KR20090121873A - Assembling apparatus of square seal for oil pump - Google Patents

Abstract

PURPOSE: An apparatus for assembling a square seal for an oil pump is provided to automatically assemble a square seal to an oil pump, thereby preventing separation or inferior assembly of the square seal. CONSTITUTION: An apparatus for assembling a square seal for an oil pump includes a robot frame(100) which forms a working line for square seal assembly, and a square seal assembly unit(200) which is installed on one side of the robot frame to chuck and automatically assemble a square seal to an oil pump. The square seal assembly unit includes an assembly unit body, a chucking and arranging part which is connected to the assembly unit body and moves up and down to chuck and arranged the square seal to a mounting part of the oil pump, and a pressfit part which is connected to the assembly unit body and moves up and down to pressfit the arranged square seal to the square seal mounting part.

Description

Assembling apparatus of square seal for oil pump

The present invention relates to an assembling apparatus of an oil pump square chamber, and more particularly, an assembling operation of assembling the square chamber to an oil pump can be automatically performed to solve general problems caused by the conventional manual work. In particular, the present invention relates to a device for assembling a square seal for an oil pump, which can solve various problems such as the square seal does not function properly and is easily detached from the oil pump or assembled in a twisted state of the square seal.

In a typical automotive engine engine to which an oil pump can be applied, there are many parts in which a cylinder and a piston and a pair of adjacent parts, such as a crank shaft and a cam shaft, move relatively in motion.

Most of the above-mentioned parts are made of metal materials. If these parts are in direct contact with each other, the frictional heat is generated in the friction surface, which causes the friction surface to become rough and easily wear or press the parts. Triggered.

In order to prevent this phenomenon, oil is generally supplied to the friction surface. When oil is supplied to the friction surface, an oil film is formed therebetween, and the frictional resistance decreases due to the frictional heat between the two parts. It is possible to prevent the temperature rise, thereby reducing the wear phenomenon and increase the durability of the parts.

The oil which performs this role is mainly stored in an oil pan provided at the engine bottom of the vehicle and is pumped to each engine of the engine when the engine is driven. At this time, the oil pump is responsible for pumping the oil to each engine of the engine. In other words, the oil pump sucks and pressurizes the oil stored in the oil pan when the engine is driven, and sends the oil to the lubrication unit. Usually, the oil pump is coupled to one side of the engine. It is divided into cyclic type, and the like.

Looking briefly about the structure of the oil pump, the oil pump has a pump body in which a space in which oil flows is formed, and a spline shaft provided at one side of the pump body and coupled to the main part of the engine. The oil pump is provided with a square seal, a snap ring and an oil seal at different positions of the oil pump.

Since the square seal, snap ring and oil seal serve to keep the joint of the oil pump and the engine in the airtight position, it is necessary not only to be correctly assembled at the oil pump in place, but also to be strictly controlled.

In particular, in the case of the square seal, unlike the oil seal, a rubber ring having a square cross section (rubber ring) has to be assembled accurately so that the square seal is not twisted when the square seal is assembled to the square seal mounting portion of the oil pump.

However, in the prior art, since the assembling work of assembling the square seal to the oil pump has been relied on only by hand, the work is inevitably inconvenient, and there is a problem in that the yield falls due to inefficient work.

In addition, in the case of the prior art, since the workers are assembling the square thread by excessively opening the square thread in order to conveniently assemble the square thread, the elastic force of the excessively opened square thread is lost, and thus the square thread does not function properly. Various problems arise, such as being easily detached from the pump or assembled in a twisted square seal.

An object of the present invention, the assembly work of assembling the square seal to the oil pump can be automatically performed to solve all the problems according to the conventional manual work, in particular, the square seal does not function properly as in the conventional It is to provide an assembly device of the square seal for the oil pump that can solve various problems such as easily separated from the oil pump or assembled in a twisted square seal.

The object, according to the invention, the robot frame for forming a work line for the assembly of the square chamber; And a square chamber assembling unit provided at one side of the robot frame and automatically assembling the square chamber to assemble the square chamber mounting portion of the oil pump. .

Here, the square chamber assembly unit, the assembly unit body; A chucking arrangement unit connected to the assembly unit body so as to move up and down and chucking the square chamber and placing the square chamber in a square chamber mounting portion of the oil pump; And a pressing assembly unit which is connected to the assembly unit body so as to move up and down adjacent to the chucking arrangement unit, and pressurizes the square chamber disposed on the square chamber mounting unit to the square chamber mounting unit.

The square seal assembly unit, the first column is standing upright along the vertical direction on one side of the assembly unit body; A first slider coupled to the first column and moving up and down with respect to the first column, the chucking arrangement being connected to one side; And a first raising and lowering driver configured to lift and lower the first slider with respect to the first column.

The first elevating drive unit may include a first elevating rail provided between the first column and the first slider; And a first elevating cylinder fixed to the side of the first column to move the first slider up and down through the first elevating rail.

A first stopper may be further provided in a lower region of the first column to limit a falling position of the first slider.

The chucking arrangement unit may include: a plurality of chucking blocks chucking the square chamber while moving radially outward in an inner region of the square chamber, and movable radially inward and outward; And a block driver driving the plurality of chucking blocks to move the plurality of chucking blocks radially inward and outward.

The plurality of chucking blocks may be four chucking blocks arranged at equally spaced intervals along the circumferential direction.

The outer surface of each of the four chucking blocks may have an arc shape.

The pressing assembly unit, the pressing plate portion for substantially contacting the upper surface of the square chamber to press the square chamber; A plurality of pressure shafts connected to the pressure plate to move the pressure plate upward and downward; And a second raising and lowering driving unit configured to lift and lower the plurality of pressing shafts.

The second lift drive unit, the shaft connecting portion for interconnecting the plurality of pressure shafts from above; And a second elevating cylinder coupled to the first slider and having an end of the rod connected to the shaft connecting portion.

The plurality of pressing shafts may be three pressing shafts arranged at equal angle intervals along the circumferential direction, and a triangular support portion for supporting the three pressing shafts in the form of a triangle may be further provided in a central region of the three pressing shafts. have.

It may further include a rotating unit for rotating the pressing assembly a predetermined angle.

The rotating unit may include a rotating cylinder provided adjacent to the robot frame and having a rotating cylinder body and a rotating cylinder rod extending and contracting from the rotating cylinder body. A first hinge portion rotatably connecting the rotating cylinder body with respect to one side of the robot frame; And a second hinge portion for rotatably connecting the rotating cylinder rod with respect to the triangular support portion.

One side of the robot frame may be further provided with an index table provided with a plurality of cassettes for supporting the square chamber stacked in multiple stages.

The robot frame may form an in-lined work line, and the robot frame may further include a unit moving unit for moving the square seal assembly unit along the length of the robot frame on the robot frame. Can be.

A base provided on the other side of the robot frame to support the oil pump; And it may further include a loading robot for loading the oil pump of the object to the base.

According to the present invention, the assembling work of assembling the square seal to the oil pump can be automatically performed to solve all the problems caused by the conventional manual work. Various problems such as easily detached from the pump or assembled in a square seal twisted state can be solved.

In order to fully understand the present invention, the operational advantages of the present invention, and the objects achieved by the practice of the present invention, reference should be made to the accompanying drawings which illustrate preferred embodiments of the present invention and the contents described in the accompanying drawings.

Hereinafter, the present invention will be described in detail by explaining preferred embodiments of the present invention with reference to the accompanying drawings. Like reference numerals in the drawings denote like elements.

1 is a partially enlarged perspective view of a vehicle oil pump.

As shown in this figure, the vehicle oil pump 1 includes a pump main body (not shown) in which a space in which oil flows is formed, and a spline provided on one side of the pump main body and coupled to a main portion of an engine (not shown). The shaft 2 and the square chamber attaching part 3 formed in step below the spline shaft 2 are provided.

For reference, although the oil pump 1 shown in FIG. 1 is for a vehicle, the scope of the present invention is not limited thereto, but oil pumps such as other internal combustion engines or heavy equipment other than the vehicle oil pump 1 are not shown. The present invention can also be applied.

On the outer surface of the spline shaft 2, several to several tens of rows of key-shaped unevenness or male thread 2a called serration are formed at equal intervals along the circumferential direction thereof. As described above, the spline shaft 2 having the external thread 2a formed thereon is a coupling part widely used to transmit a large torque as in the engine as described above. ) And the engine's tight coupling are important, and as a result, a rigorous quality inspection such as the presence or absence of male thread 2a, machining dimensions and precision is required.

The square chamber 4 is detachably coupled to the square chamber mounting unit 3. The square seal 4 points to the rubber ring which has a square shape in cross section. The square chamber 4 is mounted on the square chamber mounting part 3 to serve to keep the coupling portion between the oil pump 1 and the engine airtight.

As such, the square seal 4 serves to keep the coupling portion between the oil pump 1 and the engine airtight, and the oil seal 6 and the snap ring 5 around the spline shaft 2 in addition to the square seal 4. ) Is further provided to keep the area airtight.

As such, the square seal 4, the snap ring 5, and the oil seal 6 serve to keep the coupling portion between the oil pump 1 and the engine at the corresponding position, so that the oil seal 1 can be precisely positioned at the corresponding position of the oil pump 1 It must be assembled.

In particular, in the case of the square chamber 4, unlike the oil chamber 6, since the cross section is a rubber ring having a square shape, when the square chamber 4 is assembled to the square chamber mounting portion 3 of the oil pump 1, the square chamber (4) must be assembled correctly so as not to twist, for this purpose, the present invention proposes the assembly device of the square seal for the oil pump as follows.

FIG. 2 is a schematic plan view of an assembly apparatus of an oil pump square chamber according to an embodiment of the present invention, FIG. 3 is a side structural view of an index table, and FIG. 4 is a square chamber showing an operation of chucking a square chamber. Partial side view of the assembly unit, FIG. 5 is a schematic plan view of the chucking portion shown in FIG. 4, and FIGS. 6 and 7 are parts of the square seal assembly unit, which are shown step by step for the operation of assembling the square seal to the oil pump, respectively. 8 is a side view, and FIG. 8 is an enlarged view illustrating main parts of FIG. 2.

As shown in these drawings, the oil pump square chamber assembly apparatus according to the present embodiment, the robot frame 100 and the robot frame 100 forming a work line for the assembly of the square chamber 4, It is provided on one side, and includes a square chamber assembly unit 200 to chuck the square chamber 4 to assemble to the square chamber mounting portion 3 of the oil pump (1).

The robot frame 100 is a part forming a work line for assembling the square chamber 4. As shown in FIG. 2, since the square chamber assembly unit 200 is coupled to the robot frame 100, the robot frame 100 is an in-lined operation related to the assembly of the square chamber 4. Form a line.

In order to form an in-lined work line in which the robot frame 100 is assembled, the robot frame 100 includes a square seal assembly unit 200 having a length of the robot frame 100 on the robot frame 100. The unit moving part 110 which moves along a direction is further provided. The unit moving unit 110 may be implemented by, for example, a linear motor, and serves to move the square seal assembly unit 200 on the robot frame 100. The robot frame 100 is further connected to the leg 120 for supporting the robot frame 100 perpendicular to the ground.

2 and 3, the index table 130 is provided at one side of the robot frame 100. The index table 130 is a disk-shaped turntable, which is rotated in one direction based on a central axis by rotating means (not shown).

The index table 130 may be provided with, for example, four first to fourth stations # 1 to # 4. Each of the first to fourth stations # 1 to # 4 is provided with cassettes 140 supporting the square chambers 4 stacked in multiple stages.

Among the first to fourth stations # 1 to # 4, the first station # 1 may be a station to which the square chamber assembling unit 200 is moved to chuck the square chamber 4 as a work target, The second to third stations # 1 to # 3 may be supply, take-out and buffer stations provided to achieve continuous supply of the square chamber 4. However, since the scope of the present invention is not limited thereto, the four first to fourth stations # 1 to # 4 are not necessarily provided in the index table 130. In addition, in some cases, the index table 130 may not be provided. In this case, a separate robot may separately provide the square chamber 4 as a work target.

As described above, when the first station # 1 is a station in which the square chamber assembling unit 200 is moved to chuck the square chamber 4 of the work target, the square chambers 4 which are symptomatically stacked in multiple stages may be provided. The position in the cassette 140 needs to be raised in turn. That is, since the distance in which the square chamber assembly unit 200 descends is generally determined to be constant, after the chucking and moving the uppermost square chamber 4 from the cassette 140, the square chamber 4 immediately underneath is returned again. It may be desirable to move to the topmost position.

To this end, as shown in FIG. 3, a square chamber lift driver 145 may be further provided in the first station # 1 area to sequentially raise the square chamber 4. As shown, the square chamber lift driver 145 may be applied in a structure in which the ball screw 145b is operated by the motor 145a to raise the lowermost square chamber 4 through the lift plate 145c. However, the scope of the present invention is not limited thereto.

Although not shown in FIG. 2, a base 150 (see FIGS. 6 and 7) provided with the oil pump 1 to which the square chamber 4 is assembled is provided on the other side of the robot frame 100.

The base 150 may be a type fixed at a corresponding position or may be a type moved along a separate work line. In the vicinity of the base 150 may be further provided with a loading robot (not shown) for loading the oil pump 1 of the target object to the base 150. The loading robot may be a rotating robot that grasps and rotates the oil pump 1 one by one at the place where the oil pump 1 is loaded, and loads the loaded robot into the base 150, but is not necessarily the case.

The square chamber assembling unit 200 is provided at one side of the robot frame 100, and chucks the topmost square chamber 4 stored in the cassette 140 of the first station # 1 to oil pump 1. Serves to assemble to the square seal mounting portion (3). That is, the square chamber assembly unit 200 moves along the robot frame 100 to chuck the square chamber 4 and then moves back to the base 150 side so that the square of the oil pump 1 loaded on the base 150 is square. It serves to assemble the square chamber (4) by the thread mounting portion (3).

As shown in FIG. 4, the square seal assembly unit 200 is connected to the assembly unit body 210 and the assembly unit body 210 so as to be moved up and down, and chucks the square seal 4 to oil. The chucking arranging unit 230 disposed on the square chamber mounting unit 3 of the pump 1 is connected to the assembly unit body 210 so as to be moved up and down and adjacent to the chucking arranging unit 230, and the square chamber mounting unit ( It is provided with a pressure assembly 250 for pressing and assembling the square chamber (4) arranged in 3) by the square chamber mounting portion (3).

In addition, the square seal assembly unit 200 is coupled to the first column 260 and the first column 260 that are erected in an up and down direction on one side of the assembly unit body 210, and the first column 260. Moving up and down relative to the first side, the first slider 270 having the chucking arrangement 230 connected to one side thereof, and the first upward and downward driving driving the first slider 270 relative to the first column 260. The driving unit 280 is further provided.

The first elevating driving unit 280 is fixed to the first elevating rail 281 provided between the first column 260 and the first slider 270 and the first column 260, and the first elevating unit A first elevating cylinder 282 for elevating and moving the first slider 270 through the rail 281 is provided.

Accordingly, when the first elevating cylinder 282 is operated to lower the first slider 270 through the first elevating rail 281 while the rod moves downward, the chucking arrangement 230 is lowered in association with the first elevating cylinder 282. On the contrary, when the rod moves upward, ascending the first slider 270 through the first raising and lowering rails 281 may also raise the chucking arrangement 230 in association with the rod.

At this time, in order to chuck the square chamber 4 existing at the top of the cassette 140, it is advantageous if the lowering position of the first slider 270 is set in advance, so that the square column assembling unit 200 has a first column ( A first stopper 290 for limiting the lowering position of the first slider 270 is further provided in the lower region of the 260.

Here, the first stopper 290 may be of a mechanical type that mechanically restricts the lowering position of the first slider 270, or generates an electrical signal when the first slider 270 contacts, thereby raising the first lowering. It may be of electronic type to stop the operation of the cylinder 282.

The chucking arranging unit 230 has a portion for chucking the square chamber 4 in the cassette 140 to be assembled to the square chamber mounting unit 3 of the oil pump 1 in the state of being lowered together with the first slider 270. All.

As shown in FIGS. 4 and 5, the chucking arrangement 230 expands radially outward in the inner region of the square chamber 4 while chucking the square chamber 4 and is movable radially inward and outward. A plurality of chucking block 231 and a plurality of chucking block 231 is provided with a block driving unit 232 for driving a plurality of chucking block 231 to move inward and outward in the radial direction.

In the present embodiment, the plurality of chucking blocks 231 are provided as four arranged at equal angle intervals along the circumferential direction, and the outer surface of each of the four chucking blocks 231 has an arc shape. This is due to the square yarn 4 having an annular shape. If the virtual outer frame connecting the outer surfaces of the four chucking blocks 231 has a square shape, since the square chamber 4 is excessively open, the elasticity of the square chamber 4 may be lost. The outer surface of each of the four chucking blocks 231 is manufactured in an arc shape so that the virtual outer frame connecting the outer surfaces of the two chucking blocks 231 can be substantially circular.

The block driver 232 serves to move the four chucking blocks 231 radially outward and inward by providing air pressure or removing the provided air pressure. That is, the four chucking blocks 231 can be moved radially outward and inward in the body 230a by providing air pressure to the area of the body 230a shown in FIG. 5 or removing the provided air pressure. Of course, in order for this operation to proceed organically, the four chucking blocks 231 in the body 230a will have to be equipped with a movement path in advance.

Accordingly, if pneumatic pressure is provided through the block driving unit 232 in the state where the four chucking blocks 231 are disposed in the inner region of the square chamber 4, the four chucking blocks 231 are inflated radially outward and are square. While chucking the yarn 4, the square yarn 4 is expanded slightly more than the original state so that the square yarn 4 can be easily assembled into the square yarn mounting portion 3. In this state, the square chamber 4 is disposed in the square chamber mounting part 3 in the state in which the square chamber 4 is expanded outward in the radial direction.

At this time, since the outer surface of each of the four chucking blocks 231 has an arc shape, the elastic force of the square chamber 4 which is excessively widened as the square chamber 4 is opened manually by the conventional method is lost and is thus square. It is possible to solve the problem that the seal 4 does not perform its proper function and is easily detached from the oil pump 1 or the square seal 4 is assembled after being untwisted.

The pressure assembly 250 serves to assemble the square chamber 4 disposed on the square chamber mounting unit 3 by the chucking arrangement 230 to the square chamber mounting unit 3 to assemble. As shown in FIG. 4, the pressure assembling unit 250 is in contact with the upper surface of the square chamber 4 and pressurizes the square chamber 4 to the pressure plate 251 and the pressure plate 251. A plurality of pressing shafts 252 connected to move the raising and lowering of the pressure plate 251 and a second raising and lowering driver 253 for raising and lowering the plurality of pressing shafts 252 are provided.

The second lift driver 253 is coupled to the shaft connecting portion 253a for interconnecting the plurality of pressure shafts 252 from the top, and the first slider 270 and the end of the rod is connected to the shaft connecting portion 253a. And a second raising and lowering cylinder 253b.

Accordingly, when the second lifting cylinder 253b is operated to move the rod downward and the number of the pressing shaft 252 and the shaft connecting portion 253a is lowered, the pressure plate 251 is lowered in association with the square chamber ( 4) can be pressurized, on the contrary, as the rod moves upwards, when the plurality of press shafts 252 and the shaft connecting portion 253a are raised, the press plate portion 251 is raised in association with the pressurization of the square chamber 4. Is released.

In the present embodiment, the plurality of pressing shafts 252 applied to the pressure assembly 250 are provided three, and are arranged at equal angular intervals along the circumferential direction. Therefore, the three pressing shafts 252 are spaced 120 degrees from each other. In the central region of the pressing shafts 252, a triangular support part 254 (see FIGS. 2, 4 and 8) for supporting the pressing shafts 252 in the form of a triangle is further provided.

On the other hand, when pressing the square chamber 4 by the operation of the three pressing shaft 252, since the three pressing shaft 252 has a 120-degree intervals between each other, the pressing force is applied to the square chamber 4 substantially. Part is bound to be limited. In this case, the square chamber 4 may not be completely uniformly adhered to the square chamber mounting portion 3, and the remaining portion where the pressing force is not provided may be somewhat excited from the square chamber mounting portion 3. In order to prevent this, there is further provided a rotation unit 240 for rotating the pressure assembly 250 by a predetermined angle. As a result, the three pressing shafts 252 initially press the square chamber 4 firstly, and the square chamber 4 presses the second square chamber 4 again while being rotated by the rotary unit 240. It is possible to closely contact the square seal mounting part 3 evenly.

2 and 8, the rotation unit 240 is provided adjacent to the robot frame 100, the length can be extended and reduced from the rotating cylinder body 241a and the rotating cylinder body 241a. A rotating cylinder 241 having a rotating cylinder rod 241b, a first hinge part 242 connecting the rotating cylinder body 241a to one side of the robot frame 100 so as to be relatively rotatable, and a triangular paper A second hinge portion 243 is provided to connect the rotating cylinder rod 241b to the branch portion 254 so as to be relatively rotatable.

As a result, when the rotary cylinder 241 is operated, the three pressing shafts 252 may be rotated by about 45 degrees by the interaction with the first and second hinge portions 242 and 243 as shown by the dotted lines in FIGS. 2 and 8. In this state, as the pressure is applied to the square chamber 4 again, the pressing force may be provided again to the remaining portion where the pressing force was not initially provided, so that the square chamber 4 is completely uniformly adhered to the square chamber mounting part 3. It can be assembled. Here, the rotation angle of the pressing shaft 252 need not necessarily be 45 degrees.

Referring to the operation of the assembly device of the square seal for oil pump having such a configuration as follows.

First, the assembling process for the square chamber 4 by the square chamber assembly unit 200 is performed. That is, the square chamber assembling unit 200 moves to the index table 130 along the robot frame 100 to chuck the square chamber 4 in the cassette 140 (the method of chucking is as follows), and the work target. Oil pump (1) is moved to the side of the base 150 is loaded and supported.

For the assembly of the square chamber 4, the pneumatic pressure is provided through the block driving unit 232 with the four chucking blocks 231 of the chucking arrangement 230 is disposed in the inner region of the square chamber 4, Accordingly, as the four chucking blocks 231 are expanded radially outward, the square chamber 4 is expanded slightly more than the original state.

In this state, when the first elevating cylinder 282 is operated and the rod is moved downward, and the first slider 270 is lowered through the first elevating rail 281, the chucking arrangement unit 230 is interlocked with this. As it is lowered, the square chamber 4 may be arranged in the square chamber mounting part 3.

Then, the pressure assembly 250 is operated in this state. That is, when the second lifting cylinder 253b is operated and the rod moves downward while the plurality of pressure shafts 252 and the shaft connecting portion 253a are lowered, the pressure plate portion 251 is lowered in association with the square chamber 4. Pressurize the primary.

When the primary pressurization is completed, the rotary cylinder 241 of the rotary unit 240 is operated to rotate the three pressing shafts 252 approximately 45 degrees by interaction with the first and second hinge portions 242 and 243. In this state, due to the operation of the second raising and lowering cylinder 253b described above, the second pressing force may be provided again to the remaining portion where the pressing force is not provided at the first time as the square chamber 4 is pressurized again. The square chamber 4 can be assembled while being completely uniformly in close contact with the square chamber mounting portion 3. When the assembly is completed, the square chamber assembly unit 200 is returned to its original position.

As such, according to the present embodiment, the assembling work of assembling the square chamber 4 to the oil pump 1 can be automatically performed, thereby solving the general problems caused by the conventional manual work, and in particular, as in the related art. It is possible to solve various problems such that the square chamber 4 does not perform its proper function and is easily detached from the oil pump 1, or the square chamber 4 is assembled in a distorted state.

As described above, the present invention is not limited to the described embodiments, and various modifications and changes can be made without departing from the spirit and scope of the present invention, which will be apparent to those skilled in the art. Therefore, such modifications or variations will have to be belong to the claims of the present invention.

1 is a partially enlarged perspective view of a vehicle oil pump.

Figure 2 is a schematic plan view of the assembling apparatus of the square chamber for the oil pump according to an embodiment of the present invention.

3 is a side view of an index table.

4 is a partial side view of the square seal assembly unit showing the chucking operation of the square seal.

FIG. 5 is a schematic plan view of the chucking part shown in FIG. 4.

6 and 7 are partial side views of the square seal assembly unit shown in stages for the operation of assembling the square seal to the oil pump, respectively.

8 is an enlarged view illustrating main parts of FIG. 2.

* Explanation of symbols for the main parts of the drawings

1: Oil Pump 2: Spline Shaft

2a: Male thread 2b: Inner hole

3: square seal mounting portion 4: square seal

5: snap ring 6: oil seal

100: robot frame 110: unit moving unit

130: index table 140: cassette

150: base 200: square seal assembly unit

210: assembly unit body 230: chucking arrangement

240: rotating unit 250: pressure assembly

260: first column 270: first slider

280: the first lift drive unit

Claims (16)

A robot frame forming a work line for assembling a square chamber; And Is provided on one side of the robot frame, the square chamber assembling apparatus for the oil pump comprising a square chamber assembly unit for automatically assembling the square chamber mounting portion of the oil pump chucking the square chamber. The method of claim 1, The square seal assembly unit, Assembly unit body; A chucking arrangement unit connected to the assembly unit body so as to move up and down and chucking the square chamber and placing the square chamber in a square chamber mounting portion of the oil pump; And It is connected to the assembly unit body so as to move up and down adjacent to the chucking arrangement portion, the oil comprising a pressure assembly for assembling the square chamber disposed in the square chamber mounting portion by pressing the square chamber mounting portion Assembly device of square seal for pump. The method of claim 2, The square seal assembly unit, A first column standing upright in an up and down direction on one side of the assembly unit body; A first slider coupled to the first column and moving up and down with respect to the first column, the chucking arrangement being connected to one side; And And a first raising and lowering driving unit for elevating and driving the first slider with respect to the first column. The method of claim 3, The first lift drive unit, A first elevating rail provided between the first column and the first slider; And And a first elevating cylinder fixed to the first column and configured to move the first slider up and down through the first elevating rail. The method of claim 3, And a first stopper for limiting the lowering position of the first slider in the lower region of the first column. The method of claim 2, The chucking arrangement unit, A plurality of chucking blocks chucking the square seal while moving radially outward in an inner region of the square seal, the plurality of chucking blocks movable radially inward and outward; And Assembly apparatus of the square chamber for the oil pump, characterized in that it comprises a block driving unit for driving the plurality of chucking blocks so that the plurality of chucking blocks move inward and outward in the radial direction. The method of claim 6, The plurality of chucking block is an assembly device of the oil seal square chamber, characterized in that the four chucking blocks are arranged at equal intervals between each other in the circumferential direction. The method of claim 7, wherein The outer surface of each of the four chucking block has an arc (arc) shape assembly device for the oil pump, characterized in that the arc (arc) shape. The method of claim 3, The pressure assembly, A pressure plate portion which is in contact with an upper surface of the square chamber to press the square chamber; A plurality of pressure shafts connected to the pressure plate to move the pressure plate upward and downward; And And a second elevating drive unit for elevating and driving the plurality of pressurized shafts. The method of claim 9, The second lift drive unit, A shaft connecting portion interconnecting the plurality of pressing shafts from above; And And a second raising and lowering cylinder coupled to the first slider and having an end of the rod connected to the shaft connection part. The method of claim 9, The plurality of pressing shafts are three pressing shafts are arranged with an equiangular interval therebetween in the circumferential direction, An apparatus for assembling a square chamber for an oil pump, characterized in that a triangular support portion for supporting the three pressing shafts in the form of a triangle is provided in the central region of the three pressing shafts. The method of claim 11, Assembly apparatus of the oil seal square chamber further comprises a rotating unit for rotating the pressure assembly portion a predetermined angle. The method of claim 12, The rotating unit, A rotating cylinder provided adjacent to the robot frame and having a rotating cylinder body and a rotating cylinder rod which is provided to extend and contract from the rotating cylinder body; A first hinge portion rotatably connecting the rotating cylinder body with respect to one side of the robot frame; And And a second hinge portion for rotatably connecting the rotating cylinder rod with respect to the triangular support portion. The method of claim 1, One side of the robot frame is an assembly device of the square chamber for oil pump, characterized in that the index table is provided with a plurality of cassettes for supporting the square chamber stacked in multiple stages. The method of claim 1, The robot frame forms an in-lined work line, The robot frame is a square chamber assembly device for oil pump, characterized in that the unit moving unit for moving the square chamber assembly unit in the longitudinal direction of the robot frame on the robot frame is further provided. The method of claim 1, A base provided on the other side of the robot frame to support the oil pump; And The assembly device of the oil seal square chamber further comprises a loading robot for loading the oil pump of the operation target to the base.

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