of each room is higher than the set temperature (S2: NO), the control unit 106 blocks the flow path 5 arranged in the room that has reached the set temperature by the drive power output unit 104. Then, the electric valve 8 is driven so as to perform (flow path blocking step S4). As a result, it is possible to prevent the room temperature from being warmed to a set temperature or higher and to suppress fuel consumption when the reduced heat medium is warmed again by the boiler 2.

  Next, the control part 106 measures the flow volume of each flow path 5 and the bypass flow path 9 using the flow sensor 7 and the flow sensor 93 for bypass (flow measurement step S5). The measured flow rate data is transmitted to the control unit 106 via the flow rate signal receiving unit 102.

  Further, when the measurement of the flow rate is started, the control unit 106 transmits a measurement start signal to the timer 103 (timer start step S6). The timer 103 that has received the measurement start signal starts measuring the time T.

  Next, it is determined whether or not the time T measured by the timer 103 is within a predetermined time (measurement time determination step S7). In the present embodiment, as illustrated in FIG. 5, the control unit 106 transmits a request signal to the timer 103. When the timer 103 receives the request signal, the timer 103 transmits a time T to the control unit 106. Then, the control unit 106 determines whether or not the time T is within 120 seconds. Here, when it is determined that the time T is within 120 seconds (S7: YES), the control unit 106 determines whether or not the measured flow rate of each flow path 5 is outside the set predetermined flow rate range. Is determined (flow rate determination step S8). Here, when it is determined that the flow rate is outside the range of the predetermined flow rate (S8: YES), the control unit 106 is within the predetermined flow rate range in which the flow rate of each flow path 5 is set by the drive power output unit 104. The electric valve 8 is driven so as to become (flow rate adjusting step S9).

  Specifically, the difference between the flow rate of the flow path 5 and the set predetermined flow rate range is obtained, and the number of steps for driving the stepping motor 84 of the electric valve 8 is calculated according to the difference. Electric power for driving the number of steps is transmitted to the driving power output unit 104 to drive the electric valve 8.

  After driving the electric valve 8, the process returns to the measurement time determination step S7 to determine again whether or not the flow rate of each flow path 5 is outside the range of the predetermined flow rate.

  Returning to the measurement time determination step S7, if it is determined that the time T is greater than 120 seconds (S7: NO), the next step is performed regardless of whether or not the flow rate of each flow path 5 is outside the range of the predetermined flow rate. Proceed to S10. As described above, when the control is not completed within a predetermined time, the adjustment of the flow rate is forcibly terminated, thereby limiting the drive time of the electric valve 8 and making it difficult to break.

  Returning to the flow rate determination step S8, if it is determined that the flow rate is within the range of the predetermined flow rate (S8: NO), the process proceeds to the next step S10.

  In the next step, it is determined whether or not the total flow rate obtained by adding the flow rate for each flow channel 5 and the flow rate measured in the bypass flow channel 9 is equal to or greater than a preset minimum total flow rate (total Flow rate determination step S10). Here, when the total flow rate is less than the minimum total flow rate (S10: NO), the control unit drives the bypass electric valve 94 by the drive power output unit 104 so that the total flow rate is equal to or higher than the minimum total flow rate (total flow rate). Adjustment step S11).

  Specifically, like the flow rate adjustment of the flow path 5 described above, the difference between the total flow rate and the minimum total flow rate is obtained, and the number of steps for driving the stepping motor 84 of the bypass electric valve 94 is calculated according to the difference. The stepping motor 84 transmits power for driving the number of steps to the driving power output unit 104 to drive the bypass electric valve 94.

  In this way, by controlling the flow rate of the bypass passage 9 so that the total flow rate becomes equal to or higher than the minimum total flow rate, the circulation pump 3 is protected so that the circulation pump 3 is not overloaded. Further, by opening the bypass passage 9, an unnecessary heat medium other than the heating purpose is caused to flow through the bypass passage 9, but in the present embodiment, the bypass passage 9 is provided as described above. Since the passing heat medium is reduced to the circulation pump 3 while maintaining a high temperature without passing through the radiator 53 or the like, the heat loss during the circulation is small.

  Then, after the bypass electric valve 94 is driven in the total flow rate adjustment step S11, the flow rate measurement step S5 is performed again to determine whether or not the flow rate of each flow path 5 is within the range of the predetermined flow rate. Return.

  On the other hand, if the total flow rate is greater than or equal to the minimum total flow rate in the total flow determination step S10 (S10: YES), the adjustment of the flow rate and the total flow rate of each flow path 5 is terminated, assuming that the circulation pump 3 is not overloaded. Then, in order to monitor the temperature of each room again, the process returns to the temperature measurement step S1.

According to the automatic flow rate control system 1 of the present embodiment as described above, the following effects can be obtained.
1. A heat medium having a flow rate within a range set in each flow path 5 can be supplied.
2. Each room can be heated as desired, maintaining a convenient and comfortable temperature.
3. Since the bypass flow path 9 is provided, a flow rate equal to or greater than the minimum total flow rate can be circulated, so that the load on the circulation pump 3 is reduced and it is difficult to break.
4). By keeping the control of the electric valve 8 within a predetermined time or number of times, a failure of the electric valve 8 can be suppressed.

  The automatic flow rate adjustment system according to the present invention is not limited to the above-described embodiment, and can be changed as appropriate.

  For example, the automatic flow rate control system 1 according to the present invention is not limited to one used as a heating system, and may be used in a cooling system, a road heating system, or the like.

  When using as a cooling system, it can replace with the boiler 2 and can provide the cooling device which cools a heat carrier.

  When used as a road heating system, each flow path 5 is buried under the road surface so that the flow path 5 itself becomes a radiator, and the heat from the flow path 5 melts snow on the road surface. Can do. Further, instead of the temperature sensor 55, a snowfall sensor or a snow cover may be provided.

  Furthermore, in the above embodiment, in order to protect the electric valve 8, the driving of the electric valve 8 is stopped when a predetermined time has elapsed from the start of control, as shown in S6 to S9. As shown in FIG. 7, instead of S <b> 6 to S <b> 9, an upper limit may be set for the number of times of driving N as in S <b> 6 ′ to S <b> 10 ′ to stop driving the electric valve 8.

  In addition, the main control panel 107 and the sub control panel 54 may be configured to display calories when the heat medium is heated, and electricity charges, kerosene charges, and the like corresponding thereto.

  Furthermore, various data may be managed by setting an ID for each radiator 53 and assigning this ID to the various data.

DESCRIPTION OF SYMBOLS 1 Flow automatic adjustment system 2 Boiler 3 Circulation pump 4 Supply pipe 5 Flow path 6 Reduction pipe 7 Flow sensor 8 Electric valve 9 Bypass flow path 10 Valve control box 11 Signal line 21 Storage tank 31 Circulation pump inlet 32 Circulation pump outlet 41 Supply pipe inlet 51 Flow path inlet 52 Flow path outlet 53 Radiator 54 Sub-control panel 55 Temperature sensor 56 Input section 57 Display section 61 Reduction pipe outlet 71 Propeller 81 Drive section 82 Valve section 83 Gear 84 Stepping motor 85 Valve 91 Bypass channel inlet 92 Bypass channel outlet 93 Bypass flow sensor 94 Bypass motor valve 101 Signal transmission / reception unit 102 Flow rate signal reception unit 103 Timer 104 Drive power output unit 105 Power supply unit 106 Control unit 107 Main control panel

Claims (3)

A flow rate automatic adjustment system that automatically adjusts the flow rate of the heat medium when circulating the heat medium through a plurality of flow paths,
A circulation pump for circulating the heat medium through the plurality of flow paths;
A supply pipe connected to the circulation pump and connected to the inlet of each flow path, and distributing and supplying the heat medium to each flow path;
A reduction pipe connected to the outlet of each flow path, for joining the heat medium flowing out from the outlet and reducing it to the circulation pump;
A plurality of flow rate sensors provided for each of the flow paths to measure the flow rate of the heat medium in the flow paths;
A plurality of electric valves provided for each of the flow paths to adjust the flow rate of the heat medium in the flow paths;
A plurality of radiators for radiating heat of the heat medium provided and supplied for each flow path to each room;
A plurality of temperature sensors for measuring the temperature of each room;
A timer that measures time,
A valve control box for controlling the driving of each electric valve;
Have
The valve control box compares the temperature measured by each temperature sensor with the set temperature set in each room, and when it is determined that the temperature of the room is higher than the set temperature, the room The electric valve is driven so as to cut off the flow path arranged at the same time, and the time measurement is started by the timer, and it is determined whether or not the time is within a predetermined time. If there is, it is determined whether or not the flow rate measured by the flow rate sensor is outside the range of the predetermined flow rate set for each flow path, and if the flow rate is outside the range of the predetermined flow rate The difference between the flow rate of each flow path and the predetermined flow rate set for each flow path is obtained, and the electric valve is driven according to the difference, and it is determined that each flow rate is within the range of the predetermined flow rate. The flow rate of each flow path until When it is determined that the time measured by the timer is greater than a predetermined time, it is determined whether the flow rate is outside the range of the predetermined flow rate and the driving control of each electric valve. The automatic flow rate adjustment system, wherein the drive control of each electric valve is terminated regardless of whether the flow rate is out of a predetermined flow rate range. A flow rate automatic adjustment system that automatically adjusts the flow rate of the heat medium when circulating the heat medium through a plurality of flow paths,
A circulation pump for circulating the heat medium through the plurality of flow paths;
A supply pipe connected to the circulation pump and connected to the inlet of each flow path, and distributing and supplying the heat medium to each flow path;
A reduction pipe connected to the outlet of each flow path, for joining the heat medium flowing out from the outlet and reducing it to the circulation pump;
A plurality of flow rate sensors provided for each of the flow paths to measure the flow rate of the heat medium in the flow paths;
A plurality of electric valves provided for each of the flow paths to adjust the flow rate of the heat medium in the flow paths;
A plurality of radiators for radiating heat of the heat medium provided and supplied for each flow path to each room;
A plurality of temperature sensors for measuring the temperature of each room;
A valve control box for controlling the driving of each electric valve;
Have
The valve control box compares the temperature measured by each temperature sensor with the set temperature set in each room, and when it is determined that the temperature of the room is higher than the set temperature, the room The electric valve is driven so as to block the flow path arranged at the same time, and it is determined whether or not the number of times of driving the electric valve by adjusting the flow rate is equal to or less than the predetermined number of times of driving. If the number is less than or equal to the number of times, it is determined whether or not the flow rate measured by the flow rate sensor is outside the range of the predetermined flow rate set for each flow path, and the flow rate is outside the range of the predetermined flow rate In this case, the difference between the flow rate of each flow path and the predetermined flow rate set for each flow path is obtained, the electric valve is driven according to the difference, and each flow rate is within the range of the predetermined flow rate. Until it is determined that there is The determination as to whether the flow rate of each flow path is outside the range of the predetermined flow rate and the drive control of each electric valve are repeated, while it is determined that the number of drive times of the electric valve exceeds the predetermined number of drive times. In the case where the flow rate of the electric valves is out of the predetermined flow range, the automatic flow rate control system terminates the drive control of the electric valves regardless of whether or not the flow rates of the flow paths are out of a predetermined flow rate range . A bypass flow sensor for measuring the flow rate of the heat medium and a bypass electric valve for adjusting the flow rate are provided between the supply pipe and the reduction pipe so as to be able to flow therethrough. Has a bypass channel,
The valve control box controls the flow rate of the electric valve regardless of whether the flow rate of each flow path controlled within the set predetermined flow rate range or the flow rate of each flow path is out of the predetermined flow rate range. The bypass motor-operated valve is set so that the total flow rate of the flow rate of each flow channel for which drive control has been completed and the flow rate measured in the bypass flow channel is equal to or greater than a preset minimum total flow rate. The automatic flow rate adjustment system according to claim 1 or 2 , wherein the flow rate automatic control system is driven.

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