KR101046579B1 - Internal hydraulic lifting device - Google Patents

Abstract

PURPOSE: An embedded hydraulic pulling-up device for a river, dam, a filtration plant, a sewage treatment plant, a new town complex is provided to use strong torque transferred from a reducer for opening and closing an opening and closing door. CONSTITUTION: An embedded hydraulic pulling-up device for a river, dam, a filtration plant, a sewage treatment plant, a new town complex is composed as follows. A screw(200) with a screw fastener(210) is screwed on a bearing nut(120) integrally formed in the top end of a cylinder rod(100). An adapter(300) is fixed to the top of the screw coupler through a bolt. A lower cover plate is coupled to the outer surface of the adapter using a bearing to rotate the adapter. Multiple fixing pins are protruded from the outer top of the adapter in a circular shape.

Description

Internal hydraulic lifting device installed in rivers, rainwater, sewage pumping stations, dams, water purification plants, sewage, wastewater, livestock, manure treatment plants, and industrial, residential land, new cities, urban development complexes

The present invention relates to a hydraulic built-in lifting device installed in a river, rainwater, sewage pumping station, dam, water purification plant, sewage, wastewater, livestock, manure treatment plant, and industrial, residential, new town, urban development complex, and more specifically, hydraulic built-in lifting By remarkably improving the coupling structure of the device, the high speed torque transmitted from the rotating shaft of the hydraulic motor is reduced by the reducer to generate a strong low speed torque, and the powerful low speed torque generated in this way can be used to open and close the door more efficiently without friction loss. At the same time,

The present invention relates to a high-quality, high-quality hydraulic built-in lifting device that maximizes convenience and efficiency as a whole, such that the built-in hydraulic lifting device can be moved back and forth to prevent damage and damage when the door is opened or lowered.

In general, there are several types of rivers, rainwater, sewage pumping stations, dams, water purification plants, sewage, wastewater, livestock, manure treatment plants, and industrial, residential land, new towns, and urban development complexes, depending on the purpose of use. Doors are installed,

In the case of the conventional opening and closing doors installed as described above, almost all of them have a defect in manufacturing, difficult to install, and expensive to manufacture, because the entire configuration is very complicated. There were many difficulties in the administrative aspects such as maintenance, repair etc.

On the other hand, in the case of an opening door having at least two hydraulic cylinders installed on the door, the operation of each door is not smooth because the hydraulic cylinders are not perfectly synchronized, which causes the door to open and lower by twisting and descending. There were various problems such as noise and abnormal wear caused by the door frame.

The present invention has been made in view of the above-mentioned problems to significantly improve the coupling structure of the hydraulic built-in lifting device to reduce the high-speed rotational force transmitted from the rotating shaft of the hydraulic motor to the reducer to generate a strong low-speed rotational force and thus generated The powerful low speed torque can be used to open and close the door more efficiently without friction loss,

When the door is repeatedly moved forward and backward by the guide rubber and wedges for water resistant rubber protection, it is very easy to connect with the sliding door and the sliding device for the hydraulic built-in lifting device to move forward and backward simultaneously with the door to prevent damage and damage. The purpose is to provide a high-quality, high-quality hydraulic built-in lifting device that maximizes the ease of use and efficiency as a whole.

Hydraulic built-in lifting device of the present invention for achieving the object described in the problem to be solved as described above is basically a screw in a bearing nut integrally formed on the upper end of the hollow cylinder rod is fixed to the opening and closing door coupled to both ends of the door frame The fastener is screwed on the screw welded on the top,

Fastening the adapter to the screw fastening surface of the screw with a bolt,

The outer cover of the adapter is coupled to the lower cover plate by using a bearing so that the adapter is rotatable and bolted to the upper surface of the adapter so that a plurality of fixing pins protrude upward in a circular shape,

The cam body and a pair of upper and lower cam shafts, each of which bearings are coupled to the cam body and the outer side of the stepped cam protrusion formed on one side of the cam body, are laminated by being in close contact with each other so as to face each other, and the cam protrusions are opposed to each other. Coupling a pair of rotors with gears on the outer surface to the fixing pins of the adapters so that the inner surface is in close contact with the combined bearing,

The upper cover plate is seated so that the inner surface is coupled to the upper cam body outer bearing to the upper inner surface of the inner gear while the inner gear having the gear formed thereon is seated on the lower cover plate so that the teeth formed on the outer surfaces of the pair of rotors are engaged. After fixing the upper cover plate, the inner gear and the lower cover plate integrally using bolts,

The hydraulic motor is coupled to the upper cover plate, and the rotary shafts thereof are configured by key coupling to the upper and lower cam shafts.

The inner end is inserted between the upper and lower bearings coupled to the outer surface between the screw fastener and the adapter, and the left and right sides move inside the sliding block installed on the upper base plate of the upper side of the door frame while being bolted to the bottom of the lower cover plate. It is characterized in that the sliding plate which is inserted into the slide so that only before, after the slide is installed is integrally formed.

The present invention is a breakthrough improvement of the overall coupling structure of the hydraulic built-in lifting device due to the advantages that it is more easy to install and use the reducer,

While the overall structure is simple, the powerful rotating force transmitted from the reducer can be used to open and close the door almost without friction loss.

When assembling the hydraulic built-in lifting device, the sliding plate is assembled in one piece in advance so that the sliding plate can be easily inserted into the sliding block installed on the upper side of the upper base plate of the door frame before and after the slide plate.

As described above, the hydraulic built-in lifting device of the present invention is easy to assemble, and after assembly, it is very convenient to install it so that the front and rear positions can be moved. It is obvious that this is a very innovative invention.

1 is a state in which the hydraulic built-in lifting device of the present invention coupled to the sliding block.
Figure 2a, Figure 2b is a partial exploded view of the hydraulic built-in lifting device of the present invention,
Figure 2a is a perspective plan view.
Figure 2b is a bottom perspective view.
Figure 3 is an exploded perspective view of the main portion for explaining the bearing engagement state of the upper and lower cam shaft and a pair of rotor of the present invention.
Figure 4 is a side cross-sectional perspective view for explaining the coupling state of the screw and adapter and the sliding plate of the present invention.
5A, 5B, and 5C are side cross sectional views of the present invention.
Figure 5a is a side cross-sectional view showing the entire configuration.
Figure 5b is a side cross-sectional view showing a main portion configuration.
5C is an enlarged cross-sectional view of the main portion;
Figure 6 is a side cross-sectional view showing an installation of the present invention.

Hereinafter, an embodiment for realizing the hydraulic built-in lifting device of the present invention will be described in detail with reference to the accompanying drawings.

Hydraulic built-in lifting device of the present invention as shown in the accompanying drawings, Figures 1 to 6 to reduce the high-speed rotational force transmitted from the rotating shaft (850a) of the hydraulic motor 850 to a powerful low-speed rotational force to the adapter 300 corresponding to the output end And forward and reverse rotation of the screw 200 coupled to the adapter 300, forward and backward by screwing the screw rod 200 and the lower end screwed to the bearing nut 120. To be used to raise and lower the opening and closing door 20 coupled to the bottom of the cylinder rod 100,

Looking at the coupling structure, the bearing nut 120 is integrally formed on the upper end of the hollow cylinder rod 100, the lower end of which is fixed to the opening and closing door 20 coupled to both ends of the door frame 10. ) Is screwed with the screw 200 has a spiral formed on the outer edge is configured so that the cylinder rod 100 is moved forward and backward when the screw 200 is rotated.

In addition, the screw fastener 210 is integrally welded to the upper end of the screw 200, and the adapter 300 is fixed to the upper surface of the screw fastener 210 by bolts 310.

The lower cover plate 400 is coupled to the outer surface of the adapter 300 by using the bearing 410 such that the adapter 300 is rotatable, and a plurality of fixing pins are formed on the outer surface of the adapter 300 in a circular shape. The bolt 321 is fastened so that the 320 protrudes upward.

Further, bearings B1, B2, B3, and B4 are formed on the outer surface of the cam body 511 and 521 and the outer side ends of the cam bins 512 and 522, respectively. A pair of combined upper and lower cam shafts 520 and 510 are stacked in close contact with each other so as to face each other, and the cam protrusions of the upper and lower cam shafts 520 and 510 face each other. A pair of rotors 600 having gears 610 formed on the outer surface of the bearings B2 and B3 coupled to the bearings B2 and B3 coupled to the fixing pins 320 of the adapter 300, respectively, are coupled to the bearings B2 and B3. It is.

In addition, an inner gear 700 having a gear 710 formed on an inner surface thereof is seated on an upper surface of the lower cover plate 400 so that the teeth 610 formed on the outer surface of the pair of rotors 600 are engaged with each other. 700, the upper cover plate 800 is seated so that the inner surface is coupled to the bearing B4 of the outer surface of the cam body 521 of the upper cam shaft 520, the upper cover plate 800 and the inner gear 700 And the lower cover plate 400 is fixedly integrally fastened by a bolt 810.

In addition, the hydraulic motor 850 is bolted to the upper surface of the upper cover plate 800, the rotary shaft 850a of the hydraulic motor 850 is coupled to the upper and lower cam shafts (520, 510). .

On the other hand, the upper and lower bearings (910, 920) are coupled to the outer surface between the screw fastener 210 and the adapter 300, the lower cover plate 400 between the upper, lower bearings (910, 920). The inner end of the sliding plate 900 coupled to the bottom bolt 930 is inserted.

The sliding plate 900 is inserted into the sliding block 30 installed above the upper base plate 11 of the door frame 10 so as to be slidable only before and after the left and right sides thereof.

Here, the sliding block 30 installed on the upper base plate 11 of the door frame 10 is installed by assembling a plurality of parts, and the sliding plate fastened to the lower cover plate 400 by bolts 930 ( 900 would be sufficient if the seat is configured to slide back and forth.

On the other hand, the hydraulic built-in lifting device of the present invention configured as described above is further installed by inserting the slide bearings (S1) (S2) (S3) in the middle and upper and lower portions of the pair of rotor (600) The rotation of the 600 may be configured to minimize the contact friction of each part.

In addition, the permanent magnet 41 is fixedly installed in the screw fastener 210 integrally welded to the top of the screw 200,

The outer surface of the cover body 130 welded to the lower side of the sliding plate 900 detects a pulse signal due to the proximity of the permanent magnet 41 fixed to the screw fastener 210 which rotates simultaneously with the rotation of the screw 200. By further installing and configuring the rotation detection device 40 by installing a rotation sensor 42 that can be,

The rotation signal sensed by the rotation sensing device 40 is sent to the control panel to accumulate and compare the rotational speed to automatically adjust the rotation speed of the hydraulic motor 850 to adjust the appearance length of the cylinder rod 100 to open and close the door ( 20) may be configured to adjust the rising and falling positions.

In the hydraulic built-in lifting device of the present invention configured as described above, the sliding plate 900 is already assembled in the process of connecting and installing the hydraulic motor 850 and the reducer part and the screw 200.

Therefore, when the sliding plate 900 is inserted into the sliding block 30 installed above the upper base plate 11 of the door frame 10, the sliding plate 900 is naturally seated inside the sliding block 30. After installation is inserted to enable sliding.

As described above, the hydraulic built-in lifting device of the present invention is easy to assemble, and after assembly, it is very convenient to install the door frame 10 so that the front and rear positions can be moved.

In addition, after the door frame 10 is installed, the cylinder door 100 constituting the hydraulic built-in lifting device can be opened and closed while the door 20 is lifted and lowered simply by being fixed to the lower side of the door 20. Will be.

This time will be described the process of opening and closing the door 20 using the hydraulic built-in lifting device of the present invention as described above.

When the hydraulic pressure is supplied to the hydraulic motor 850 by operating an external controller (not shown), the rotation shaft 850a of the hydraulic motor 850 rotates at a high speed.

Then, the upper and lower cam shafts 520 and 510 coupled to the rotary shaft 850a and the key are rotated at the same time, and the cam protrusions 512 and 522 of the upper and lower cam shafts 520 and 510 are respectively rotated. The pair of rotors 600 are also rotated, and the cam protrusions 512 and 522 are eccentrically formed on the cam bodies 511 and 521, respectively. The teeth 610 formed on the outer surface of the rotor 600 are 610. Rotation of the rotor 600 is greatly decelerated at low speed while rolling contact with the gear 710 formed in a continuous curve on the inner surface of the inner gear 700.

By the way, the pair of rotor 600 is coupled to the fixing pins 320 protruding upward in a circular shape on the adapter 300.

Therefore, since the fixing pin 320 which rotates in a circular shape simultaneously with the rotation of the pair of rotors 600 also rotates at low speed, a powerful low speed rotational force stably decelerated is output to the adapter 300 on which the fixing pin 320 is formed.

At this time. The screw fastener 210 welded to the upper end of the screw 200 is coupled to the bottom of the adapter 300, the bolt (310).

Therefore, the screw 200 rotates at a low speed by the powerful low-speed rotational force output from the adapter 300, and the cylinder rod 100 having the upper end screwed into the bearing nut 120 is the screw ( The lower or lower end of the cylinder rod 100 is fixed to the lower side of the opening / closing door 20, and the opening / closing door 20 moves up or down as the cylinder rod 100 moves forward or backward. It is opened and closed while descending.

Here, the hydraulic built-in lifting device of the present invention is a cam body 511 (521) and cam of the upper and lower cam shafts (520, 510) coupled to the rotary shaft (850a) and the key (KEY) of the hydraulic motor 850. Since the bearings B1, B2, B3, and B4 are respectively coupled to the outer surfaces of the protrusions 512 and 522, the high-speed rotational force of the hydraulic motor 850 is transmitted almost as it is without frictional resistance. The bearing 410 is also formed on the outer surface, so that the low-speed rotational force decelerated by the rotor 600 is transmitted to the adapter 300 without frictional resistance as well as between the inner ends of the sliding plate 900. Although the upper and side bearings 910 and 920 are installed, the screw fastener 210 on the top of the adapter 300 and the screw 200 acts in the axial direction of the screw 200. Is rotated.

Therefore, the hydraulic built-in lifting device of the present invention can be used to open and close the opening and closing door 20 efficiently without losing the reduced powerful low speed rotational force.

On the other hand, the hydraulic built-in lifting device of the present invention can further install the slide bearings (S1) (S2) (S3) in the middle and upper and lower portions of the pair of rotors 600 of the screw 200. Since the contact frictional force of each part is minimized by the slide bearings S1, S2, and S3 during the rotation of the rotor 600, the rotor 600 rotates more smoothly.

 Meanwhile, when the opening / closing door 20 is elevated, the protrusion 22 formed on the upper side of the opening / closing door 20 abuts against the guide rubber protection guide 13 formed on the upper side of the door frame 10 so that the opening / closing door 20 is pushed backward. While the close contact of the water-resistant rubber (20a) is released, when the opening and closing door 20 is lowered, the door 20 is pushed forward by the wedges (12) (21), the water-resistant rubber (20a) to the inner surface of the door frame (10) Tightly adhered, water is completely blocked

Here, the hydraulic built-in lifting device of the present invention is installed so that the sliding plate 900 is integrally coupled to the front and rear sliding inside the sliding block 30 installed on the upper base plate 11 of the door frame 10. Since the sliding plate (900) at the time of moving forward and backward of the opening and closing door to relieve the shock while moving forward and backward at the same time, the damage of the cylinder is completely prevented.

In addition, the hydraulic built-in lifting device of the present invention is the rotation sensor 42 to detect the pulse signal according to the permanent magnet 41 is fixed to the screw fastener 210 is rotated at the same time as the rotation of the screw 200 is approaching Since the rotation sensing device 40 is further formed, the rotation signal sensed by the rotation sensing device 40 is sent to a control panel (not shown) to accumulate and compare the rotation speed to automatically calculate the rotation speed of the hydraulic motor 850. Since at least two hydraulic cylinders are installed in the opening / closing door 20 as in the related art, the hydraulic cylinders are not synchronized and there is no phenomenon in which the operation is not smooth.

On the other hand, the hydraulic built-in lifting device of the present invention, the bearing nut 120 is formed with a cover body 130 to surround the screw 200,

Since the cover body 130 that can surround the cylinder rod 100 is integrally welded to the bottom surface of the sliding plate 900, the interior of the sliding plate 900 is covered by the cover body 130 when the cylinder rod 100 moves forward and backward. Since it is sealed, relatively large foreign substances such as sand or twigs do not penetrate into the screw 200 and the cylinder rod 100.

10: door frame 11: upper base plate
12, 21: Wedge 13: Guide rail for opening and closing door protection
20: opening and closing door 20a: index rubber
22: protrusion 30: sliding block
40: rotation detection device 41: permanent magnet
42: rotation detection sensor 100: cylinder rod
110: bottom 120: bearing nut
130: cover 200: screw
210: screw fastener 300: adapter
310,321,810,930: Bolt 320: Locking pin
400: Lower cover plate 410,910,920: Bearing
510: lower camshaft 511,521: cam body
512, 522: cam projection 520: upper cam shaft
600: rotor 610,710: gear
700: inner gear 800: upper cover plate
850: motor 850a: rotating shaft
900: sliding plate

Claims (3)

The screw fastener 210 is formed at the upper end of the bearing nut 120 integrally formed at the upper end of the hollow cylinder rod 100 in which the lower end 110 is fixed to the opening and closing door 20 having both ends coupled to the door frame 10. Screw the welded screw 200,
Fixing the adapter 300 to the upper surface of the screw fastener 210 of the screw 200 with a bolt 310,
The outer cover of the adapter 300 is installed by coupling the lower cover plate 400 using the bearing 410 so that the adapter 300 is rotatable, and a plurality of fixing pins 320 in a circular shape on the outer surface of the adapter 300. ) Tighten the bolts 321 to protrude upwards,
Bearings B1, B2 and B3 on the outer surfaces of the cam body 511 and 521 and the end binary cam protrusions 512 and 522 formed on one side of the cam body 511 and 521 to the inner surface of the adapter 300, respectively. ) And a pair of upper and lower cam shafts 510 and 520 coupled to each other (B5) so that the two end cam protrusions 512 and 522 face each other and are laminated to each other, and simultaneously to the cam protrusions 512 and 522. Coupling a pair of rotors 600, each of which has a gear 610 on the outer surface so that the inner surface is in close contact with the combined bearing (B2) (B3), respectively, to the fixing pin 320 of the adapter 300,
The inner surface of the inner gear 700 in a state in which the inner gear 700 having the gear 710 formed therein is seated on the upper surface of the lower cover plate 400 so that the gear 610 formed on the outer surface of the pair of rotors 600 is engaged. The inner cover is seated on the upper cover plate 800 so that the inner surface is coupled to the bearing (B4) of the upper cam body 521, the upper cover plate 800 and the inner gear 700 and the lower cover using the bolt 810. After fixing the plate 400 integrally,
The hydraulic motor 850 is coupled to the upper cover plate 800, and the rotary shaft 850a is coupled to the upper and lower cam shafts 510 and 520 by combining a key, and at the same time,
The inner end is inserted between the upper and lower bearings 910 and 920 coupled to the outer surface between the screw fastener 210 and the adapter 300, and at the same time, the bolt 930 is coupled to the bottom surface of the lower cover plate 400. In addition, the sliding plate (900) which is inserted into the sliding block (30) installed on the upper side of the upper base plate (11) above the door frame (10) is not installed and is only slidable before and after the door frame (10). Hydraulic built-in lifting devices installed in rivers, stormwater, sewage pumping stations, dams, water purification plants, sewage, wastewater, livestock, manure treatment plants, and industrial, residential, new cities, and urban development complexes. The method of claim 1,
Insert the slide bearings (S1) (S2) (S3) in the middle and upper and lower portions of the pair of rotor 600 is further installed to minimize the contact friction of each part during the rotation of the rotor 600 Hydraulic built-in lifting devices installed in rivers, stormwater, sewage pumping stations, dams, water purification plants, sewage, wastewater, livestock, manure treatment plants, and industrial, residential, new urban and urban development complexes. The method of claim 1,
The permanent magnet 41 is fixed to the screw fastener 210 welded to the upper end of the screw 200,
The outer surface of the cover body 130 welded to the lower side of the sliding plate 900 detects a pulse signal due to the proximity of the permanent magnet 41 fixed to the screw fastener 210 which rotates simultaneously with the rotation of the screw 200. By further installing and configuring the rotation detection device 40 by installing a rotation sensor 42 that can be,
The rotation signal sensed by the rotation sensing device 40 is sent to the control panel to accumulate and compare the rotational speed to automatically adjust the rotational speed of the hydraulic motor 850 to adjust the appearance length of the cylinder rod 100 according to the opening and closing door. Hydraulic system installed in rivers, rainwater, sewage pumping stations, dams, water purification plants, sewage, wastewater, livestock, manure treatment plants, and industrial, residential, new cities, urban development complexes Built-in lifting device.

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