KR101251387B1 - Pump control unit - Google Patents

Abstract

PURPOSE: A device for controlling the pressure of an outlet of a pump is provided to reduce the energy consumption by reducing the flow rate, thereby obtaining the reduced energy consumption of an inverter. CONSTITUTION: A device(100) for controlling the pressure of an outlet of a pump comprises a valve(130), a casing(110), a shaft(123), an actuating disc(120), an operation pressure setting unit(140), a fluid path(124), and a hydraulic pressure generating pipe(151). The valve is installed in a recovering pipe connecting an inlet or an outlet, thereby opening or closing the same. The casing is arranged in the upper part of the valve. The shaft is extended inside of the casing by being protruded for operating the valve. The actuating disc is fixed in the upper end of the shaft, thereby being rotated. The operation pressure setting unit obtains a reaction force of the other side of the actuating disc by a compressive spring(144).

Description

Pump outlet pressure control unit {Pump control unit}

The present invention relates to a control device for a pump, and more particularly, to a control device for adjusting the pressure at the discharge port side of the pump does not exceed a predetermined range.

The pump rotates the blade of the pump by the rotational speed (RPM) of the motor and flows the fluid in the rotational direction. The rotation of the motor rotates according to the supply of the power source, and the speed of the pump is determined by the rotational speed of the motor. Rotate Therefore, if the power supply frequency is 60hz and the number of poles of the motor is two poles, it rotates at 3,600rpm. At this time, the pump supplies 100% flow rate.

At the same time as all pumps start up, the pump discharges the flow rate according to the pump's performance.When using less than the flow rate of the pump at the discharge side, the pumping speed and volume are controlled by controlling the pump speed through electric control method and electronic control. Use accordingly.

However, when the electronic control is not able to change speed due to a fault and cannot function, 100% start-up is used by direct start method. As a result, the actual usage is 70% and the supply amount is 100%, resulting in over 30%. This causes the discharge port to be used under high pressure.

Therefore, to solve this problem, the pump is stopped by using an electrical pressure switch, and when the pressure of the pipe goes down, the pump is restarted by the pressure switch again. This frequency is operated like lightning by turning the pump off and on at high speed. As a result of high pressure shock, piping play occurs, and the flow of water and the change of supply water do not match the ratio of hot water and cold water, which has a great influence on refrigerating equipment and other shower facilities. Also remains a disadvantage.

In other words, all pumps have inherent performance and use pressure and flow rate within the range of performance. Piping and equipment may be damaged due to the capacity of each place and equipment.

The present invention has been made to solve the above problems, it was set as the basic conditions of the invention that all problems are solved if the process of using the pump to use the fluid is the same amount.

Therefore, even if the pump used by controlling the pump speed by varying the electric speed only causes the electronic system to fail, or by using the indirect start method, which is not variable, the pump can be used to control the flow and pressure. As a technique for smoothing the supply, the inventor of the present invention intends to introduce an acting invention of controlling pressure and flow rate by a mechanical device.

60% of the time is used in a facility where the pump's maximum pressure performance is 100% and only 80% of the facilities of the user are used. Is seriously damaged. At this time, the mechanical safety device is to provide a device that allows the mechanical pressure control to be variable according to the amount of use less than 70% while controlling the mechanical pressure not exceeding the first safety range 70%.

This applies not only to single pumps, but also to conduits that use booster pumps in combination. The normal operating limits of the electronically operated electronic system controls are used below the mechanical safety shutoff setting, and below the mechanically set pressure, the pump's inherent flow capacity can be used.

According to the present invention, the pressure and the flow rate can be simultaneously adjusted according to the function of the high pressure safety shutoff device and the use flow rate, thereby protecting the safety of the facility and enabling the smooth use in emergency even in places where drinking water is used.

The present invention to solve the above problems,

A valve installed in the input pipe of the pump or a recovery pipe connecting the discharge pipe and the input pipe of the pump to open and close the pump;

A casing disposed above the valve;

A shaft protruding to manipulate the valve and extending into the casing;

An operating disk fixed to the upper end of the shaft to be rotatable;

An operating pressure setting unit for allowing the other side of the working disk to have a reaction force by the compression spring;

A flow passage communicating with one side of the working disk in an arc shape to an adjacent working pressure setting part so as to have the same center as the center of rotation of the working disk; And

And a hydraulic pressure generating pipe connected to the pressure check pipe branched from the discharge pipe and extending into the flow path.

At this time, the operating pressure setting portion is a rod hinged to the other side of the working disk, a housing fixed on the side of the casing so that the rod is inserted, a compression spring inserted between the housing and the rod to elastically support the rod, the housing and It includes a control lever for adjusting the pressure of the rod to set the pressure of the compression spring.

In addition, the working disk has a semi-circular shape, the operating pressure setting portion is coupled to the other side of the straight section of the working disk, it is preferable that the flow path is formed from one side to the other side of the straight section.

And the bottom surface of the casing is formed with a vent hole and a vent valve can be connected to the inlet pipe side.

The control device according to the present invention can be used by limiting the maximum performance of the fixed rotary pump can meet the function of the inverter to convert the speed used.

In the method of adjusting the flow rate of the pump inlet, the power consumption decreases as the flow rate decreases, thereby reducing the power when the inverter is used.

By adjusting the pressure in the pipe by using the force of the direct pressure of the pipe in the situation that the pump rotation is fixed, in response to the pressure change immediately recovers the flow rate of the discharge part when the high pressure of the pump occurs and re-supply to the inlet pump inlet, or In the method of adjusting the inflow rate, the amount of discharged is immediately reduced because the inflow rate is controlled to reduce the pressure of the discharge part, so that the effect can be obtained at the same time as a safety valve of high pressure.

When the limited pressure is exceeded by limiting the pressure of the discharge pipe, the excess flow is flowed back into the recovery pipe so that it can function as an emergency safety valve of pressure, and it can be used for booster pump system that combines several pumps. Using the Inverter The inverter fails and the speed cannot be changed. When the direct pump is only running, the unbalanced operation of the pump turning off and turning on again due to the excessive pressure increase results in a failure to supply smooth drinking water. Even without mechanically, the flow rate is variable and pressure control can be satisfied.

As it is applied to the conduit of the booster pump system, it has the effect of completely eliminating the critical high pressure safety device of the system.

Even without special electronic control, all pressurized pumps can be used by adjusting the flow rate and pressure even when the rotation is fixed, thereby reducing the cost, making it easy to use, and without the risk of malfunction.

1 is a view showing a pump inlet flow rate adjustment method installed with a control device according to the present invention,
2 is a view showing the flow rate recovery method of the pump discharge unit is installed control device according to the present invention,
3 is a view showing in detail the control device according to the invention, and
4 is a view showing an operation of the control device according to the present invention.

Hereinafter, an outlet pressure control apparatus of a pump according to a preferred embodiment of the present invention with reference to the accompanying drawings.

The outlet pressure control device of the pump according to the present invention may be installed in two forms. First, as shown in Figure 1, the control device 100 is installed in the input pipe 10 of the pump (P), the pump inlet to open and close the input pipe 10 in accordance with the pressure of the discharge pipe (20) It is a sub flow control method. Second, as shown in FIG. 2, the control device 100 is installed in the discharge pipe 20. The fluid in the discharge pipe 20 is returned to the input pipe 10 side according to the pressure of the discharge pipe 20. Rotation is a pump discharge part flow recovery method.

In the pump inlet flow rate adjusting method of FIG. 1, when a pressure exceeding a set pressure is applied to the discharge pipe 10, the pressure is transmitted to the control device 100, and the transferred pressure is attached to the control device 100. By turning the valve, the input pipe 10 is opened and closed. That is, when the pump operation amount is larger than the fluid usage, the pressure of the discharge pipe 20 increases, and by closing the input pipe 10 flowing into the pump P, the pressure of the discharge pipe 20 is lowered. .

In the pump discharge part flow recovery method of FIG. 2, when a pressure exceeding a set pressure is applied to the discharge pipe 20, the pressure is transmitted to the control device 100, and the transferred pressure is attached to the control device 100. The valve is turned to cause the discharge pipe 20 to communicate with the input pipe 10. That is, when the pump operation amount is larger than the fluid usage, the pressure of the discharge pipe 20 increases, and by opening the discharge pipe 20 to the inlet pipe 10, the pressure of the discharge pipe 20 is lowered. . Accordingly, the recovery pipe 30 is further formed from the discharge pipe 20 to the input pipe 10 side, and the control device 100 is installed in the recovery pipe 30.

Hereinafter, the pump outlet pressure control device 100 as described above will be described in detail.

Referring to FIG. 3, the pump outlet pressure control device 100 according to the present invention includes a casing 110, a working disk 120 rotated according to the hydraulic pressure delivered to the casing 110, and the working disk. It is configured to include a valve 130 for rotating together to open and close the desired pipe in accordance with the rotation of 120, and an operating pressure setting unit 140 for setting the rotational reaction force of the operating disk 120.

First, the working disk 120 embedded in the casing 110 has a semicircular shape, and the working disk 120 is horizontally disposed in the casing 110, and the shaft 123 is located at the center of the working disk 120. Is coupled to extend through the lower surface of the casing 110 to the valve 130. That is, the shaft 123 serves to transmit the rotational force of the operating disk 120 to the valve 130, the valve 130 while the valve sphere 131 of the valve 130 is rotated by the rotation of the shaft 123 Will open and close. The operating disk 120 may be fixed to the upper portion of the casing 110 through the operating disk 120, the upper end of the shaft 123 to be fixed without shaking.

On the side of the casing 110 is formed an operating pressure setting unit 140 for providing a reaction force to the operating disk 120. The operating pressure setting unit 140 is mechanically configured by a spring, and is formed at a position facing the straight section 121 of the operating disk 120 having a semicircular shape. The operating pressure setting unit 140 includes a rod 141 coupled to the hinge 122 at the end of the straight section 121, and a housing 142 mounted on the side surface of the casing 110 to insert the rod 141. ), The compression spring 144 inserted between the rod 141 and the housing 142 so that the rod 141 is elastically supported from the housing 142, and the distance between the housing 142 and the rod 141 is reduced. It consists of an adjustment lever 143 that rotates the housing 142 to extend.

At this time, it is preferable that the control lever 143 and the housing 142 are integrated and the housing 142 is screwed to the casing 110. In addition, the casing 110, which is radially outer side of the control lever 143, is marked with a scale 145 of the pressure range to be set by the control lever 143. Accordingly, when the control lever 143 is turned in the high pressure direction, the housing 142 moves to the rod 141 side to press the compression spring 144, thereby increasing the reaction force of the compression spring 144, thereby increasing the reaction disk 120. The rotational force is further suppressed to increase the set pressure. Turning the control lever 143 in the low pressure direction, on the contrary, the rotational force is suppressed small and the set pressure is lowered.

On the side of the casing 110, an input port 150 through which the hydraulic pressure is transmitted to the operating disk 120 is formed, and the hydraulic pressure is extended from the input port 150 through the inside of the casing 110 into the working disk 120. The tube 151 is formed. The input port 150 is where the pressure check pipe 40 branched from the discharge pipe 20 of the pump P is connected. And the hydraulic generating pipe 151 has a function to be the driving force to rotate the operating disk 120 by the fluid introduced through the pressure check tube 40 and the input port 150 to transfer the pressure to the working disk 120. To perform. Therefore, the flow path 124 into which the hydraulic generator tube 151 is inserted is formed in the working disk 120.

The flow path 124 is formed to draw one side and the other side of the straight section 121 of the operating disk 120 in an arc shape, the hinge 122 engaging portion to which the reaction force of the operating disk 120 is applied is the end thereof On the other side of the hinge 122, the engaging portion is started. And the end of the flow path 124 is closed so as not to penetrate the operating disk 120 is configured so that the input pressure is directed toward the hinge 122 coupling portion. In addition, the flow path 124 and the hydraulic generating tube 151 are formed to have the same center as the center of the working disk 120 so that there is no change in the rotation of the working disk 120.

In the control device 100 according to the present invention, the pressure exceeding the reaction force of the compression spring 144 is transmitted through the input port 150 and the hydraulic generating tube 151 in the basic state as shown in FIG. As shown in (b) of FIG. 4, the compression spring 144 is contracted while the operating disk 120 rotates to operate the valve 130 while rotating the valve sphere 131. Furthermore, if a larger pressure is continuously introduced, as shown in (c) of FIG. 4, the pushing force of the fluid is increased, so that the operating disk 120 is further returned to completely close or open the valve sphere 131.

The control device 100 of the present invention is divided into a pump inlet flow rate control method as shown in Figure 1 and a pump discharge part flow rate recovery method as shown in Figure 2, in the pump inlet flow rate control method as the pressure of the fluid increases The control device 100 is configured to close the valve 130, and in the pump discharge portion flow rate recovery method, the control device 100 is configured to open the valve 130 as the pressure of the fluid increases.

The control device 100 according to the present invention is designed to have a play in the flow path 124 and the hydraulic generating pipe 151 for free and smooth rotation of the operating disk 120, the fluid may be leaked due to this play. Can be. Therefore, it may be desirable to be configured to recover the leaked fluid to the inlet pipe 10 side through the vent hole 160 and the vent valve 161 in the lower portion of the casing 110.

In addition, the control device 100 according to the present invention is shown as being installed outside the pump separately from the pump (P) in the drawing, but may be manufactured in one unit to be integral with the pump when manufacturing the pump. That is, the control apparatus 100 may be provided in the pump P. FIG.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined by the appended claims. .

100: outlet pressure control device of the pump
10: input piping 20: discharge piping
30: recovery piping 40: pressure check pipe
110: casing 120: working disk
121: straight line 122: hinge
123: shaft 124: euro
130: valve 131: valve sphere
140: operating pressure setting unit 141: rod
142: housing 143: control lever
144: compression spring 145: scale
150: input port 151: hydraulic generating tube
160: Vant Ball 161: Vant Valve

Claims (4)

A valve 130 installed in the input pipe 10 of the pump P or the recovery pipe 30 connecting the discharge pipe 20 and the input pipe 10 of the pump P to open and close;
A casing 110 disposed above the valve 130;
A shaft 123 which protrudes to manipulate the valve 130 and extends into the casing 110;
An operation disk 120 fixed to the upper end of the shaft 123 to be rotatable;
An operating pressure setting unit 140 for allowing the other side of the working disk 120 to have a reaction force by the compression spring 144;
A flow passage 124 communicating in an arc shape to the input of the operating pressure setting unit 140 so as to have the same center as the rotation center of the operating disk 120 through one side of the operating disk 120; And
And a hydraulic pressure generating pipe 151 connected to the pressure check pipe 40 branched from the discharge pipe 20 of the pump P and extending into the flow path 124. Control unit. The method of claim 1, wherein the operating pressure setting unit 140,
A rod 141 coupled to the hinge 122 at the other side of the working disk 120;
A housing 142 fixed on the side of the casing 110 so that the rod 141 is inserted therein;
A compression spring 144 inserted between the housing 142 and the rod 141 to elastically support the rod 141;
And a control lever (143) for setting the pressure of the compression spring (144) by adjusting the distance between the housing (142) and the rod (141). 3. The method according to claim 1 or 2,
The working disk 120 has a semicircular shape, the working pressure setting unit 140 is coupled to the other side of the straight section 121 of the working disk 120, the one side to the other side of the straight section 121 Discharge port pressure control device of the pump, characterized in that the flow path (124) is formed. The method of claim 3, wherein
The vent hole 160 of the pump, characterized in that the vent hole 160 and the vent valve 161 is formed on the bottom surface of the casing 110 is connected to the inlet pipe 10 side.

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