KR101861970B1 - A Vacium Self-priming Pump - Google Patents

Abstract

The present invention provides a vacuum self-priming pump to facilitate re-work by facilitating initialization after a fluid is pumped. The vacuum self-priming pump includes: a motor; a housing having a chamber disposed therein with an impeller rotatably connected to a rotating shaft of the motor, an inlet engaged with an inlet pipe to receive the fluid into the chamber, and an outlet through which the fluid is discharged from the chamber; an air discharge pipe in which air remaining in the inlet, the inlet pipe, and the chamber moves; a vacuum mechanism for discharging the air moving through the air discharge pipe to the outside; a control mechanism receiving power from a power supply unit through preset data to control drives of the motor and the vacuum mechanism; and an air blocking mechanism having a main blocking member and an auxiliary blocking member provided in the air discharge pipe to open and close an air discharge passage of the air discharge pipe.

Description

[0001] The present invention relates to a vacuum self-priming pump,

The present invention relates to a vacuum strong suction pump for improving the structure of a vacuum strong suction pump of Korean Patent Registration No. 10-791044 proposed by the applicant of the present invention. More specifically, So that the reworking can be facilitated.

Generally, a pump is a device that pumps the fluid upward to forcibly move the fluid when the fluid is below the discharge port, and is used to move or circulate the fluid.

In this case, the pump needs to be fully filled with water in the chamber at the beginning of operation, so that the pump can be properly operated. In the past, by using another pump or a water- The air inside the chamber is evacuated to a vacuum state, and the water is filled in.

However, in the conventional pump and the water-sealed vacuum pump, when water containing a lot of sludge is pumped, it is necessary to initially fill the inside of the chamber with water.

That is, when air is left in the chamber, the vacuum pump is not properly operated and the workability is poor.

The applicant of the present invention has proposed a vacuum pump for sucking a fluid in a vacuum state by forming the inside of the chamber in a vacuum state without initially being filled with water in order to solve the above-mentioned conventional problems .

[0004] As described above, the vacuum force pulling pump proposed by the present applicant is Korean Patent Registration No. 10-791044 (name: vacuum force pulling pump). The vacuum pulling force pump is, as known in the art, And an air discharge means for discharging the air in the pumping chamber to the outside is provided and a one-way check valve is installed to prevent the fluid from flowing back to the discharge port of the pumping chamber, By forcibly discharging the fluid to the outside to generate a pressure difference, it is possible to more easily move the fluid pumped by the motor, thereby shortening the working time and minimizing the power consumption, thereby improving the efficiency of the work.

1. Korean Patent Registration No. 10-791044

However, in the vacuum pump of Korean Patent No. 10-791044 proposed by the applicant of the present invention as described above, the discharge port through which the air in the chamber is discharged during the operation of the vacuum pump of the fluid is blocked or adsorbed by the flowing fluid So that the pump operation can not be performed stably.

As a result, after the pump of the fluid, the initialization can not proceed smoothly, and the reworking can not be performed stably.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned conventional problems, and an object of the present invention is to improve the structure of a vacuum strong suction pump of Korean Patent Registration No. 10-791044 proposed by the applicant of the present invention A vacuum suction pump for sucking air through a chamber, and a vacuum pump for sucking the fluid discharged from the chamber through a vacuum pump, So that it is possible to perform the operation stably.

In order to accomplish the above object, the present invention provides a vacuum pump for a vacuum pump, comprising: a motor; A housing having an inlet connected to the inlet pipe through which the fluid is supplied to the chamber, and an outlet through which the fluid is discharged from the chamber; An air discharge pipe through which the air remaining in the inlet, the inlet pipe, and the chamber is moved; A vacuum means for discharging the air moved through the air discharge pipe to the outside; Control means for controlling the driving of the motor and the vacuum means by receiving and controlling the power of the power supply unit through the set data; The control unit controls the supply of power by controlling the control unit, which is provided in the air discharge pipe and is configured to calculate the sensing data of the sensing unit to sense the level of the chamber, A main body which is provided at a portion located between the main blocking member and the vacuum means in the air discharge pipe and communicates with the air discharge pipe so as to move air, A floating plate provided with a shield plate which is moved according to the buoyancy of the fluid flowing into the inside of the tubular body and is prevented from being clogged by the fluid being ejected toward the outlet side of the tubular body, And an opening / closing member for opening / closing the air outlet pipe, The so as to open and close the air discharge passage blocking means; And an air discharge pipe connected to an inlet of the chamber and connected to the air discharge pipe at an upper portion thereof, the vacuum suction pump comprising: The inlet of the air discharge cylinder is located at a position higher than the maximum height of the chamber; And an auxiliary sensing sensor for sensing the level of the fluid and applying the sensed data to the control means is provided at a position of the air discharge cylinder at a level where the fluid flows in the inlet, Wherein the opening and closing member constituting the auxiliary blocking member comprises: an opening and closing plate having an upper end closed by the end portion of the air discharge pipe and extending downward at a bottom surface thereof and having a through hole vertically penetrating the center thereof; And a through-hole disposed between the outlet of the tubular body and the air discharge pipe and having a receiving hole for receiving the opening and closing plate and being fixed at the center of the receiving hole so that a lower end of the extending rod is positioned inside the tubular body, A fixture provided inside the fixture; A lower end fixed to an upper end of the richer body and an upper end connected to a lower end of the extending rod; A connection pipe is provided between the chamber and the air discharge pipe, and respective internal spaces are connected; Wherein the connection pipe is provided with an opening / closing valve which is operated according to the set data by receiving the sensing data of the vacuum state of the chamber through the control of the control means, And a shutoff valve is provided at a portion of the air discharge pipe located between the connection pipe and the vacuum unit to prevent backflow.

In the vacuum pump as described above, when the fluid is pumped, after the air in the chamber is completely exhausted, the air discharge pipe is smoothly closed to maintain the vacuum state of the chamber, After the operation is completed, the rich is opened to its own load and air is injected into the air discharge pipe, so that the vacuum state of the air discharge pipe can be smoothly released.

Thus, the rich state can be stably returned to the home position, so that the initialization is smoothly performed, and the vacuum pump operation is continuously and smoothly performed.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic view showing a vacuum force suction pump according to an embodiment of the present invention; FIG.
Fig. 2 is a schematic view showing an air discharge cylinder constituting a vacuum force suction pump according to the embodiment. Fig.
Fig. 3 is a schematic view showing air blocking means constituting a vacuum force suction pump according to the present embodiment. Fig.
Fig. 4 is a schematic view showing an auxiliary blocking member applied to the air blocking means constituting the vacuum force suction pump according to the present embodiment. Fig.
Fig. 5 is a schematic view showing a housing constituting a vacuum force suction pump according to the embodiment. Fig.
6 to 8 are schematic views showing a sensing sensor constituting a vacuum force suction pump according to the present embodiment.

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

The embodiments of the present invention can be modified in various forms, and the scope of the present invention should not be construed as being limited to the embodiments described in detail below. This embodiment is provided to more fully describe the present invention to those skilled in the art. Therefore, the shapes and the like of the elements in the drawings can be exaggeratedly expressed to emphasize a clearer description. It should be noted that in the drawings, the same members are denoted by the same reference numerals. Detailed descriptions of well-known functions and constructions which may be unnecessarily obscured by the gist of the present invention are omitted.

1 to 8 are diagrams showing a vacuum force suction pump according to an embodiment of the present invention. The vacuum force suction pump 1 according to the present embodiment includes a motor 2; A chamber 41 in which an impeller 3 connected to the rotating shaft of the motor 2 rotates and an inlet 42 through which the fluid flows into the chamber 41; A housing (4) having an outlet (43); An air discharge pipe 5 through which the air in the chamber 42 and the chamber 41 is moved; a vacuum means 6 for discharging the air moved through the air discharge pipe 5 to the outside; A control means (7) for controlling the driving of the motor (2) and the vacuum means (6) by receiving and controlling the power of the power supply unit through the set data; Air blocking means (8) for opening and closing the air discharge passage of the air discharge pipe (5); And an air discharge pipe 9 connected to an inlet of the chamber 41 and connected to the air discharge pipe 5 at an upper portion thereof.

That is, the air shutoff means 8 is provided between the air exhaust pipe 5 and the inlet 42 to shut off or release the air exhaust passage of the air exhaust pipe 5 to control the movement of the fluid.

Accordingly, the air in the air discharge cylinder 9 and the chamber 41 is discharged to the outside through the vacuum means 6 and the fluid flows in from the outside through the inlet 91.

The fluid introduced through the inlet port 91 is received in the air discharge cylinder 9 and is supplied to the chamber 41 to be filled with the fluid. At the same time, The air introduced into the discharge cylinder (9) is discharged to the outside through the air discharge pipe (5) and the vacuum means (6).

Accordingly, since the inside of the chamber 41 forms a vacuum state, the vacuum chamber can be formed in a vacuum state without any additional operation such as addition of priming, and the pump operation can be efficiently performed.

Preferably, the outlet 43 connected to the chamber 41 is provided with a check valve 10 for preventing the backflow of the fluid.

That is, when the chamber 41 is formed in a vacuum state through the vacuum means 6, external air and fluid flow back through the outlet 43 is prevented through the check valve 10 It is most preferable that the vacuum state of the chamber 41 is implemented smoothly.

The air discharge tube 9 is formed in a cylindrical shape having a supply port 92 spatially connected to an inlet of the chamber 41 and an inlet 91 through which fluid flows.

That is, a space for storing the fluid introduced into the inlet 91 is formed.

The air discharge pipe (5) connected to the vacuum means (6) is connected at a position higher than the inlet (91) in the air discharge cylinder (9).

Accordingly, when a vacuum suction force by the vacuum means 6 is formed in the air discharge cylinder 9, the fluid flowing into the inlet 91 freely falls and is stored in the air discharge cylinder 9 The air is supplied to the chamber 41 and the air introduced into the inlet 91 is discharged to the outside through the air discharge pipe 5 via the vacuum means 6.

At this time, the air remaining in the chamber 41 is discharged to the outside through the air discharge pipe (5) via the air discharge cylinder (9).

The inlet (91) is located at a position higher than the maximum height of the chamber (41).

That is, after the fluid is introduced at a position higher than the maximum height of the chamber 41, the fluid falls freely and is supplied to the chamber 41 after passing through the air discharge cylinder 9, More smoothly.

A control unit for controlling the driving of the motor 2 and the vacuum means 6 by sensing the level of the fluid at a position of the air discharge cylinder 9 located at a water level at which the fluid flows in the inlet 91, And an auxiliary sensing sensor 93 adapted to apply the sensed data to the control means 7 is provided.

That is, the auxiliary sensing sensor 93 senses the level of the fluid flowing into the inlet 91, and the control means 7 calculates the level of the sensed fluid in the air discharge cylinder 9 .

At this time, when the inlet 91 is located at a position higher than the maximum height of the chamber 41, when the fluid has a water level equal to that of the inlet 91, the chamber 41 is completely filled, The vacuum state is realized.

Therefore, when the auxiliary sensing sensor 93 senses the level of the fluid, the chamber 41 has a vacuum state.

In this way, the control means 7 calculates the level data of the fluid with respect to the level at which the chamber 41 is formed in the vacuum state through the auxiliary sensing sensor 93, When the driving of the means 6 is stopped and the rotation of the impeller 33 driven by the motor 2 is maintained, the fluid in the chamber 41 is vacuum pumped, Thereby generating a vacuum suction of the fluid at the inlet port 91 continuously.

Thus, the fluid is continuously vacuum pumped.

The air discharge pipe 5 is provided with an on-off valve 20 which is controlled by the control means 7 so as to open and close the inside of the air discharge pipe 5 so that the driving of the vacuum means 6 So that outside air can be prevented from entering the air discharge cylinder 9 through the air discharge pipe 5 after the air is stopped.

That is, if the space of the air discharge pipe 5 is closed through the opening / closing valve 20 after the driving of the vacuum means 6 is stopped, 9, it is prevented that air is sucked from the outside through the air discharge pipe 5, so that the vacuum suction force at the inlet 91 is more smoothly generated, .

The opening and closing valve 20 closes the movement of the air from the air discharge pipe 5 to the air discharge cylinder 9 and moves the air from the air discharge cylinder 9 to the vacuum means 6 Way check valve configured to open the check valve, and it is most preferable to apply the check valve according to the user's selection.

In this case, it is preferable that the air discharge cylinder 30 is directly connected to the housing 4.

The check valve 10 is a one-way check valve that prevents the fluid and air from flowing back to the chamber 41 from the outlet 43 and discharges the fluid to the outside through the outlet 43 And a solenoid valve for receiving power from the power supply unit through the control unit 7. The solenoid valve may be operated according to a user's selection so that air or fluid flows back to the chamber 41 from the outside, It is preferable that the vacuum state of the chamber 41 can be formed more smoothly by preventing air from flowing into the chamber 41 when the vacuum means 6 is driven.

In the vacuum pump 1 according to the present embodiment, the chamber 41 senses the level of the fluid contained in the chamber 41 and senses whether or not the vacuum state is implemented. (11) adapted to apply data to the control means (7).

It is most preferable that the vacuum state of the chamber 41 is sensed in real time through the sensing means 11 so as to obtain the base data for the control of the motor 2 and the vacuum means 6 Do.

The sensing means 11 preferably comprises a water level sensor for sensing the level of the fluid and is disposed at a position corresponding to a water level enough to perform a vacuum pump in the chamber 41, It is most preferable to arrange them according to the user's selection.

In the vacuum forced sucking pump 1 according to the present embodiment, the sensing means 11 provided in the air discharge pipe 5 and disposed in the chamber 41 to sense the level of the chamber 41 And a main blocking member 81 adapted to control the supply of power through the control of the control means 7 to receive the sensed data and to calculate the opening and closing of the air discharge pipe 5 based on the set data, In this case, the main blocking member 81 preferably comprises a solenoid valve that is driven by the power supplied through the control unit 7 to open and close the air discharge passage, and is most preferably composed of a solenoid valve.

Accordingly, when the air discharge passage is closed in order to realize the inside of the chamber 41 in a vacuum state, the main blocking member 81 is opened / closed through the electric signal of the control means 7 and promptly responded Closing is performed, so that the work quality can be improved.

In the vacuum force suction pump 1 according to the present embodiment as described above, the sensing means 11 includes a first sensor (not shown) disposed in the chamber 41 at a position of a water level enough to generate a vacuum suction force, (12), and a second sensor (13) positioned above the first sensor (12).

That is, it is preferable that the first sensor 12 and the second sensor 13 detect the internal level of the chamber 41, respectively.

On the other hand, the main blocking member 81 is arranged to open or close a position of the air discharge pipe 5 having a higher water level than the second sensor 13.

That is, the main blocking member 81 opens and closes the inside of the air discharge pipe 5 at a position higher than the sensing means 11.

The control means 7 drives the main blocking member in the form of closing the air discharge pipe 5 when the level of the chamber 41 senses the level of the fluid at the second sensor 13 ; When the level of the chamber 41 senses the level of the fluid in the first sensor 12 during the operation of the vacuum pump in the chamber 41, As shown in Fig.

Accordingly, even if the water level fluctuates within the interval range of the water levels at which the first sensor 12 and the second sensor 13 are located in the chamber 41 in which the vacuum pump operation is performed, The opening and closing of the inside of the discharge pipe 5 is not performed, thereby securing the structural stability and improving the working efficiency.

In the vacuum force suction pump 1 according to the present embodiment as described above, the sensing means 11 is inserted into and fixed to the chamber 41, A sensor body 14 having a pipe shape in which coils of conductive material constituting the sensor 12 and the second sensor 13 are inserted and molded, (15) having terminals fixed to the chamber (41) while the upper part of the sensor body (13) is closed and connected with an electric wire extending from the coil to the outside, and a fixed cover And a permanent magnet (17) fixed to the outer peripheral surface of the buoyant body (16).

That is, while the permanent magnets 17 are lifted and lowered according to the level of the chamber 41 in the sensor body 14, the coils constituting the first sensor 12 and the second sensor 13 are respectively passed And generates a battery signal to sense the level of the chamber 41.

In this case, it is preferable that a fixing protrusion 18 is formed at the lowermost end of the sensor body 14 so that the buoyant body 16 is not released to the outside.

It is preferable that the control means 7 controls the driving of the main blocking member 81, the vacuum means 6 and the motor 2. In accordance with the set data, 41) is controlled by controlling the driving of the vacuum means (6) and the opening of the air discharge passage by the sub-shut-off member (81) The control unit 5 receives the level data of the fluid according to the vacuum state of the chamber 41 and stops the driving of the vacuum means 6 and closes the air discharge passage through the main blocking member 81 to drive the motor 2 So that the impeller 3 is continuously rotated so as to pump the fluid through the chamber 41 by vacuum.

In this case, when the level of the chamber 41 senses the level of the fluid in the second sensor 13, the control means 7 controls the main shut-off member 81 ); When the level of the chamber 41 senses the level of the fluid in the first sensor 12 during the operation of the vacuum pump in the chamber 41, (81).

Accordingly, even if the water level fluctuates within the interval range of the water levels at which the first sensor 12 and the second sensor 13 are located in the chamber 41 in which the vacuum pump operation is performed, The opening and closing of the inside of the discharge pipe 5 is not performed, thereby securing the structural stability and improving the working efficiency.

The air shutoff means 8 is provided at a position between the main shut-off member 81 and the vacuum means 6 in the air discharge pipe 5, A tube 83 connected to the tube 83 to communicate with the tube 84 so as to move the air, a float 84 adapted to move according to the buoyancy of the fluid introduced into the tube 83, And an auxiliary blocking member 82 including an opening / closing member 85 for opening / closing a hole of the tube body 821.

That is, when the fluid flows into the tubular body 83, when the fluid 84 moves upward due to buoyancy of the fluid flowing into the tubular body 83, the opening and closing member 85 blocks the inside of the tubular body 83 Closing member 85 opens the inside of the tubular body 83 when the buoyant force of the fluid is lowered to cause the tubular member 84 to move downward.

The opening and closing member 85 constituting the auxiliary blocking member 82 is formed in such a manner that an upper surface thereof is in close contact with an end portion of the air discharge pipe 5 and is closed, An opening and closing plate 86 provided with an extension rod 861 and a receiving hole disposed between the outlet of the tube 83 and the air outlet pipe 5 for receiving the opening and closing plate 86, A fixed body 88 provided with a fixing pipe 87 having a through hole fixed to the inner side of the tubular body 83 so that the lower end of the extending rod 861 is positioned inside the tubular body 83 at the center of the tubular body 83, 84 and an upper end thereof has a receiving pipe 89 fastened to the lower end of the extending rod 861. [

That is, the chamber 41 is evacuated by moving the air in the chamber 41 through the tube 83 and discharging the air through the vacuum unit 6.

Accordingly, when the fluid is filled in the chamber 41 and the air is exhausted, the opening / closing plate 86 is lifted up by the rich portion 84 to close the end of the air discharge pipe 5 The air in the chamber 41 is smoothly discharged through the air discharge pipe 5.

After the completion of the pumping operation of the fluid, the valve 84 is lowered, and the opening / closing plate 86 returns to the original position stably to realize initialization.

It is preferable that a shield plate 841 is provided at the upper portion of the rich body 84 to prevent the fluid from being jammed and closed in the direction of the discharge port of the tube 83.

Accordingly, even if the fluid flows inside the tubular body 83 and flows or flows toward the discharge port during the operation of vacuum-pumping the fluid after sucking the air inside the chamber 3 to form a vacuum state, The fluid is blocked by the plate 841 so that the fluid is not sucked to the discharge port and does not close the space of the discharge port, so that the operation is stably performed.

The vacuum force pulling pump 1 according to the present embodiment as described above is configured to drive the vacuum means 6 in a state in which the main blocking member 81 is opened through the control means 7, And then sucks the fluid and the air from the chamber 41 and the inlet 42 via the tube 83 via the air discharge pipe 5 so that air is sucked into the tube 83 and the air discharge pipe 5 Through the vacuum means 6, and the fluid is introduced into the chamber 41.

In this way, when the fluid is introduced into the chamber 41 to form a vacuum state, the sensing means 11 senses the sensed fluid level and applies the sensed fluid level data to the control means 7 .

After the control means 7 receives the data of the level of the fluid sensed by the sensing means 11 and calculates the data, the driving of the vacuum means 6 is stopped according to the set data (program) The main blocking member 81 is controlled to close the air discharge pipe 5 and the rotation of the impeller 3 according to the driving of the motor 2 is continuously maintained to discharge the fluid in the chamber 41 to the outlet 43 to the outside.

When the fluid is pumped through the chamber 41 and the pump operation of the fluid is completed and the level of the fluid in the chamber 41 is lowered to release the vacuum state, The control means 9 receives the data of the level of the fluid sensed by the sensing means 11 and calculates the data of the level of the fluid in the main blocking member 81 And the air discharge pipe 5 is opened to maintain the initial driving state.

As described above, when the air discharge passage is closed in order to implement the inside of the chamber 41 in a vacuum state, the main blocking member 81 is opened / closed through the electric signal of the control means 7 and immediately responded By fast closing, the work quality is improved.

On the other hand, when the air discharge passage is closed in order to realize the inside of the chamber 41 in a vacuum state, the main blocking member is not properly controlled by the control unit 7 due to an error or short circuit of the electric circuit When the chamber 41 is in a state in which the vacuum state is implemented and the fluid is put into a state of being introduced into the vacuum means 6 via the air discharge pipe 5, So that the air discharge passage is stably closed even in an emergency.

At this time, while the auxiliary blocking member 82 is supplied with the fluid into the tubular body 83 while air is sucked into the vacuum means 6 through the air discharge pipe 5, ).

Thus, when the rich gas 84 is continuously raised by the fluid, the opening / closing plate 86 rises and the end of the air discharge pipe 5 is closed.

That is, the fluid is prevented from flowing into the air discharge pipe 5, and the air discharge pipe 5 is in a vacuum state at this time.

As described above, in the state where the opening / closing plate 86 closes the air discharge pipe 5, an operation of vacuum-pumping the fluid through the chamber 41 is performed.

Accordingly, even if the main blocking member 81 is not properly driven, the air vent is closed through the auxiliary blocking member 82 to prevent the inflow of the fluid into the vacuum unit 6 to prevent damage do.

In the air discharge pipe 5 of the vacuum forced sucking pump 1 according to the present embodiment thus constructed, the connecting pipe 19 is provided at positions spaced apart from the upper and lower ends of the auxiliary blocking member 82, respectively.

That is, air is circulated through the connection pipe 19 by bypassing the auxiliary blocking member.

The connection pipe 19 is provided with an on-off valve 20 which is operated according to the set data by receiving the sensing data on the vacuum state of the chamber 41 under the control of the control means 7 .

That is, the inside of the connection pipe 19 is opened and closed through the opening / closing valve 20.

The vacuum forced sucking pump 1 according to the present embodiment has a structure in which a portion of the air discharge pipe 5 located between the connection pipe 19 and the vacuum means 6 is blocked A shut-off valve 21 is provided to allow fluid to flow out through the air outlet pipe 5 to the vacuum means 6 after the vacuum means 6 has been stopped through the shut-off valve 21 So that safety can be secured.

That is, when the space of the air discharge pipe (5) is closed through the shutoff valve (21) after the driving of the vacuum means (6) is stopped, the fluid flows out to the vacuum means (6) And the safety is realized.

In addition, in the vacuum forced sucking pump 1 according to the present embodiment, the air discharge pipe 5 positioned between the vacuum means 6 and the shut-off valve 20 is provided with a drain A tube (22) is provided; The drain pipe (21) is preferably provided with a drain valve (23) driven by the control means (7).

That is, the fluid absorbed in the chamber 41 is introduced into the space between the vacuum means 6 and the shutoff valve 21 through the drain pipe 33 to enter the vacuum means 6 .

It will be apparent to those skilled in the art that various modifications and equivalent arrangements may be made therein without departing from the scope of the present invention as defined by the appended claims and their equivalents. . Therefore, it is to be understood that the present invention is not limited to the above-described embodiments. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims. It is also to be understood that the invention includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the appended claims.

1: vacuum pump suction pump 2: motor
3: impeller 4: housing
41: chamber 42: inlet
43: outlet 5: air outlet
6: Vacuum means 7: Control means
8: air blocking means 81: main blocking member
82: auxiliary blocking member 83: tubular body
84: rich 841: shield plate
85: opening and closing member 86: opening / closing plate
87: Fixation tube 88: Fixture
89: Receiving tube 9: Air discharge cylinder
91: inlet 92: inlet
93: Auxiliary detection sensor 10: Non-return valve
11: sensing means 12: first sensor
13: second sensor 14: sensor body
15: Fixing lid 16: Buoyant body
17: permanent magnet 18:
19: connector 20: opening / closing valve
21: shutoff valve 22: drain pipe
23: drain valve

Claims (1)

A motor 2; A chamber 41 in which an impeller 3 connected to the rotating shaft of the motor 2 rotates is disposed therein, an inlet 42 to which an inlet pipe for receiving a fluid is supplied to the chamber, A housing (4) having an outlet (43) through which fluid is discharged; An air discharge pipe (5) through which the air remaining in the inlet (42), the inflow pipe and the chamber (41) is moved; A vacuum means 6 for discharging air moving through the air discharge pipe 5 to the outside; A control means (7) for controlling the driving of the motor (2) and the vacuum means (6) by receiving and controlling the power of the power supply unit through the set data; The control means is provided in the air discharge pipe 5 and is arranged in the chamber 41 to receive sensed data of the sensing means 11 adapted to sense the level of the chamber 41, A main blocking member 81 for controlling the supply of electric power through the control of the air supply pipe 7 to control the opening and closing of the air discharge pipe 5, (83) which is provided at a portion located between the means (6) and communicated with the air discharge pipe (5) so as to move the air, (84) provided with a shielding plate (841) for preventing fluid from jumping and closing in the direction of a discharge port of the tube (83), and a valve plate And an opening / closing member 85 for opening / Auxiliary shut-off member 82, the air discharge pipe of the air in the air blocking means (8) so as to open and close the air discharge passage (5) and that; And an air discharge pipe (9) connected to the inlet (42) of the chamber (41) and connected to the air discharge pipe (5) at an upper portion thereof;
The inlet 91 of the air discharge cylinder 9 is located at a position higher than the maximum height of the chamber 41;
An auxiliary sensing sensor (not shown) adapted to sense the level of the fluid and to apply the sensed data to the control means (7) is provided at a position of the air discharge cylinder (9) positioned at a level where the fluid flows in the inlet (91) 93;
The opening and closing member 85 constituting the auxiliary blocking member 82 has an upper portion which is in close contact with the end portion of the air discharge pipe 5 to be closed and has a through hole extending vertically downward at the bottom, An opening and closing plate 86 provided with a rod; (86), and a lower end of the elongated rod is disposed at the center of the receiving hole, between the outlet of the tube (83) and the air discharge pipe (5) A fixture 88 having a fixing pipe provided therein with a through hole fixed to be pierced so as to be positioned in the fixing hole 88; And a lower end of which is fixed to the upper end of the bolt 84 and an upper end of which is connected to the lower end of the extending rod;
A connection pipe 19 is provided at the upper and lower ends of the auxiliary shut-off member 82 in the air discharge pipe 5, respectively;
The connection pipe 19 is provided with an opening / closing valve 20 which is operated according to the set data by receiving sensing data on the vacuum state of the chamber 41 under the control of the control means 7,
And a shutoff valve (21) for preventing reverse flow is provided at a portion of the air discharge pipe (5) located between the connection pipe (19) and the vacuum means (6)
The sensing means (11)
In the chamber 41, a first sensor 12 disposed at a position of a level to generate a vacuum suction force of the fluid, and a second sensor 13 positioned above the first sensor 12 , ≪ / RTI >
The first sensor 12 and the second sensor 13, which are inserted and fixed in the chamber 41 and are spaced apart from each other with a space therebetween, A sensor body 14 in the form of a pipe which is fixed to the chamber 41 while closing the upper part of the sensor body 14 and is fixed to the chamber 41, And a permanent magnet 17 fixed to an outer circumferential surface of the buoyant body 16 so that the buoyant body 16 has buoyancy and is disposed inside the sensor body 14 ;
The main blocking member (81)
The second sensor (13) being arranged to open and close a position in the air discharge pipe (5) having a higher water level than the second sensor (13);
At the lowermost end of the sensor body 14,
A fixing protrusion 18 is formed so that the buoyant body 16 is not released to the outside;
At one portion of the air discharge pipe (5) located between the connection pipe (19) and the vacuum means (6)
A shutoff valve (21) for shutting off the movement of the fluid is provided;
The air discharge pipe (5) positioned between the vacuum means (6) and the shutoff valve (21)
A drain pipe (22) for discharging the fluid to the outside is provided;
In the drain pipe 22,
And a drain valve (23) driven through the control means (7).

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