KR200423907Y1 - Screw type vacuum pump with the check valve - Google Patents

Abstract

The present invention relates to a screw-type vacuum pump that can reduce the number of screws, reduce the weight of the rotor, and increase the rotational effect per minute (rpm) even though the overall size is reduced.

The present invention has a housing having a compression space formed therein in the shape of a cylinder formed with an inlet at one end; A drive shaft and a driven shaft each of which has a screw rotated by the driving of the motor and engaged with each other; An exhaust plate installed at an opposite end of the portion where the inlet of the housing is formed, the exhaust plate penetrating laterally from a surface facing the inside of the housing and having an exhaust passage; And a valve means fixed to the driving shaft and the driven shaft so as to cover the exhaust passage formed in the exhaust plate and rotated by rotation of the shafts to open and close the exhaust passage.

Vacuum pump, screw, valve means, balance weight

Description

Screw type vacuum pump with the check valve}

1 is a cross-sectional view showing an example of a vacuum pump according to the present invention,

2 is for explaining the operation of the valve means provided in the vacuum pump according to the present invention

  Figure 4a is a flow path is open,

  4B is a state in which a flow path is closed.

Figure 3 is a side view showing an example of a screw provided in the vacuum pump according to the present invention,

Figure 4 is a cross-sectional view showing an example of a conventional screw type vacuum pump,

Figure 5 is a side view showing a part of a screw provided in a conventional screw type vacuum pump.

<Explanation of symbols for the main parts of the drawings>

1: housing

   11: intake port

   12: compression space

2: drive shaft

3: driven shaft

4: screw

   41, 42: balance weight 411, 421: inclined surface

5: motor

6: valve means

   61: fixed valve 61b: external fixed valve 61a: internal fixed valve

     611: Aerator

   63: by aeration

   62: rotary valve 621: vent hole

7: exhaust plate

   71: by aeration

   72: axial ball

The present invention relates to a screw-type vacuum pump, more specifically, by reducing the number of screws, the weight of the rotor is lighter, even though the overall size is reduced, the compression effect is high, it is possible to increase the rpm (rpm) It relates to a screw type vacuum pump.

Generally, the vacuum pump (vacuum pump) refers to a means for forcibly conveying the gas by using a pressure difference, a number of known is known, the present invention is a vacuum for compressing air through the interlocking rotation of a pair of screw shaft The pump (hereinafter referred to as screw vacuum pump) is an improvement.

4 shows a screw-type vacuum pump commonly known in the art as follows.

The conventional screw-type vacuum pump is provided with an inlet 101 and an outlet 102 at the upper and lower sides, a housing 100 having a compression space 103 formed therein, and a gas passing through the housing 100. Drive shaft 200 and driven shaft 300, each of which is provided with a screw 400 to compress the drive shaft 300 and the drive means to rotate the driven shaft 300 is interlocked by transmitting power to the drive shaft 200 It is composed.

Both ends of the driving shaft 200 and the driven shaft 300 are rotatably supported by a bearing, and the driving means drives the power of the motor 500 and the driving shaft 200 provided in the driving shaft 200. Composed of gears 201 and 301 to be transmitted to the 300, the inlet 101 and the outlet 102 is provided with a gas inlet pipe and gas discharge pipe can be forcibly transported gas.

When the vacuum pump configured as described above drives the motor 500 provided in the drive shaft, the drive shaft 200 is rotated, and the gear 301 of the driven shaft 300 meshed with the gear 201 installed in the drive shaft 200. ) Is rotated so that the driven shaft 300 is interlocked. Accordingly, as the screw 400 provided in the drive shaft 200 and the driven shaft 300 are rotated in engagement with each other, the air pressure of the compression space 103 is lower than that of the external air. Therefore, the gas is introduced into the compression space 103 from the inlet 101 and compressed, and then discharged through the outlet 102.

Screw 400 configured in the conventional screw pump configured as described above is thinner at both ends as shown in Figure 5 is not balanced with the thick portion of the opposite side is the rotation center is disturbed because the rotation is not smooth, Figure 5 As shown in the figure, the balancing hole 401 is formed in the thick portion through a drilling process to make the weight of the thick portion equal to the weight of the thin portion to form a rotation center.

However, when the balancing hole 401 is formed in such a thick portion, the drilling process must be performed, and thus, there is a disadvantage in that a lot of time and process are required for the manufacture of the screw. As it hardens, the balancing effect is lowered. As a result, the rotation of the screw 400 in the non-balancing state causes vibration and noise, as well as a cause of reducing the life of the pump.

In addition, conventional screw pumps need to increase the number of screws in order to obtain higher efficiency because air is pumped by the differential pressure created by the driving of the screw. There was a problem that required power.

The present invention is designed to solve the problems described above, by providing a balancing weight on one side of the screw without forming a balancing hole to provide a screw-type vacuum pump that can be prevented from being disturbed by balancing balancing The purpose.

In addition, an object of the present invention is to provide a screw-type vacuum pump that can increase the effect of the inflow and discharge of air by forming an inclined surface that can attract or push air to the balance weight.

Furthermore, an object of the present invention is to provide a screw-type vacuum pump which increases the compression effect by allowing the sucked air to be discharged instantaneously in a compressed state for a predetermined time.

The present invention for achieving the above object is a housing having a compression space formed therein in the shape of a cylinder formed with an inlet at one end; A drive shaft and a driven shaft each of which has a screw rotated by the driving of the motor and engaged with each other; An exhaust plate installed at an opposite end of the portion where the inlet of the housing is formed, the exhaust plate penetrating laterally from a surface facing the inside of the housing and having an exhaust passage; And a valve means fixed to the driving shaft and the driven shaft so as to cover the exhaust passage formed in the exhaust plate and rotated by rotation of the shafts to open and close the exhaust passage.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a cross-sectional view showing an example of a vacuum pump according to the present invention, Figure 2 is an exploded perspective view showing an example of the valve means provided in the vacuum pump according to the present invention, Figure 3 is a vacuum pump according to the present invention Figure 4 is a side view showing an example of the provided screw, Figure 4 is for explaining the operation of the valve means provided in the vacuum pump according to the present invention, Figure 4a is an open flow path, Figure 4b is a closed flow path to be.

As shown, the screw-type vacuum pump according to the present invention has a valve means 6 for opening and closing the exhaust port so that the air compressed by the screw 4 is not exhausted for a predetermined time so that the air is sufficiently compressed.

Before describing the valve means 6, the overall configuration of the screw type vacuum pump of the present invention will be described.

Screw-type vacuum pump of the present invention is a tubular shape in which the inlet 11 is formed at one end of the housing (1) formed with a compression space 12 therein; A drive shaft 2, a driven shaft 3, each of which has a screw 4 formed so as to rotate by driving of the motor 5 and mesh with each other; An exhaust plate (7) provided at an end opposite to the portion where the inlet port (11) of the housing (1) is formed and penetrating sideward from a surface facing the inside of the housing (1); And valve means (6) provided on the drive shaft (2) and the driven shaft (3) to open and close the exhaust passage (71) formed on the exhaust plate (7).

As shown in FIG. 1, the housing 1 has a tubular shape, and an inlet 11 is formed at an upper center thereof, and a drive shaft 2 and a driven shaft 3 are rotatably installed therein, and inside the air. Compression space 12 is formed is compressed.

Screws 4 are formed on the drive shaft 2 and the driven shaft 3, respectively, and the ends of the shafts 2, 3 are rotatable inside the housing 1 by shaft support means such as bearings. It is installed.

A motor 5 is installed at one end of the drive shaft 2, and a gear 21 is installed between the motor 5 and the screw 4, and a gear tooth engaged with the gear value of the gear 21. A gear 31 having a structure is provided on the driven shaft 3 so that rotation of the drive shaft 2 can be transmitted to the driven shaft 3.

The lower end of the housing 1, that is, the end opposite to the end where the inlet 11 is formed, is opened, and the exhaust plate 7 is provided at the open end as shown in FIGS. 1 and 2.

The exhaust plate 7 is a plate on which the exhaust passage 71 is formed, and serves to seal the open end of the housing 1 and constitute a exhaust passage.

As illustrated in FIG. 2, two exhaust passages 71 may be formed to face each of the axes 2 and 3, and may be connected to each other to be connected to one exhaust port.

As described above, the means for opening and closing the inlet of the exhaust passage 71 formed in the exhaust plate 7 is the valve means 6 described above.

The valve means 6 is rotated in accordance with the rotation of the fixed valve 61 and the drive shaft 2 and the driven shaft 3 fixed to the inside of the housing 1, as shown in Figs. It consists of a valve 62.

First, the rotary valve 62 is formed in a cylindrical shape as shown in Figs. 1 to 2B, and a vent hole 62 is formed on one side of the side wall.

The rotary valve 62 configured as described above may be integrally formed at the lower end of the screw 4 as shown. By forming the rotary valve 62 integrally at the lower end of the screw 4 as described above, not only the overall structure can be simplified, but also the assembly can be facilitated.

The fixed valve 61 which is operated opposite to the rotary valve 62 is fixedly installed inside the housing 1, and constitutes only the internal fixed valve 61a or the external fixed valve 61b as shown. can do.

First, the internal fixing valve 61a has a shaft hole through which a shaft penetrates in the center, and a vent hole 63 is formed at one side of the side wall. The vent hole 63 is formed to be connected to the exhaust hole 71 formed in the exhaust plate 7.

The ventilation hole 63 formed in the internal fixed valve 61a serves as a flow path for exhausting the compressed gas generated in the compression space 12 inside the housing 10, and the ventilation hole formed in the rotary valve 62. When 621 is aligned with the vent hole 63, a flow path between the compression space 12 and the vent hole 63 is connected to allow air in the compression space 12 to flow out through the exhaust hole 71. Exhausted.

As described above, the opening and closing of the flow path may be performed only by the internal fixing valve 61a, but as illustrated, the external fixing valve 61b may be further provided.

The external fixed valve 61b has a cylindrical cylindrical shape, and an outer end thereof is fixed to the internal fixed valve 61a, and a vent hole 611 is formed at one side thereof.

The vent hole 611 formed in the outer fixed valve 61b and the vent hole 63 formed in the inner fixed valve 61a are aligned and connected to each other.

The internal fixed valve 61a and the external fixed valve 61b may be integrally formed.

As the screw 4 of the vacuum pump provided with the valve means 6 as described above, balance weights 41 and 42 are formed as shown in FIGS. 1 and 3.

The balance weights 41 and 42 are means for aligning the center of rotation with mass weights formed at both ends of the screw.

Typically, the screw 4 formed in the vacuum pump cuts both ends horizontally, so as shown in FIG. 6, one side is thin, while the opposite side is thick, so that the center of rotation does not match the center of the axes 2 and 3. There is a problem that vibration occurs.

Accordingly, the screw provided in the vacuum pump according to the present invention protrudes a thinly cut portion as shown in FIG. 3 to form balance weights 41 and 42 to achieve symmetry of the weight with the thick portion.

As such, the inclined surfaces 411 and 421 are formed on the balance weights 41 and 42 formed on the screw 4.

Among these inclined surfaces 411 and 421, the inclined surface 411 formed in the balance weight 41 formed in the portion facing the suction port 11 side of the housing 1 is the interrupted portion of the shafts 2 and 3 as shown. It is formed toward the distance away from the center of the shaft (2, 3) is formed to form an upward inclination to induce the air sucked from the inlet 11 can be compressed more smoothly down.

Incidentally, the inclined surface 421 formed on the balance weight 42 formed in the portion facing the exhaust plate 7 is formed in the portion facing the exhaust plate, away from the center of the shafts 2 and 3, and is inclined upward, thereby compressed air. Acts to push the gas toward the exhaust passage 71.

Hereinafter, the operation process of the present invention configured as described above has been described with reference to each component above, but this will be described again as follows.

Since the overall driving of the vacuum pump is similar to the conventional one, a description thereof will be omitted. However, the present invention is provided with a valve means 6 and describes the role and operation of the valve means 6.

First, only the internal fixed valve 61a is provided as the fixed valve 61.

The flow path is opened only when the vent hole 621 formed in the rotary valve 62 and the vent hole 63 formed in the internal fixed valve 61a are aligned, and the vent hole 621 and the vent hole 63 are displaced. In the flow path is closed.

That is, the ventilation hole 621 formed in the rotary valve 62 is formed in the internal fixed valve 61a while the driving shaft 2 and the driven shaft 3 rotate to rotate the rotary valve 62. The flow path is opened only at the point of contact with 63, and the compressed air of the compression space 12 is discharged to the outside through the exhaust path 71 of the exhaust plate 7, and the flow path is discharged during the time that the remaining axes 2, 3 rotate. It is closed and the air is compressed by the screw 4.

When the external fixed valve 61b is further installed, the same operation as above, but the vent hole 611 formed in the external fixed valve 61b is always aligned with the vent hole 63 formed in the internal fixed valve 61a. Keeping up.

In this process, the inclined surface 411 formed on the balance weight 41 guides the air flowing into the suction port 11 to the continuous screw 4 side, so that the air moves more smoothly to the lower side, and the balance weight 42 The formed inclined surface 421 pushes the induced air toward the exhaust plate 7 to increase the exhaust pressure.

As described above, the present invention has an effect of providing a screw type vacuum pump that can prevent balancing by forming balancing weights at thin portions of the ends of the screws to adjust the balancing.

In addition, there is an effect that can increase the intake and discharge effect of the air by forming an inclined surface to attract or push the air in the balance weight.

Moreover, there is an effect that the compression effect can be enhanced by installing the valve means so that the sucked air is discharged momentarily in a compressed state for a predetermined time.

Although the present invention has been described with reference to the accompanying drawings, it will be apparent to those skilled in the art that many various obvious modifications are possible without departing from the scope of the present invention from this description. Therefore, the scope of the present invention should be construed by the claims described to include many such variations.

Claims (4)

A housing 1 having a compression space 12 formed therein in a cylindrical shape having a suction port 11 formed at one end thereof; A drive shaft 2, a driven shaft 3, each of which has a screw 4 formed so as to rotate by driving of the motor 5 and mesh with each other; An exhaust plate (7) provided at an end opposite to the portion where the inlet port (11) of the housing (1) is formed and penetrating sideward from a surface facing the inside of the housing (1); And a valve means (6) installed on the drive shaft (2) and the driven shaft (3) to open and close the exhaust passage (71) formed on the exhaust plate (7). The method of claim 1, The valve means 6 is fixed to one side of the housing 1, the shaft (2, 3) is penetrated, the vent hole 63 is connected to the exhaust passage 71 formed in the exhaust plate 7 on the side wall An internal fixed valve 61a formed; The lower end of the screw (4) is formed in a cylindrical shape, the vent hole 621 facing the vent hole 63 formed in the internal fixed valve (61a) is formed, the drive shaft (2) and the driven shaft ( Screw type vacuum pump, characterized in that consisting of a rotary valve 62 is fixed to each of the 3) is rotated by the rotation of the shaft (2, 3). The method of claim 2, An external fixed valve 61b is further provided outside the rotary valve 62 constituting the valve means 6, and the external fixed valve 61b has a cylindrical cylindrical shape and its outer end thereof is the internal fixed valve 61b. Screw type vacuum pump, characterized in that fixed to one side is formed with a vent hole (611). The method of claim 3, wherein Balance weights 41 and 42 are formed at both ends of the screw 4, and the balance weight 41 formed at the end of the suction port 11 side of the balance weights 41 and 44 stops stopping the screw 4. The guide inclined surface 42 is formed on the facing surface, the screw-type vacuum pump, characterized in that the guide inclined surface 45 is formed toward the exhaust plate (7) in the balance weight (44) formed on the discharge port (12) side.

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