KR100952116B1 - Control valve of returning-water - Google Patents

Abstract

The present invention provides a heating control system and a return control valve and a heating water supply control method thereof for heating the temperature of each room to a temperature set within the same time and at the same time limiting excessive driving of the valve to prevent noise or power waste. It is about. The present invention provides a motor 120 for providing a driving force of the valve; A rotating shaft 140 having one end linked with the motor 120 to transmit a driving force of the motor 120; The valve body is provided in the return pipe 12 to support the rotating shaft 140, the valve body 153 is formed in the bottom and one side is opened therein to allow the water flowing from the bottom side to flow out to the side ( 150); An upper disk 160 fixed to the other end of the rotating shaft 140 to rotate together with the rotating shaft 140 in the valve chamber 153 and having a through hole 161 through which water can pass; It comprises a lower disk 170 in contact with the upper disk 160 and fixed to the bottom of the valve body 150, the through-hole 171 through which water penetrates therein: the motor 120 is the Return volume return valve for controlling the amount of water moving from the bottom of the valve body 150 to the side by changing the overlapping area of the through hole 161 of the upper disk 160 and the through hole 171 of the lower disk 170 It includes.

Return volume, return valve, step control, heating

Description

Control valve of returning-water}

The present invention relates to a heating control system, and more particularly, to a heating control system for heating the temperature of each room to a temperature set within the same time, and at the same time limiting excessive driving of the valve to prevent noise or power waste, and It relates to a return control valve and a heating water supply control method thereof.

In a heating system supplied to a conventional house, the heating water heated in a boiler is moved to a hot water distributor, thereby raising a temperature of a room through a heating pipe distributed from the hot water distributor to each room.

At this time, each heating pipe has a different length. Therefore, the heating time of each room changes. That is, the place where the heating pipe is short reaches the set temperature in a short time, and the place where the heating pipe is long reaches the set temperature after a long time.

In this case, the boiler continues to run so that the last heating line reaches the set temperature. Therefore, the boiler operating time is long, not only the fuel efficiency is worsened, but also the temperature of the room approaching the set temperature continues to rise so that all rooms do not reach the desired set temperature.

Therefore, in order to solve such a problem, recently used heating systems have previously set the flow rate by adjusting the valve in accordance with the length of the heating pipe. However, there was no way to reflect this when the length of the heating piping was different from the initial design due to the remodeling of the house.

And even when the surrounding environment changes, there is a problem that the preset flow rate does not raise the temperature of all the rooms uniformly.

Therefore, the present invention has been made to solve the above-mentioned conventional problems, an object of the present invention is to measure the temperature to circulate each room and return water, and the heating system and the heating water to adjust the flow rate of the circulating heating water accordingly It is to provide a supply control method.

Another object of the present invention is to control the heating water flow rate by measuring the temperature of the heating water being returned, while controlling the heating system and its heating water supply control to avoid waste of noise and power by avoiding excessive valve operation To provide a way.

Still another object of the present invention is to provide a return volume control valve which can be opened and closed precisely by an amount to be opened and closed in a control unit, and the opening and closing degree can be kept constant according to a control signal of the control unit even by repeated use. will be.

According to a feature of the present invention for achieving the above object, the return volume control valve according to the present invention includes a motor for providing an opening and closing driving force of the valve; A rotating shaft having one end coupled with the motor to transmit a driving force of the motor; A valve body provided inside the return pipe to support the rotation shaft and having a valve chamber formed therein so that the lower end and one side thereof are opened to allow the water flowing from the lower end to the side; An upper disk fixed to the other end of the rotating shaft to rotate together with the rotating shaft in the valve chamber and having a through hole through which water can pass; And a lower disk which is in contact with the upper disk and fixed to a lower end of the valve body, and has a through hole formed therein through which water flows. The motor changes an area where the through hole of the upper disk overlaps with the through hole of the lower disk. Adjust the amount of water that moves from the bottom of the valve body to the side.

At this time, the contact surface of the rotary shaft and the valve body may further comprise a sealing ring for preventing the water in the valve chamber from flowing back through the contact surface of the rotary shaft and the valve body.

In addition, it is composed of a plurality of gears, by connecting one end of the rotating shaft and the motor, may further include a gear box for adjusting the rotational amount of the rotating shaft relative to the rotational amount of the motor.

In addition, the through-holes of each of the upper disk and the lower disk may be formed in the same fan shape.

In addition, any one of the lower surface or the upper surface of the lower disk protruding moving projection is formed; On the other side, the movable projection is inserted to form a movable guide groove: the guide groove is formed so that the guide projections from the position where the through holes of each of the upper disk and the lower disk overlap with each other are shielded so that there is no overlapping portion. It may be formed along a moving copper line.

And either one of the upper disk or the lower disk is inserted into the inside of the disk and a portion protrudes to the lower surface or the upper surface of the lower disk, the elastic projection is formed elastically deformable into the disk; On the other side, a guide groove is formed along a moving line through which the guide protrusion moves from a position where all the through holes of the upper disk and the lower disk overlap each other to a shielded position so that there is no overlapping portion. At the position to be divided into two times, a wider groove may be formed that is wider than the guide groove so that the elastic protrusion can be seated.

On the other hand, the heating control system according to the present invention and the boiler for heating and circulating the heating water circulating the heating pipe; A hot water distribution unit which receives hot water from the boiler and distributes the hot water to the heating pipes, collects the hot water circulated through the heating pipes, and discharges the water to the boiler; A heating control system comprising a control unit for controlling the heating water flow rate supplied to each of the heating pipes by controlling the driving of the boiler and the heating water return flow rate of the hot water distribution unit. A plurality of return valves for controlling a flow rate of return flow introduced from the room through the return pipe; It comprises a plurality of temperature sensors for measuring the return temperature of each return pipe: The control unit measures the temperature of the return water returned from each heating pipe from the temperature sensor, the return valve in accordance with the return temperature The amount of circulation of the heating water is controlled by adjusting the degree of opening.

At this time, the control unit, the return valve of the return pipe having a return temperature less than the user set temperature in comparison with the user set temperature and the return temperature of each return pipe is opened; The return valve of the return pipe having a return temperature greater than or equal to the user set temperature is shielded: When there are a plurality of return pipes having a return temperature less than or equal to the user set temperature, the heating amount, which is a difference between the user set temperature and the return temperature, is respectively calculated. ; The opening degree of the return valve of the return pipe having the largest heating amount may be maximized, and the opening degree of each of the return valves may be divided into a plurality of stages according to a difference from the maximum heating amount.

The plurality of steps may be read out from a lookup table defined according to a difference between the maximum heating amount and the heating amount of each return pipe; The look-up table may store the rotation angle of the rotating shaft in the return valve obtained by dividing the maximum opening angle of the return valve by an integer (N) times according to the difference in the heating amount.

And the return valve, the motor for providing an opening and closing drive of the valve;

A rotating shaft having one end coupled with the motor to transmit a driving force of the motor; A valve body provided inside the return pipe to support the rotation shaft and having a valve chamber formed therein so that the lower end and one side thereof are opened to allow the water flowing from the lower end to the side; An upper disk fixed to the other end of the rotating shaft to rotate together with the rotating shaft in the valve chamber and having a through hole through which water can pass; And a lower disk which is in contact with the upper disk and fixed to a lower end of the valve body and has a through hole formed therein through which water flows. The motor changes an area where the through hole of the upper disk overlaps with the through hole of the lower disk. It is also possible to adjust the amount of water moving from the bottom of the valve body to the side.

In addition, the contact surface of the rotary shaft and the valve body may further comprise a sealing ring for preventing water in the valve chamber from flowing back through the contact surface of the rotary shaft and the valve body.

And it is composed of a plurality of gears, by connecting one end of the rotating shaft and the motor, may further include a gearbox for adjusting the rotational amount of the rotating shaft relative to the rotational amount of the motor.

In addition, the through-holes of each of the upper disk and the lower disk may be formed in the same fan shape.

And, any one of the upper disk lower surface or the lower disk upper surface protruding moving projections are formed; On the other side, the movable projection is inserted to form a movable guide groove: the guide groove is formed so that the guide projections from the position where the through holes of each of the upper disk and the lower disk overlap with each other are shielded so that there is no overlapping portion. It may be formed along a moving copper line.

In addition, any one of the upper disk or the lower disk is inserted into the disk and a part of which protrudes into the lower surface of the upper disk or the upper surface of the lower disk, an elastic projection capable of elastic deformation into the disk is formed; On the other side, a guide groove is formed along a moving line through which the guide protrusion moves from a position where all the through holes of the upper disk and the lower disk overlap each other to a shielded position so that there is no overlapping portion. At the position to be divided into two times, a mounting groove having a wider width than the guide groove may be formed so that the elastic protrusion may be seated.

On the other hand, the heating water supply control method according to the present invention comprises the steps of (A) recognizing the boiler operation command; (B) driving each of the return valves to fully open them; (C) measuring the return temperature from the temperature sensor provided in each return tube; (D) determining whether there is a value below a set set temperature among the measured return temperatures; (E) driving a boiler when there is a return temperature below the set temperature; (F) determining whether there are a plurality of return temperatures below the set temperature; (G) calculating a heating amount when there are a plurality of return temperatures below the set temperature; (H) setting a maximum value of the calculated heating amount as a reference heating amount; (I) calculating a valve opening grade according to a difference value between the reference heating amount and the heating amount of each return pipe; (J) opening the return valve in accordance with the calculated opening rating; (K) is performed by repeating steps (C) to (J).

At this time, as a result of the determination in step (F), when there is one return temperature below the set temperature, the return valve of the return pipe having a return temperature below the set temperature may be opened to the maximum, and all other return valves may be shielded. have.

Meanwhile, in the step (K), the repetition of the steps (C) to (J) may be repeated at a specified time interval.

Here, the return valve, the motor for providing an opening and closing drive of the valve; A rotating shaft having one end coupled with the motor to transmit a driving force of the motor; A valve body provided inside the return pipe to support the rotation shaft and having a valve chamber formed therein so that the lower end and one side thereof are opened to allow the water flowing from the lower end to the side; An upper disk fixed to the other end of the rotating shaft to rotate together with the rotating shaft in the valve chamber and having a through hole through which water can pass; And a lower disk which is in contact with the upper disk and fixed to a lower end of the valve body and has a through hole formed therein through which water flows. The motor changes an area where the through hole of the upper disk overlaps with the through hole of the lower disk. It is also possible to adjust the amount of water moving from the bottom of the valve body to the side.

The contact surface of the rotary shaft and the valve body may further include a sealing ring to prevent water in the valve chamber from flowing back through the contact surface of the rotary shaft and the valve body.

In addition, it is also composed of a plurality of gears, by connecting one end of the rotating shaft and the motor, it is also possible to further include a gearbox for adjusting the amount of rotation of the rotating shaft relative to the amount of rotation of the motor.

In addition, the through-holes of each of the upper disk and the lower disk may be formed in the same fan shape.

In addition, any one of the lower surface or the upper surface of the lower disk protruding moving projection is formed; On the other side, the movable projection is inserted to form a movable guide groove: the guide groove is formed so that the guide projections from the position where the through holes of each of the upper disk and the lower disk overlap with each other are shielded so that there is no overlapping portion. It may be formed along a moving copper line.

At this time, any one of the upper disk or the lower disk is inserted into the disk to protrude to the lower surface of the upper disk or the lower disk, the upper surface of the lower disk, the elastic projection is formed elastically deformable into the disk; On the other side, a guide groove is formed along a moving line through which the guide protrusion moves from a position where all the through holes of the upper disk and the lower disk overlap each other to a shielded position so that there is no overlapping portion. At the position to be divided into two times, a mounting groove having a wider width than the guide groove may be formed so that the elastic protrusion may be seated.

In the above-described return amount control valve according to the present invention, a heating control system having the same, and a heating water supply control method thereof, the following effects can be expected.

That is, the heating water circulation amount can be proportionally adjusted according to the temperature of each room without being limited to the length of the heating pipe, and the temperature of each room can be raised to the set temperature within the same time. In addition, since the flow rate of the water is adjusted according to the return temperature of the heating water, there is an advantage that the temperature of each room can be proportionally increased without being affected by environmental changes after the renovation or construction of the house.

In addition, the present invention has the advantage that it is possible to prevent the waste of power or the generation of noise due to excessive valve operation by increasing the temperature of each room proportionally, step by step the amount of adjustment of the return valve.

In addition, the stepwise operation of the return valve by the mechanical configuration of the valve in addition to the electronic control, so that the operation position of the return valve is always constant even after repeated use, it is possible to prevent the malfunction of the return valve There is an advantage.

Hereinafter, with reference to the accompanying drawings, a specific embodiment of the return water return valve according to the present invention as described above, a heating control system having the same and a method for controlling the heating water supply thereof will be described in detail.

1 is a block diagram showing the overall configuration of the heating control system according to a specific embodiment of the present invention, Figure 2 is an internal configuration showing a specific embodiment of a hot water distribution unit applied to the heating control system according to the present invention. 3 is a partial cross-sectional view showing a specific embodiment of the return flow return valve according to the present invention, Figures 4a to 4b shows a first embodiment of the upper and lower disks provided in the return flow return valve according to the present invention; 5A to 5B are plan views showing a second embodiment of the upper and lower disks provided in the return flow return valve according to the present invention, and FIGS. 6A to 6B are provided in the return flow return valve according to the present invention. 7A to 7B are plan views illustrating a fourth embodiment of the upper and lower disks provided in the return water return valve according to the present invention. Fig., And Fig. 8a through Fig. 8d are a plan view and a side view showing a fifth embodiment of the upper and lower disc is provided with a water exchange water exchange valve according to the present invention.

First, as shown in Figure 1, the heating control system according to the present invention comprises a boiler (10). The boiler 10 is a part that heats the heating water in the pipe by burning fossil fuel such as gas or kerosene, and is driven or not according to a control signal of the control unit 20 to be described later.

On the other hand, the heating water heated in the boiler 10 is delivered to the hot water distribution unit 30 through the hot water distribution unit 30 and the return pipe 12 connecting the boiler 10.

The hot water distribution unit 30 delivers the heating water heated in the boiler 10 to each of the rooms 71, 72, 73, and 74 through the water supply pipes 51, 52, 53, and 54. 72, 73, 74) is raised.

At this time, the hot water distribution unit 30, the flow rate of the heating water delivered to each room (71, 72, 73, 74) is adjusted differently, the detailed structure of the hot water distribution unit 30 and the flow rate control method is as follows It will be described in detail with Figures 2 and 3.

In the example shown in FIG. 1, an example is shown in which the heating water is supplied to four rooms 71, 72, 73, and 74. As shown therein, the heated heating water supplied by the water supply pipe 14 is the first to the fourth water pipe 51, 52, 53, 54, respectively, the first to fourth rooms 71, 72 73, 74).

In addition, the temperature of the room is increased, and the heating water whose temperature is lowered is recovered to the hot water distribution unit 30 through the first and fourth return pipes 61, 62, 63, and 64, respectively.

On the other hand, the hot water distribution unit 30 has a detailed configuration as shown in FIG. The hot water distribution unit 30 is configured to include a water supply pipe 14 to receive the heating water heated from the boiler (10). The water supply pipes 51, 52, 53, and 54 are distributed from the water supply pipe 14 by the number of the rooms 71, 72, 73, and 74. At this time, each of the water supply pipes (51, 52, 53, 54) is not provided with a separate flow control device.

In addition, the hot water distribution unit 30 is configured to include each inlet pipe into which the heating water circulated through each of the rooms (71, 72, 73, 74). The inlet pipe is connected to a return pipe 12 which transfers the collected heating water to the boiler 10. At this time, the end of each of the return pipe (61, 62, 63, 64) is provided with a temperature sensor for measuring the temperature of the returned heating water.

The temperature sensor is a part for measuring the temperature of the heating water is returned to the control unit 20.

Meanwhile, in the return pipe 12 to which the return pipes 61, 62, 63, and 64 are connected, a return amount return valve for controlling a flow rate of the heating water returned from the return pipes 61, 62, 63, and 64. (Hereinafter referred to as a 'return valve') is provided. At this time, the return valve (100, 200, 300, 400) is provided corresponding to the number and position of the return pipe (61, 62, 63, 64), respectively.

The return valve (100, 200, 300, 400) is a portion for adjusting the flow rate of return according to the control signal of the control unit, the control unit measures the water temperature of the heating water to be recovered by the temperature sensor of the return valve Adjust the opening and closing amount. That is, in the present invention, in controlling the amount of heating water circulating through each room, the amount of return is adjusted to adjust the amount of circulation.

Here, the method of adjusting the return amount will be described in detail in describing the operation of the present invention.

Hereinafter, a detailed configuration of the return valve will be described with reference to FIG. 3. The return valve (100, 200, 300, 400) is configured to include a motor 120 provided outside the return pipe (12). The driving angle of the motor 120 is adjusted according to the control of the control unit 20.

And the motor 120 is connected to the rotating shaft 140 for transmitting the rotational force of the motor 120 to the upper disk 160 to be described later. The rotation shaft 140 may be directly connected to the motor 120, but may be connected by a gear box 130 including a plurality of gears to adjust the rotation ratio.

As an example, as shown in FIG. 3, when four radii are connected through a gearbox 130 composed of different gears, the amount of rotation of the motor 120 does not coincide with the amount of rotation of the rotation shaft 140. That is, the amount of rotation of the rotating shaft 140 is smaller than the amount of rotation of the motor 120, and thus the amount of rotation of the disk to be described later can be precisely controlled.

On the other hand, the rotating shaft 140 is inserted into the valve body 150 provided in the return pipe (12). The valve body 150 has an upper end formed close to the rotation shaft 140 to support the rotation shaft 140, and at least one sealing ring 142 is provided between the rotation shaft 140 and the valve body 150. Thus, the water in the valve chamber 153, which will be described later, is prevented from penetrating into the gearbox 130 or the motor 120 through a contact surface between the rotating shaft 140 and the inner surface of the valve body 150.

On the other hand, the lower portion of the valve body 150 is formed with a valve chamber 153 so that the heating water can flow. The valve chamber 153 is open at the lower end thereof, and an inlet hole 155 communicating with the return pipes 61, 62, 63, and 64 is formed, and one side of the valve chamber 153 is open with a drain hole 157 communicating with the return pipe 12. Is formed.

The lower end of the rotating shaft 140 is formed in a length located in the valve chamber 153, the upper disk 160 is fixed to the lower end of the rotating shaft 140 is connected.

In addition, a lower disk 170 corresponding to the upper disk 160 is fixed to an inner lower end of the valve chamber 153 below the upper disk 160. Of course, the upper and lower disks 160 and 170 are formed to have a size corresponding to the inner diameter of the valve chamber 153 so that no leakage occurs to the outside of the disks 160 and 170.

Accordingly, as the rotary shaft 140 rotates, the upper disk 160 rotates, and the lower disk 170 does not rotate so that the through holes 161 and 171 formed in the upper and lower disks 160 and 170 are opened and closed. It is possible to control the distribution of the heating water of the recovery pipe.

The upper and lower disks may be formed in various forms. Hereinafter, various embodiments of the upper and lower disks will be described in detail with reference to FIGS. 4 through 8.

4A to 4B are plan views showing a first embodiment of the upper and lower disks provided in the return amount return valve according to the present invention.

In the first embodiment of the disk, the upper and lower disks (160a, 170a) are formed in the same shape, the through hole (161a, 171a) is formed in half of the center around the rotating shaft (140). Therefore, when the through hole 161a of the upper disk 161a and the through hole 171a of the lower disk 171a overlap, the return valves 100, 200, 300, and 400 are completely opened. When the shield 163a of the upper disk 160a and the through hole 171a of the lower disk 170a overlap, the shielded portion 163a is completely shielded.

5A to 5B are plan views illustrating a second embodiment of upper and lower disks provided in the return water return valve according to the present invention.

 The second embodiment of the disc differs in shape from the through holes 161b and 171b from the first embodiment. That is, as shown, through-holes (161b, 171b) are formed on the side opposite to the 1/4 size with respect to the rotation axis 140 of the disk. The upper and lower disks 160b and 170b may control the opening and closing of the control valve while reducing the amount of rotation of the upper disk 160b in half as compared with the first embodiment.

Of course, more examples will not be described below, but the through hole may be formed in various sizes, and accordingly, the amount of rotation of the upper disk for controlling the closing may be set differently.

6A to 6B are plan views showing a third embodiment of the upper and lower disks provided in the return amount return valve according to the present invention.

As shown in the drawing, in the third embodiment of the disk according to the present invention, the upper and lower disks 160c and 170c have through holes 161c and 171c having basically the same shape as the first embodiment of the disk. do. However, a circular arc-shaped guide groove 165c is formed on a lower surface of the shielding portion 163c of the upper disk 160c, and is inserted into the guide groove 165c on one side of the upper surface of the lower disk 170c so as to be movable. A protruding moving protrusion 175c is formed.

The guide groove 165c is a portion for limiting the moving range of the moving protrusion 175c. The guide groove 165c maintains the relative positions of the upper and lower disks 160c and 170c even after repeated use of the motor 120. do. That is, even though the motor 120 may finely adjust the operation range, fine operation errors may accumulate by repeated use. When such an operation error accumulates, the control unit 20 may operate the return valve so that the disks 160c and 170c are shielded, so that the actual return valve may not be completely shielded. Therefore, the guide groove 165c and the moving protrusion 175c are parts for solving such an error.

Of course, the guide groove may be formed on the upper surface of the lower disk 170c, and the moving protrusion may be formed on the lower surface of the upper disk 160c.

7A to 7B are plan views showing a fourth embodiment of the upper and lower disks provided in the return amount return valve according to the present invention.

In the fourth embodiment of the disk, the through holes 161d and 171d of the upper and lower disks 160d and 170d have the same shape as the second embodiment of the disk, and thus the upper and lower disks 160d and 170d. In the embodiment, the guide groove 165d and the moving protrusion 175d are formed.

8A to 8D are a plan view and a side view showing a fifth embodiment of the upper and lower disks provided in the return water return valve according to the present invention.

The eighth embodiment of the disc has a form similar to that of the third embodiment of the disc. However, a certain portion of the guide groove 165e is provided with a seating groove 167e having an extended width. This is because the control of the return valve according to the present invention is made for each section, in order to mechanically guide the seating position in each section in accordance with the opening level of the return valve. Therefore, if the return valve is adjusted in four steps (maximum, large, small, shielded), as shown, four seating grooves 167e are formed to divide the guide grooves 165e into three.

In addition, an elastic protrusion 175e corresponding to the moving protrusion 175c is formed on the upper surface of the lower disc 170e in the third embodiment of the disc. The elastic protrusion 175e refers to a protrusion provided to protrude to the upper surface of the lower disk 170e and capable of elastic deformation downward. For example, a bearing having a spring therein may be used.

Accordingly, the elastic protrusion 175e moves along the guide groove 165e and stably rests on the seating groove 167e to determine the opening amount of the return valves 100, 200, 300, and 400. .

Hereinafter, the operation of the heating control system according to the present invention will be described in detail according to the heating water supply control method.

9 is a flowchart illustrating a specific embodiment of a heating water supply control method according to the present invention, Figure 10 is an illustration showing an example of a look-up table applied to a specific embodiment of the heating water supply control method according to the present invention It is a chart.

As shown in Figure 9, the Namba water supply control method according to the present invention is started by the boiler 10 operation command is generated in the control unit 20 (S110). The operation command may be generated by a user's input, or may be generated by the control unit 20 recognizing that the temperature of the room is lower than a specified temperature, and thus, the driving point of the boiler 10.

When the operation command is generated, the control unit 20 opens all of the return valves 100, 200, 300, and 400 provided in the hot water distribution unit 30 (S120). At this time, when the return valves 100, 200, 300, and 400 are opened, the heating water is circulated in each of the water supply pipes 51, 52, 53, and 54 and the return pipes 61, 62, 63, and 64.

Thereafter, the control unit 20 measures the temperature of the returned heating water from the temperature measuring sensor provided at the end of the return pipe (61, 62, 63, 64) (S130).

In operation S140, it is determined whether there is a measured value less than a set temperature among the measured temperatures of the heating water. If there is no return water below the set temperature, it is not necessary to operate the boiler 10, so that the return temperature is checked at a predetermined time interval without the boiler 10 running, and a value below the set value among the return temperatures may occur. Wait for a while.

However, as a result of the determination of step 130, if the heating water is less than the set temperature, the boiler 10 is operated to increase the temperature of the heating water (S140).

Then, it is determined whether there is a plurality of heating water having a return temperature less than the set temperature (S160). This is because proportional control is not necessary when there is one heating water having a return temperature less than the set temperature, and only proportional control is required according to the return temperature.

Therefore, in the case where there is one heating water having a return temperature below the set temperature, only 100% of the return valve provided in the return pipe through which the heating water having the return temperature below the set temperature passes passes the return water provided in the other return pipe. All valves are shielded. At this time, the 100% opening means that the upper disk 160 is rotated so that the through holes 161 and 171 of the upper and lower disks 160 and 170 coincide with each other and are formed through the through holes 161 and 171. It means to maximize the channel.

On the other hand, when there are a plurality of return pipes measuring the return temperature of less than the set temperature, the heating amount is calculated for the heating water of each of the return pipes measured temperature less than the set temperature (S170). In this case, the heating amount refers to a difference between a set temperature and a heating water temperature of the return pipes 61, 62, 63, and 64.

Then, the maximum value of each of the calculated heating amount is selected as the reference heating amount (S180).

Next, the individual heating grade is calculated based on the heating amount for the heating water of each of the return pipes 61, 62, 63, and 64 based on the reference heating amount (S190). At this time, the calculation of the individual heating amount is calculated by reading from the lookup table stored in the storage medium of the control unit 20.

Here, referring to the look-up table shown in FIG. 10, when the difference between the reference heating amount and the heating amount of the return pipe is 0 ° C. or more and less than 5 ° C., the individual heating grade is calculated as a first grade. The return valve opening amount is 100%, and the rotation angle of the upper disk 160 by the motor 120 is 0 °.

When the difference between the reference heating amount and the heating amount of the return pipe is 5 ° C. or more and less than 10 ° C., the individual heating grade is calculated as the second level, and thus the return valve opening amount is 75%, and the motor 120 The rotation angle of the upper disk 160 is 45 °.

In addition, when the difference between the reference heating amount and the heating amount of the return pipe is more than 10 ℃ 15 ℃ is calculated by the individual heating grade 3 grade, accordingly the return valve opening amount is 50%, the upper disk (160) The rotation angle is 90 °; When the difference between the reference heating amount and the heating amount of the return pipe is 15 ° C. or more, the individual heating grade is calculated as four grades. The return valve opening amount is 25% and the rotation angle of the upper disk 160 is 135 °. Becomes

Accordingly, the return valve (100, 200, 300, 400) is divided into five stages the degree of opening and closing is controlled step by step (total five stages including the shielding state). Here, the lookup table may be set differently according to a driving state or heating conditions of the heating control system. Therefore, it means that the degree of division of the heating grade or the opening and closing control grade of the return valve (100, 200, 300, 400) and the like according to the installation environment can be set differently.

When subdividing the heating grade, there is an advantage that the temperature difference of each room can be finely controlled. However, the continuous operation of the return valves (100, 200, 300, 400) makes the noise too high and the power consumption is increased. There are more disadvantages than effects. Therefore, it is desirable to divide by appropriate grade and control step by step.

Control of the step-by-step return valve (100, 200, 300, 400) with the mechanical shape of the upper and lower disks (160, 170) as shown in Figures 6 to 8, without depending on the drive control of the motor 120 It is desirable to. In particular, in the fifth embodiment of the disk, a seating groove 167e is formed at a relative position of the upper and lower disks 160e and 170e corresponding to the heating level defined in the lookup table. That is, the seating grooves 167e are formed at five positions from the 100% open position of the upper and lower disks 160e and 170e to the shielding, respectively, so that the steps of the return valves 100, 200, 300, and 400 are performed. To facilitate control.

The control unit 20 opens the return valves 100, 200, 300, and 400 by a predetermined size according to the grade calculated by reading from the lookup table (S200).

Of course, the return valve (100, 200, 300, 400) of the return pipe in which the temperature value above the set temperature is measured is shielded.

Thereafter, after the time delay of a predetermined time, the steps 130 to 200 are repeatedly performed until the return temperature of all the return pipes 61, 62, 63, and 64 becomes higher than or equal to the set temperature (S210).

The rights of the present invention are not limited to the embodiments described above, but are defined by the claims, and those skilled in the art can make various modifications and adaptations within the scope of the claims. It is self-evident.

The present invention relates to a heating control system, while heating the temperature of each room to a set temperature within the same time, while limiting excessive driving of the valve to prevent noise and power waste, and by the mechanical configuration of the return valve The operation position of the return valve is always made constant, thereby preventing the malfunction caused by the repeated use of the return valve.

1 is a block diagram showing the overall configuration of a heating control system according to a specific embodiment of the present invention.

Figure 2 is an internal configuration showing a specific embodiment of the hot water distribution unit applied to the heating control system according to the present invention.

Figure 3 is a partial cross-sectional view showing a specific embodiment of the return amount control valve according to the present invention.

Figure 4a to Figure 4b is a plan view showing a first embodiment of the upper and lower disks provided in the return amount control valve according to the present invention.

5a to 5b are plan views showing a second embodiment of the upper and lower disks provided in the return amount control valve according to the present invention.

Figure 6a to Figure 6b is a plan view showing a third embodiment of the upper and lower disks provided in the return amount control valve according to the present invention.

7A to 7B are plan views showing a fourth embodiment of the upper and lower disks provided in the return volume control valve according to the present invention;

8A to 8D are a plan view and a side view showing a fifth embodiment of the upper and lower disks provided in the return volume control valve according to the present invention;

9 is a flowchart illustrating a specific embodiment of a heating water supply control method according to the present invention.

10 is an exemplary view showing an example of a look-up table applied to a specific embodiment of the heating water supply control method according to the present invention.

* Description of the symbols for the main parts of the drawings *

10: boiler 12: return pipe

14: water supply pipe 20: control unit

30: temperature distribution unit 51: the first water supply pipe

52: second water supply pipe 53: third water supply pipe

54: fourth water supply pipe 61: first return pipe

62: second return pipe 63: third return pipe

64: 4th return pipe 71, 72, 73, 74: 1st, 2nd, 3rd, 4th room

100,200,300,400: 1, 2, 3, 4 return valve

110,210,310,410: 1st, 2, 3, 4 temperature sensor

120: motor 130: gearbox

140: rotating shaft 142: sealing ring

150: valve body 153: valve chamber

155: inlet hole 157: drain hole

160a, 160b, 160c, 160d, 160e: upper disc

161a, 161b, 161c, 161d, 161e, 171a, 171b, 171c, 171d, 171e: through hole

163a, 163b, 163c, 163d, 163e: shielding part

165c, 165d, 165e: Guide Home

167e: settling groove 175c, 175d: moving protrusion

175e: elastic protrusion

Claims (24)

A motor providing an opening and closing drive force of the valve; A rotating shaft having one end coupled with the motor to transmit a driving force of the motor; A valve body provided inside the return pipe to support the rotation shaft and having a valve chamber formed therein so that the lower end and one side thereof are opened to allow the water flowing from the lower end to the side; An upper disk fixed to the other end of the rotating shaft to rotate together with the rotating shaft in the valve chamber and having a through hole through which water can pass; A lower disk in contact with the upper disk and fixed to the lower end of the valve body and having a through hole through which water penetrates; The lower surface of the upper disk and the upper surface of the lower disk are provided rotatably in contact with each other, the motor rotates any one of the upper disk or the lower disk, so that the through hole of the upper disk and the through hole of the lower disk overlap Return volume control valve, characterized in that for controlling the amount of water moving from the bottom of the valve body to the side by changing the area. The method of claim 1, And a sealing ring at the contact surface of the rotating shaft and the valve body further comprising a sealing ring to prevent water in the valve chamber from flowing back through the contact surface of the rotating shaft and the valve body. The method of claim 2, It is composed of a plurality of gears, by connecting one end of the rotating shaft and the motor, the return volume control valve further comprises a gear box for adjusting the rotational amount of the rotating shaft relative to the rotational amount of the motor. The method of claim 3, wherein The through-holes of each of the upper disk and the lower disk is formed in the same shape in a fan shape, the flow rate regulating valve. The method according to any one of claims 1 to 4, A protruding moving protrusion is formed on either the lower surface of the upper disk or the upper surface of the lower disk; On the other side, the moving protrusion is inserted to form a movable guide groove: And the guide groove is formed along a moving line through which the guide protrusion moves from a position where the through holes of each of the upper disk and the lower disk overlap each other to a position where it is shielded so that there is no overlapping portion. The method according to any one of claims 1 to 4, Any one of the upper disk and the lower disk is inserted into the disk to partially protrude to the lower surface of the upper disk or the upper surface of the lower disk, and an elastic protrusion capable of elastic deformation into the disk is formed; On the other side, a guide groove is formed along a moving line through which the guide protrusion moves from a position where all the through holes of the upper disk and the lower disk overlap each other to a shielded position so that there is no overlapping portion. Recirculation amount control valve, characterized in that the seating groove is wider than the guide groove is formed so that the elastic projection can be seated in the position divided by the ship. delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete

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