KR20140033564A - Pumping device - Google Patents

Abstract

Provided is a pumping apparatus which comprises: a main pump having an inlet part and an outlet part, and having a rotor mounted therein and able to rotate; an actuation generating part connected to the rotor and generating a rotational actuating force for rotating the rotor; a lubricant control feeding part installed to be connected to the main pump and selectively feeding a lubricant to the inside of the inlet part according to whether or not a fluid flows through the inlet part; and an actuation control part installed to be connected to the main pump and the actuation generating part, and controlling the rotational actuation of the rotor by selectively connecting the actuation generating part and the rotor according to the pressure volume of the fluid at the outlet part. The pumping apparatus according to the present invention has the lubricant control feeding part which selectively and automatically feeds the lubricant to the inside of the inlet part according to whether or not the fluid flows through the inlet part of the main pump. The actuation control part automatically controls the actuation of the rotor by selectively connecting the actuation generating part and the rotor according to the pressure volume of the fluid at the outlet part of the main pump.

Description

[0001] Pumping device [0002]

The present invention relates to a pumping apparatus, and more particularly, to a pumping apparatus for sucking and discharging a fluid.

Generally, a pump is a device that receives power from a driving means such as a motor or an engine and starts and transfers the fluid. Such a pump is distinguished from a cost-effective pump in which the energy conversion takes place in an unsealed state, and a positive displacement pump in which energy is switched in a sealed state. The cost-effective pump reduces the discharge pressure as the discharge amount increases, and the displacement type pump maintains the discharge amount approximately constant regardless of the load pressure. Here, the volume pump is mainly composed of a rotary type volumetric pump that sucks and discharges a fixed amount of fluid while rotating the rotor in the casing by the driving means.

The applicant of the present invention has proposed this rotary volume type pump in Korean Patent Laid-Open Publication No. 10-2012-0079243.

However, since the rotary type volumetric pump of the prior art can not control the supply of the lubricating water to the inside of the volumetric pump, there is a problem that when the volumetric pump is driven once, the lubricating water inside the lubricating tank is exhausted.

In addition, when the operator moves the position of the displacement pump in a state in which the outlet of the displacement pump is hermetically closed due to the manual operation of the drive means for driving the displacement pump by manual operation, the drive means is stopped There is a problem that the pressure inside the volume pump increases and the pump may be damaged.

It is an object of the present invention to provide a pumping device which can automatically control the operation of the driving means in accordance with the supply of lubricating water into the pump and the pressure of the discharged fluid.

The main pump includes an inlet portion and an outlet portion. The main pump includes a rotating rotor rotatably mounted therein. The driving pump includes a drive generating portion connected to the rotating rotor to generate a rotational driving force to rotate the rotating rotor, A lubricating water control unit connected to the main pump and selectively supplying lubricating water into the inlet unit according to whether the fluid flows through the inlet unit, a lubricating water control unit connected to the main pump and the driving generating unit, And a drive control unit for controlling rotation of the rotation rotor while selectively connecting the drive generation unit and the rotation rotor according to the fluid pressure magnitude.

In addition, the lubricating water control and supply unit allows the lubricating water to be supplied into the inlet portion before the flow of the fluid is generated into the main pump through the inlet portion, The supply of the lubricating water to the inside of the inlet portion can be cut off.

The drive control unit may stop the operation of the main pump by interrupting the connection between the drive generation unit and the main pump when the fluid pressure magnitude at the outlet unit is greater than the maximum pressure input, When the fluid pressure is smaller than the input minimum pressure, the drive generating unit and the main pump may be reconnected to operate the main pump.

The lubrication water control and supply unit may include a storage tank connected to an inlet of the main pump in a state where the lubricating water is stored, and a lubricant control unit installed inside the inlet of the main pump, A flow sensor connected to the storage tank for receiving a signal from the flow sensor and operating only when the flow of the fluid into the main pump through the inlet does not occur, And a lubricating water supply pump for allowing the lubricating water to be discharged and moved into the inlet portion of the main pump.

The lubrication water control supply unit is connected to the lubricating water supply pump in a state where it is provided between the main pump and the storage tank so that the lubricating water of the storage tank is opened only at the operation of the lubricating water supply pump, And a control valve that allows the liquid to be supplied to the inside of the unit.

The controller may further include a water level sensor provided at an inner lower end of the storage water tank for sensing when the lubricant water stored in the storage water tank becomes low.

The drive control unit may include an electromagnetic clutch connected to the drive generation unit and connected to the electromagnetic clutch in a state of being installed at an outlet of the main pump to measure the fluid pressure in the outlet unit, Wherein the fluid pressure magnitude measured at the outlet by the pressure sensor is greater than the maximum pressure of the fluid pressure measured by the pressure sensor, The drive force of the drive generating portion is blocked from being transmitted to the main pump by the operation of the electromagnetic clutch, and when the fluid pressure magnitude measured at the outlet by the pressure sensor is smaller than the minimum pressure value The drive force of the drive generating portion can be transmitted to the main pump by the operation of the electromagnetic clutch have.

The pumping device according to the present invention automatically and selectively supplies the lubricating water to the inside of the inlet depending on whether the fluid flows through the inlet of the main pump in the lubricating water control supply part, Accordingly, it is possible to automatically control the driving of the rotating rotor while selectively connecting the driving generating part and the rotating rotor of the main pump.

1 is a schematic configuration diagram of a pumping apparatus according to an embodiment of the present invention.
2 is a perspective view of a pumping apparatus according to an embodiment of the present invention.
Figure 3 is a side view of Figure 2;
4 is a front view of Fig.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings.

2 is a perspective view of a pumping apparatus according to an embodiment of the present invention, FIG. 3 is a side view of FIG. 2, and FIG. 4 is a cross-sectional view of a pumping apparatus according to an embodiment of the present invention. FIG. 1 to 4, the pumping apparatus includes a main pump 100, a drive generation unit 200, a lubricant control unit 300, and a drive control unit 400.

The main pump 100 receives the rotational driving force from the drive generating unit 200 to be described later, sucks the fluid, and discharges the fluid to the discharging position again. The main pump 100 has a known rotary volume pump structure. That is, the main pump 100 includes a housing 110 having an inlet 111 and an outlet 112 communicating with the space 101 in a state having a space 101 inside, And a rotating rotor 120 rotatably installed in the space portion 101 of the housing 110. The inlet portion 111 guides the fluid to the inside of the space portion 101 and the outlet portion 112 flows into the space portion 101, And guides the fluid to be discharged to the outside of the housing 110 by rotation. The shaft end portion of the rotation rotor 120 is connected to the drive generation portion 200 to be described later and is rotated on the space portion 101 of the housing 100 according to the driving of the drive generation portion 200 A pump pulley 130 is mounted on a shaft end of the rotating rotor 120 to receive a rotational driving force generated from the driving generating part 200 by a driving belt 230.

The lubrication control unit 300 is connected to the inlet portion 111 of the housing 110 so that lubricating water can be supplied to the inlet portion 111 from the lubricating control unit 300 An inflow hole (not shown) is formed to pass through.

The drive generating unit 200 generates a rotational driving force to rotate the rotating rotor 120 of the main pump 100. That is, while the driving generating part 200 is rotated in the housing 110 of the main pump 100 while the rotating rotor 120 is connected to the rotating rotor 120 of the main pump 100, And allows the fluid to be introduced into the housing 110 of the main pump 100 through the inlet portion 111 and discharged through the outlet portion 112 under a predetermined pressure. The driving unit 200 may be a motor, a motor, or the like. The driving force generated by the driving force generating unit 200 is transmitted to the rotating rotor 120 of the main pump 100 through the driving belt 230, And can be transmitted to the main pump 100 by being connected to the mounted pump pulley 130. In the embodiment, the belt and the pulley are selectively applied to transmit the rotational driving force between the drive generating part 200 and the rotating rotor 120 of the main pump 100. However, the present invention is not limited thereto, Needless to say, it is also possible to have a known direct coupling structure by gears.

The lubricant control supply unit 300 may be connected to the inlet portion 111 of the main pump 100 before the fluid is introduced into the main pump 100 or before the flow of the fluid through the inlet portion 111 occurs. ). That is, the lubricant control and supply unit 300 controls the rotation of the rotation rotor 120 of the main pump 100 so that the fluid is supplied to the housing 110 of the main pump 100 before the fluid is introduced into the main pump 100. [ So that the lubricating and partitioning functions can be carried out together by impregnating between the inner surface and the rotating rotor 120. When the fluid flows into the main pump 100, that is, when the flow of the fluid through the inlet 111 is generated, the lubricant control and supply unit 300 controls the inlet 111 of the main pump 100, Thereby preventing the supply of lubricating water to the inside. The lubricant control supply unit 300 is connected to the inside of the inlet 111 of the main pump 100. The lubricant control and supply unit 300 includes a storage tank 310, a flow sensor 320, and a lubricated water supply pump 330.

The storage tank 310 is a tubular member for storing the lubricant to be supplied into the inlet 111 of the main pump 100. One side of the storage tank 310 is connected to the inlet 111 of the main pump 100 through a connection line 311. Here, a water level sensor 312 may be installed at an inner lower side of the storage tank 310 to sense when the lubricating water is discharged into the inlet portion 111 of the main pump 100 and becomes low. The water level sensor 312 is connected to the electromagnetic clutch 410 of the drive control unit 400 to be described later so that when the lubricated water storage state of the storage water tank 310 becomes low, So as to block transmission of rotational driving force to the rotating rotor 120 of the main pump 100 by the drive generating unit 200. [

The flow sensor 320 senses whether the lubricating water flows in the inlet 111 of the main pump 100 and then controls the operation of the lubricating water supplying pump 330. The flow sensor 320 is installed inside the inlet 111 of the main pump 100 and is electrically connected to the lubricant supply pump 330. The flow sensor 320 is connected to the lubricant supply pump 330, And controls the operation of the lubricating water supply pump 330. [0050] That is, when there is no flow of the lubricating water in the inlet 111 of the main pump 100, the flow sensor 320 maintains the operating state of the lubricating water supply pump 330, So that the lubricating water can be supplied to the inside of the inlet portion 111. In contrast, when the flow of the lubricating water occurs in the inlet 111 of the main pump 100, the flow sensor 320 transmits a signal generated while operating, to the lubricating water supply pump 330, The operation of the supply pump 330 is stopped, and the lubricating water is prevented from being supplied from the storing water tank 310 into the inlet portion 111.

The lubricating water supply pump 330 generates a moving pressure so that the lubricating water stored in the storage tank 310 can be supplied to the inlet 111 of the main pump 100. The inlet side of the lubricated water supply pump 330 is connected to the outlet side of the storage tank 310 and the outlet side of the lubricated water supply pump 330 is connected to the connection line 311, 100, respectively. The lubricant supply pump 330 is electrically connected to the flow sensor 320 as described above so that the flow of the fluid from the flow sensor 320 to the inside of the inlet portion 111 of the main pump 100, The operation is stopped.

A control valve for controlling the lubricating water of the reservoir tank 310 to be supplied into the inlet portion 111 of the main pump 100 only when the lubricating water supply pump 330 is operated, (340). The control valve 340 is electrically connected to the lubricating water supply pump 330 while being installed between the inlet 111 of the main pump 100 and the storage water tank 310. That is, in one embodiment, the inlet side of the control valve 340 is connected to the end of the connection line 311 connected to the storage tank 310, the lubricating water is supplied from the lubricating water supply pump 330, The lubricating water connected to the inlet hole formed in the housing 110 of the main pump 100 is installed so as to be introduced into the inlet portion 111 of the main pump 100. The control valve 340 opens the flow path between the connection line 311 and the inlet 111 of the main pump 100 while operating the lubricating water supply pump 330, To be introduced into the inlet portion (111) of the pump (100). On the other hand, when the operation of the lubricating water supply pump 330 is stopped, the control valve 340 closes the flow path between the connection line 311 and the inlet portion 111 of the main pump 100, Thereby blocking the supply of the lubricating water to the inside of the inlet portion 111 of the oil pan 100. The control valve 340 is preferably adapted to selectively apply a solenoid valve that opens and closes the flow path by receiving an electric signal depending on whether the lubricating water supply pump 330 is operated. However, the present invention is not limited thereto.

The drive control unit 400 adjusts whether or not the drive generating unit 200 and the rotating rotor 120 are connected to each other according to the magnitude of the fluid pressure at the outlet 112 of the main pump 100, Thereby controlling the rotational driving of the rotor 120. That is, the drive controller 400 selectively rotates the rotating rotor 120 according to the magnitude of the fluid pressure at the outlet 112 of the main pump 100. When the fluid pressure in the outlet 112 of the main pump 100 is greater than the maximum pressure, the drive controller 400 controls the drive generator 200 and the main pump 100, The driving connection is cut off so that the rotating rotor 120 of the main pump 100 is stopped. In contrast, when the fluid pressure in the outlet 112 of the main pump 100 becomes smaller than the minimum pressure, the drive control unit 400 controls the drive generation unit 200 and the main pump 100, So that the rotating rotor 120 of the main pump 100 is operated. Here, the drive control unit 400 includes an electromagnetic clutch 410 and a pressure sensor 420.

The electromagnetic clutch 410 is connected to the drive generator 200 and the main pump 100 in accordance with the fluid pressure magnitude at the outlet 112 of the main pump 100 measured by the pressure sensor 420. [ Thereby making it possible to selectively connect. The electromagnetic clutch 410 is electrically connected to the pressure sensor 420 while being connected to the drive shaft 210 of the drive generating unit 200.

The pressure sensor 420 is a sensor for measuring the fluid pressure inside the outlet portion 112. The pressure sensor 420 is electrically connected to the electromagnetic clutch 410 while being installed at the outlet 112 of the main pump 100. Here, the maximum pressure value and the minimum pressure value of the fluid for selectively drivingly connecting or disconnecting the drive generation unit 200 and the main pump 100 are input to the pressure sensor 420. Therefore, when the magnitude of the fluid pressure in the outlet 112 measured by the pressure sensor 420 is greater than the input maximum pressure, the drive connection of the drive generator 200 and the main pump 100 is interrupted Thereby stopping the rotational operation of the rotating rotor 120 of the main pump 100. When the fluid pressure in the outlet 112 measured by the pressure sensor 420 becomes smaller than the input minimum pressure, the drive generator 200 and the main pump 100 are driven again, So that the rotating rotor 120 of the main pump 100 can be rotated.

The operation of the pumping apparatus according to one embodiment of the present invention will now be described with reference to FIGS. 1 to 4. FIG.

First, the lubricating water supply pump 330 of the lubricating water control and supply unit 300 and the drive generation unit 200 are sequentially operated. The lubricating water stored in the storage tank 310 is guided to the connection line 311 through the lubricating water supply pump 330 and supplied to the inlet 111 of the main pump 100, And is impregnated between the inner surface of the housing 110 of the main pump 100 and the rotating rotor 120.

When the fluid is introduced into the main pump 100 through the inlet 111 of the main pump 100 while the rotating rotor 120 of the main pump 100 is rotated by the drive generator 200, The flow sensor 320 of the supply unit 300 senses the flow of the fluid and transmits a signal to the lubricated water supply pump 330 to stop the operation of the lubricated water supply pump 330, Thereby blocking the supply of the lubricating water to the inside of the inlet portion 111.

The fluid introduced through the inlet portion 111 of the main pump 100 is moved to the discharge port 112 by the rotating rotor 120 rotating and then discharged to the outside.

The driving unit 200 rotates the rotating rotor 120 of the main pump 100 so that the outlet 112 of the main pump 100 is closed When the fluid pressure in the outlet portion 112 of the main pump 100 is greater than the maximum pressure value of the pressure sensor 420 when the pumping device is moved, The rotation driving force generated in the main pump 200 is prevented from being transmitted to the rotating rotor 120 of the main pump 100, thereby preventing the main pump 100 from generating a safety accident such as an explosion. In the meantime, when the rotational driving force generated in the driving generating part 200 is blocked from being transmitted to the rotating rotor 120 of the main pump 100, When the fluid pressure becomes smaller than the minimum pressure value of the pressure sensor 420, the electromagnetic clutch 410 again transmits the rotational driving force generated in the driving generating portion 200 to the rotating rotor 120 of the main pump 100, So that the fluid can be jetted and discharged at a predetermined pressure or more in a state where the outlet 112 of the main pump 100 is opened. That is, when the fluid pressure in the outlet 112 of the main pump 100 is greater than 20 bar in a state where the maximum pressure value is 20 bar and the minimum pressure value is 5 b, The rotation drive force generated in the drive generating part 200 is blocked from being transmitted to the rotation rotor 120 of the main pump 100 and the rotation of the rotation rotor 120 is stopped. If the fluid pressure in the outlet part 112 of the main pump 100 is less than 5 bar, the rotational driving force generated in the driving generating part 200 is transmitted to the rotating rotor 120 of the main pump 100 So that the fluid pressure inside the outlet portion 112 of the main pump 100 is increased by the rotational driving of the rotating rotor 120.

The drive control unit 400 controls the driving unit 200 according to the pressure of the outlet 112 in a state where the discharge or discharge of the fluid through the outlet 112 of the main pump 100 is stopped. The main pump 100 and the main pump 100 are connected to the main pump 100 and the main pump 100 so that the driving force of the main pump 100 is selectively transmitted to the rotating rotor 120 of the main pump 100, 112 can be automatically controlled to maintain the fluid pressure within a certain range.

As described above, the pumping device according to an embodiment of the present invention is configured such that, in the lubricating water control supply part 300, the lubricating oil is supplied to the inside of the inlet part 111 according to whether the fluid flows through the inlet part 111 of the main pump 100 The drive control unit 400 can automatically supply the drive generation unit 200 and the main pump 100 according to the magnitude of the fluid pressure at the outlet part 112 of the main pump 100, The rotation of the rotating rotor 120 can be automatically controlled while the rotating rotor 120 of the rotor 120 is selectively connected.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

100: main pump 110: housing
111: inlet part 112:
120: Rotating rotor 200: Drive generating part
300: lubricating water control supply unit 310: storage tank
320: Flow sensor 330: Lubrication pump
340: control valve 400: drive control unit
410: electromagnetic clutch 420: pressure sensor

Claims (7)

A main pump having an inlet portion and an outlet portion formed therein and having a rotating rotor rotatably mounted therein;
A driving generator connected to the rotating rotor to generate a rotational driving force to rotate the rotating rotor;
A lubricating water control unit connected to the main pump and selectively supplying lubricating water into the inlet unit according to whether the fluid flows through the inlet unit; And
A drive control unit connected to the main pump and the drive generation unit to control the rotational drive of the rotary rotor while selectively connecting the drive generation unit and the rotary rotor according to the fluid pressure at the outlet; Pumping device comprising. The method according to claim 1,
The lubricating oil control supply unit
And the lubricating water is supplied into the inlet portion before the flow of the fluid is generated into the main pump through the inlet portion,
Wherein the supply of lubricating water to the interior of the inlet portion is blocked when the fluid flow through the inlet portion into the main pump occurs. The method according to claim 1,
The drive control unit may include:
When the magnitude of the fluid pressure at the outlet is larger than the input maximum pressure, the connection between the drive generating unit and the main pump is cut off to stop the operation of the main pump,
And when the fluid pressure magnitude at the outlet portion becomes smaller than the input minimum pressure, the drive generating portion and the main pump are reconnected to cause the main pump to operate. The method according to claim 1 or 2,
The lubricating oil control supply unit
A storage tank connected to the inlet of the main pump in a state where the lubricating water is stored,
A flow sensor installed inside the inlet of the main pump for sensing whether the fluid flows into the main pump through the inlet,
Wherein the main pump is connected to the storage tank and operates only when the flow of the fluid from the flow sensor to the main pump through the inlet does not occur, And a lubricating water supply pump for causing the lubricating oil to be discharged to the inside. The method of claim 4,
The lubricating oil control supply unit
Wherein the lubricating water supply pump is connected to the lubricating water supply pump in a state where it is installed between the main pump and the storage tank so that the lubricating water of the storage tank can be supplied into the inlet of the main pump Further comprising a control valve. The method according to claim 4 or 5,
And a water level sensor installed at an inner lower end of the storage water tank for sensing when the lubricating water stored in the storage water tank becomes low in water level. The method according to claim 1 or 3,
The drive control unit may include:
An electromagnetic clutch connected to the drive generating portion,
A main fluid pump connected to the electromagnetic clutch in a state of being installed at an outlet of the main pump to measure the fluid pressure inside the outlet, Including a pressure sensor to which a fluid pressure value is input,
When the fluid pressure magnitude measured at the outlet by the pressure sensor is larger than the maximum pressure value, the drive force of the drive generating portion is blocked from being transmitted to the main pump by the operation of the electromagnetic clutch,
Wherein the drive force of the drive generation portion is transmitted to the main pump by the operation of the electromagnetic clutch when the fluid pressure magnitude measured at the outlet by the pressure sensor is smaller than the minimum pressure value.

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