KR20120108204A - Each room controlling system having flux limiting valve and the flux limiting valve equipped in the each room controlling system - Google Patents

Abstract

PURPOSE: A system for controlling the temperature of each room with a flow control valve is provided to be operated with a low cost and a simple structure, and to prevent noise generated from a heating pipe. CONSTITUTION: A system for controlling the temperature of each room comprise a temperature adjustor(200), valves(300) for each room, a flow control valve(400), and a control unit(500). The temperature adjustor sets the temperature of each room. The valves for each room control the quantity of heating water supplied to each room. The flow control valve is formed at the entrance of the valves, and controls the maximum quantity of the heating water. The control unit controls the operation of the valves for each room by receiving a signal set in the temperature adjustor. [Reference numerals] (100) Heat source; (500) Control unit; (AA) First room; (BB) Second room; (CC) N th room

Description

EACH ROOM CONTROLLING SYSTEM HAVING FLUX LIMITING VALVE AND THE FLUX LIMITING VALVE EQUIPPED IN THE EACH ROOM CONTROLLING SYSTEM}

The present invention relates to a flow control valve equipped with a flow restriction valve and a flow restriction valve provided therein, and more particularly to a flow restriction valve for limiting the maximum supply amount of the heating water irrespective of the supply pressure of the heating water. The flow restrictor valve is provided on the inlet side to prevent noise from cavitation caused by the concentration of the flow in the heating room when the heating is stopped in some of the plurality of rooms and to reduce the heating cost. It relates to a square room control system and a flow rate limiting valve provided therewith.

In general, a boiler system is provided with a heating water distributor for distributing heating water in each room requiring heating.

The heating water distributor receives the heating water heated in the heat exchanger of the boiler through the heating water supply pipe and supplies the heating water to each room, and the supplied heating water is cooled after delivering the thermal energy to each room. It is returned through, the heating water distributor is installed in each room valve for controlling the supply of heating water in each room according to the heating load of the temperature set in the temperature controller installed in each room.

Conventionally, the total supply amount of the heating water supplied to each room through the heating water distributor is set to be constant, so that the heating water of the set rectified amount is always supplied. Was configured to distribute the concentrated amount of heating water to the remaining rooms to be heated.

However, when the heating water of the initially set rectified amount is supplied to a part of the heating room, the flow rate of the heating water supplied to the heating room is increased, but as the flow velocity increases, the cavitation occurs. This causes water hammer hitting the inner wall of the heating pipe, resulting in noise, and reducing heat exchange time in which the heat of the heating water is transferred to the room, thereby preventing sufficient heat transfer. Although the area is reduced, there is a problem that the heating cost is not reduced compared to the case of heating the whole room due to the low heating efficiency.

In order to solve this problem, Patent No. 10-0929210 is provided with a variable flow valve in the return pipe flowing heating water is returned through the return pipe of each room, when the heating is stopped as much as the flow rate corresponding to the room An automatic constant flow rate control device configured to adjust the total flow rate of a household has been disclosed, and accordingly, the total flow rate of each generation is controlled in proportion to the heating status of each room, so that the flow rate flowing through the room when there is a room in which heating is not performed. By reducing the total amount of refinery, it is possible to reduce noise generation and heating costs.

However, in such a constant flow rate automatic control device, it is configured to control the driving of the actuator for adjusting the opening amount of the variable flow valve by receiving the signal of the temperature control part installed in each room and the signal of the flow rate sensor installed in the return pipe. The system structure for controlling the variable flow valve to reduce the total rectification amount by the flow rate corresponding to the room in which the heating is stopped is complicated, and the installation cost of the system is expensive. Correspondingly, there is a problem in that it is not easy to control the supply amount of the heating water supplied to each room below the allowable flow rate required for heating.

The present invention has been made to solve the above problems, heating pipes generated by the cavitation as the heating water is intensively supplied to the room where the heating is performed when the heating is stopped in some of the plurality of rooms It is an object of the present invention to provide a room control system equipped with a flow restriction valve that prevents noise generation and reduces heating costs, and at the same time, simplifies the system structure so that the system can be implemented at low cost.

In addition, an object of the present invention is to provide a flow restriction valve that can reduce the unit cost of the product and increase productivity by simplifying the structure of the flow restriction valve that can limit the maximum flow rate of the heating water supplied to each valve.

Each room control system is provided with a flow rate limiting valve of the present invention for achieving the above object, the temperature controller for setting the heating temperature of each room; Each room valve for adjusting the supply amount of the heating water supplied to each room according to the heating load of each room; A flow restriction valve provided at the heating water inlet side of each valve to limit a maximum supply amount of the heating water supplied to each valve; And a controller configured to control the driving of the respective valves by receiving the signal set by the temperature controller.

In this case, the flow rate limiting valve may be configured such that the flow path of the heating water is limited by the elastic member deformed by the supply pressure of the heating water supplied to the respective valves.

The flow restriction valve according to the present invention includes a cylindrical member having a flow path for heating water therein, a central pillar member provided at an inner central portion of the cylindrical member, an inner surface of the cylindrical member and an outer surface of the central pillar member. A valve body which connects and is integrally formed with connecting members provided at predetermined intervals along the circumferential direction; And an elastic member provided between the inner side surface of the cylindrical member and the outer side surface of the central column member to deform by the supply pressure of the heating water to limit the flow path of the heating water.

In this case, the upper outer surface of the central pillar member may protrude at regular intervals along the circumferential direction, and may be configured to have a separation prevention member integrally formed to prevent the elastic member from being separated out of the cylindrical member.

In addition, the outer surface of the central pillar member is formed integrally with the flow rate distribution member for forming a flow path of the heating water so that the heating water is projected at regular intervals along the circumferential direction is uniformly distributed in the circumferential direction of the central pillar member Can be.

In addition, guide ribs protruding at regular intervals along the circumferential direction are integrally formed on the inner surface of the cylindrical member, and guide grooves are formed between the adjacent guide ribs, and the lower end of the guide rib and the lower end of the guide groove are Each of the protruding pieces protruding toward the central pillar member may be integrally formed, and a step may be formed up and down between the adjacent protruding pieces to form a flow path for the heating water.

According to the respective room control system provided with a flow restriction valve according to the present invention, a plurality of flow restriction valves are provided on the inlet side of each valve to limit the maximum supply amount of the heating water to a predetermined value or less regardless of the supply pressure of the heating water. Even if the heating is stopped in some of the rooms and only the remaining rooms are heated, the cavitation is suppressed by preventing the concentrated water from being supplied to the heating room, thereby preventing the occurrence of noise in the heating pipe. The heating cost is reduced in proportion to the flow rate supplied to the room where the heating is stopped.

According to the flow restriction valve according to the present invention, since the flow restriction valve can be manufactured through a simple configuration consisting of a valve body integrally formed by injection molding and an elastic member inserted therein, the unit price of the product can be lowered. In addition to the economic benefits, it is possible to simplify the configuration of each room control system for limiting the maximum amount of heating water supplied to each room valve.

1 is a block diagram of each control system with a flow restriction valve according to the present invention,
Figure 2 is an installation state showing a state that the flow restriction valve according to the invention is provided on the inlet side of each valve,
3 is a graph showing the relationship between the supply pressure of the heating water and the amount of heating water passing through each valve in each control system equipped with a flow restriction valve according to the present invention;
4 is a perspective view of a flow restriction valve according to the present invention;
Fig. 5 is an exploded perspective view of Fig. 4,
6 is a plan view of FIG. 4;
7 is a bottom view of FIG. 4,
8 and 9 are cross-sectional views taken along line AA of FIG. 6 showing an operating state of a flow restriction valve according to a change in heating water supply pressure.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Figure 1 is a block diagram of a control system with a flow restriction valve according to the present invention, Figure 2 is an installation state showing a state in which the flow restriction valve according to the present invention is provided on the inlet side of each valve, Figure 3 It is a graph showing the relationship between the supply pressure of the heating water and the amount of heating water passing through each valve in each control system with a flow restriction valve according to the invention.

Each room control system according to the present invention, the heat source 100 for supplying the heating water, the temperature controller (200; 200a, provided in each room to set the heating temperature of each room (room 1, room 2, room n)) 200n), each of the valves 300 (300a, 300n) for controlling the supply amount of the heating water supplied to each room according to the heating load of the respective rooms, provided in the heating water inlet side of the each valve 300, the each valve ( Control unit 500 for controlling the driving of the respective valves 300 by receiving a signal set in the flow rate limiting valve (400; 400a, 400n) and the temperature controller 200 to limit the maximum amount of the heating water supplied to 300 ).

The heat source 100 may be an individual boiler, may be centralized or collective heating, the heating water heated in the heat source 100 is supplied to each room to be heated along the heating water supply pipe (1) After the heat exchange in each room, the heating water is returned to the heat source 100 along the heating water return pipe (2).

The signal set by the temperature controller 200 is connected to be input to the control unit 500, and the control unit 500 receives the signal of the temperature controller 200 to control the driving of each valve 300. The opening amount of 300 is adjusted.

The temperature controller 200 is to enable the boiler user to set the desired room temperature, the heating operation and the heating stop is made according to whether the current room temperature has reached the set room temperature.

In this case, the opening degree of opening each valve 300 is determined by the heating load. Here, the heating load means the amount of heat required in each room that requires heating, and may vary depending on the size of the room, the length of the pipe according to the heating, the heating operation set by the user, and the desired room temperature. That is, the heating load becomes zero (0) in the room where the user stops heating, and in the case of the room set to perform heating, when the room temperature set by the user is high, a large amount of heating water must be supplied. Is opened a lot, and if the room temperature set by the user is relatively low, since only a small amount of heating water is supplied, each valve 300 is controlled to open small.

The angular valve 300, as shown in Figure 2 is composed of a valve driver 310, the valve body 320 and the body 330.

The valve driver 310 is configured to drive the vertical movement of the valve body 320 according to a signal received from the control unit 500, although not shown, the valve driver 310 is a drive motor and its drive motor. By using the power of the valve body 320 is configured to include a power transmission means for transmitting the power of the drive motor to move up and down.

The inlet 331 of the heating water is formed on one side of the body 330, the outlet 332 of the heating water is formed on the other side, the body 330 connecting the inlet 331 and the outlet 332 The valve seat 335 for controlling the cross-sectional area of the flow path is formed on the internal flow path by the vertical movement of the valve body 320.

When the heating load is large, the control unit 500 transmits a control signal to the valve driver 310 to move the valve body 320 upwardly so as to be spaced apart from the valve seat 335. The flow path between the valves is increased to increase the flow rate of the heating water supplied to the heating pipe of the room through the outlet 332, and when the heating load is small, the valve body 320 moves downward to approach the valve seat 335. By moving, the flow path between the valve seat 335 and the valve body 320 is narrowed to reduce the flow rate of the heating water supplied through the outlet 332.

The flow restriction valve 400 is provided at the inlet 331 side of the body 330 to limit the maximum supply amount of the heating water flowing into the inlet 331.

If the user heats some of the rooms and sets the heating to be stopped in the other rooms, or the heating is stopped because the current room temperature is higher than the temperature set in the temperature controller 200 among the rooms set to be heated. If the room valve 300 of the room is closed, the supply of heating water to the corresponding room is stopped, the heating water to the room where the current room temperature is lower than the temperature set by the temperature controller 200 in the room set to perform the heating Supply is concentrated.

In this case, the flow rate of the heating water supplied to the inlet 331 of each valve 300 installed in the room is increased and the supply pressure of the heating water is also increased, due to the shanghai of the valve body 320 of each valve 300. Only the adjustment of the cross-sectional area of the flow path between the valve seat 335 and the valve body 320 does not provide the effect of the cavity phenomenon due to the increased flow rate and flow rate, and thus the noise generation and the heating cost reduction. The flow rate of the heating water is increased even if the flow rate of the valve seat 335 is limited in the state in which the flow rate flowing through the inlet 331 is increased, and the flow rate of the heating water flowing through the inlet 331 and the valve seat ( This is because there is no change in the flow rate of the heating water passing through 335 to the outlet 332.

The flow rate limiting valve 400 is a problem that occurs when the flow rate of the heating water exceeds the allowable flow rate of each room as described above by limiting the maximum supply amount of the heating water flowing into each valve 300 to a predetermined value or less; To solve them.

By providing the flow restriction valve 400 at the inlet 331 of each valve 300, the supply pressure of the heating water supplied to each room is gradually increased in the range below the predetermined pressure (P1) as shown in FIG. When the flow rate is gradually increased in proportion to the supply pressure, but even if the supply pressure of the heating water exceeds a predetermined pressure (P1) of the heating water to pass through each valve 300 to the heating pipe of each room It serves to limit the supply amount not to exceed the maximum supply amount Qmax.

The flow rate limiting valve 400 is configured to restrict the flow path of the heating water by the member deformed by the supply pressure of the heating water, and its structure is simple, and a separate control device for limiting the maximum supply amount of the heating water is unnecessary. It is characterized in that it is configured to simplify the configuration of each room control system, the following describes the configuration and operation of the flow restriction valve 400.

Figure 4 is a perspective view of the flow restriction valve according to the present invention, Figure 5 is an exploded perspective view of Figure 4, Figure 6 is a plan view of Figure 4, Figure 7 is a bottom view of Figure 4, Figures 8 and 9 of the heating water supply pressure 6 is a cross-sectional view of the AA portion showing an operating state of the flow restriction valve according to the change.

Flow restriction valve 400 according to the present invention, as shown in Figures 4 and 5, the valve body 410 formed by integral coupling by injection molding, and the inside of the valve body 410 is fitted into the heating water It is composed of an elastic member 420 for limiting the flow path of the heating water by being deformed by the supply pressure of. In the present embodiment, the elastic member 420 is composed of an O-ring of a circular cross section, but is not limited thereto, and may be configured in any shape as long as the shape is deformed by the supply pressure of the heating water to limit the cross-sectional area of the flow path. Do.

The valve body 410 has a cylindrical member 411 having a heating channel therein as shown in FIGS. 5 to 7, and a central column member 412 provided at an inner central portion of the cylindrical member 411. ) And a connecting member 413 which connects the inner surface of the cylindrical member 411 and the outer surface of the central column member 412 and is provided at regular intervals along the circumferential direction.

The elastic member 420 is inserted between the inner surface of the cylindrical member 411 and the outer surface of the central column member 412, the elastic member 420 is pushed toward the connecting member 413 when the heating water flows in. It is mounted on the upper surface of the connecting member 413.

The upper outer surface of the central pillar member 412 is provided with a departure preventing member 414 protruding at a predetermined interval along the circumferential direction to prevent the elastic member 420 from being separated out of the cylindrical member 411. Done. In the present embodiment, the separation preventing member 414 is formed at an interval of 90 ° on the outer surface of the central pillar member 412.

A space between the inner surface of the cylindrical member 411 and the outer surface of the central pillar member 412 is protruded at a predetermined interval along the circumferential direction to the outer surface of the central pillar member 412 to the lower side of the separation preventing member 414. Flow rate distribution member 415 is formed to form a flow path of the heating water so that the heating water flowing into the evenly distributed in the circumferential direction of the central column member 412.

Since the heating water is uniformly distributed in the circumferential direction by the flow rate distribution member 415 and passes through the flow rate limiting valve 400, the smooth flow of the heating water is possible, thereby reducing the generation of noise. In this embodiment, the flow rate distribution member 415 is formed at an interval of 30 ° on the outer surface of the central column member 412.

The upper end of the central column member 412 and the upper end of the separation prevention member 414 and the upper end of the flow distribution member 415 are convex in the upper direction of the inflow direction of the heating water so as to minimize fluid friction with the incoming heating water. Preferably configured.

In addition, to guide the smooth flow of heating water, the inner surface of the cylindrical member 411 is formed with guide ribs 411a protruding at regular intervals along the circumferential direction, and between the adjacent guide ribs 411a. Guide grooves 411b are formed therein. Preferably, the upper end of the guide rib 411a and the upper end of the guide groove 411b are inclined upwardly to minimize the fluid friction with the heating water.

The lower end of the guide rib 411a is formed with a protruding piece 411c protruding at a predetermined length toward the central axis of the central pillar member 412, and the central pillar member 412 also at the lower end of the guide groove 411b. Protruding piece 411d is formed to protrude toward a predetermined length, and the protruding piece 411d extending from the lower end of the guide groove 411b and the protruding piece 411c extending from the lower end of the guide rib 411a. ) Is formed to cross the step in the vertical direction to form a heating water passage hole 416 that is a flow path for the heating water passes.

In the present embodiment, the guide ribs 411a and the guide grooves 411b and the protruding pieces 411c and 411d extending from the lower ends thereof are formed at intervals of 30 ° in the circumferential direction, respectively, of the guide ribs 411a. The protruding piece 411c and the connecting member 413 extending from the lower end are formed at the same height, and the elastic member 420 is seated on the upper surface of the protruding piece 411c and the connecting member 413.

Hereinafter, the operation of the flow restriction valve 400 according to the heating water supply pressure will be described with reference to FIGS. 8 and 9.

In the low pressure state in which the supply pressure of the heating water is equal to or lower than the constant pressure P1, the elastic member 420 seated on the protruding piece 411c, as shown in FIG. The flow path is formed in a space between the outer surface of the elastic member 420 and the central column member 412 and the space between the inner surface of the elastic member 420 and the cylindrical member 411, so that the flowing water flows intact. do.

On the contrary, when the pressure of the heating water exceeds the predetermined pressure P1, as shown in FIG. 9, the elastic member 420 is deformed into a flat elliptical shape by the supply pressure of the heating water, and the heating water flows. The flow path is limited to the space between the outer surface of the elastic member 420 and the central column member 412, so that the flow path is narrow, so that the flow rate of the flowing heating water is limited to a predetermined amount or less (Qmax).

As described above, in the present invention, a flow rate limiting valve 400 is provided at the inlet side of each valve 300 installed in each room, so that when the heating is stopped in some of the plurality of rooms, the initial supply pressure of the heating water is reduced. Regardless of the amount of heating water supplied to each room to be heated, the flow rate limiting valve 400 automatically limits the supply amount to be equal to or less than the set maximum supply amount. It is possible to prevent the occurrence of noise and to reduce the heating cost in proportion to the flow rate supplied to the room is stopped heating.

1: heating water supply pipe 2: heating water return pipe
100: heat source 200,200a, 200n: temperature controller
300,300a, 300n: Each valve 310: Valve actuator
320: valve body 330: body
331: entrance 332: exit
335: Valve seat 400,400a, 400n: Flow limit valve
410: valve body 411: cylindrical member
411a: Guide rib 411b: Guide groove
411c, 411d: Protruding piece 412: Center column member
413: connecting member 414: separation preventing member
415: flow distribution member 416: heating water passage hole
420: elastic member 500: control unit

Claims (6)

A thermostat for setting a heating temperature of each room;
Each room valve for adjusting the supply amount of the heating water supplied to each room according to the heating load of each room;
A flow restriction valve provided at the heating water inlet side of each valve to limit a maximum supply amount of the heating water supplied to each valve; And
And a control unit configured to control the driving of the respective valves by receiving the signal set by the temperature controller. The method of claim 1,
The flow rate limiting valve is provided with a flow rate limiting valve, characterized in that the flow path of the heating water is limited by the elastic member that is deformed by the supply pressure of the heating water supplied to the respective valves. A cylindrical member formed therein with a flow path for heating water, a central pillar member provided at an inner central portion of the cylindrical member, and an inner surface of the cylindrical member and an outer surface of the central pillar member, at regular intervals along the circumferential direction. A valve body having a connection member provided integrally therewith; And
An elastic member provided between an inner surface of the cylindrical member and an outer surface of the central pillar member to deform by a supply pressure of heating water to restrict a flow path of heating water;
Flow restriction valve comprising a. The method of claim 3,
The upper limit surface of the central column member protrudes at a predetermined interval along the circumferential direction flow restriction valve for preventing the elastic member from being separated out of the cylindrical member integrally formed. The method of claim 3,
A flow distribution member for forming a flow path of the heating water is integrally formed on the outer surface of the central column member so that the heating water protruded at regular intervals along the circumferential direction is uniformly distributed in the circumferential direction of the central column member. Flow restriction valve. The method of claim 3,
Guide ribs protruding at regular intervals along the circumferential direction are integrally formed on the inner surface of the cylindrical member, and guide grooves are formed between the adjacent guide ribs, and a lower end of the guide rib and a lower end of the guide groove are formed at the center. Each of the protruding pieces protruding toward the pillar member is integrally formed, and a step is vertically formed between the adjacent protruding pieces to form a flow path for the heating water.

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