KR20110004637A - Apparatus for sizing the housing of a catalytic converter - Google Patents

Abstract

PURPOSE: A sizing device of a housing for a catalytic converter is provided to extend service life and to reduce manufacturing costs by reducing the load capacity of a servo system. CONSTITUTION: A sizing device of a housing for a catalytic converter comprises top and bottom die assemblies(10,20). The top die assembly is transferred to top and bottom by the oil-hydraulic circuit. An upper die(13) of the top die assembly has a tapered surface on an inner diameter. The bottom die assembly is up and down moved with the servo system.

Description

Sizing device for housing for catalytic converter {APPARATUS FOR SIZING THE HOUSING OF A CATALYTIC CONVERTER}

The present invention relates to a catalytic converter for purifying exhaust gas, and more particularly, to a sizing apparatus of a housing for a catalytic converter, which can significantly reduce its manufacturing cost by reducing a load capacity of a servo system.

As is well known, an exhaust system of a vehicle is a device that is disposed on the floor of the vehicle floor and removes noise and impurities of various exhaust gases generated in an engine and discharges them to the outside. And one or more silencers that reduce noise by imparting flow resistance to the exhaust gas discharged from the engine, and carbon dioxide and water that are harmless to the human body by oxidizing and reducing hydrocarbons, carbon monoxide and nitrogen oxides, which are harmful substances in the exhaust gas. And catalytic converters for converting to nitrogen, oxygen, and the like.

Generally, the catalytic converter includes a cylindrical catalyst carrier, a mat wrapped on the outer circumferential surface of the catalyst carrier, and a cylindrical housing for receiving the catalyst carrier on which the mat is wrapped. In particular, the mat is composed of a heat-resistant fiber material, and the catalyst carrier is interposed between the catalyst carrier and the housing to secure the sealing property to prevent the unpurified exhaust gas from escaping between the catalyst carrier and the housing. It provides elastic support, insulation between the catalyst carrier and the housing. Therefore, the role of the mat is very important to maintain the performance of the catalytic converter for a long time.

In the catalyst converter manufacturing method according to the prior art, an operation step of calculating a gap volume density (GBD, Gap Bulk Density; GBD value) by measuring the outer diameter of the catalyst carrier, the weight of the mat, etc., on the outer peripheral surface of the catalyst carrier After lapping the mat, a stuffing step is inserted into the cylindrical housing, and the catalyst carrier and the sizing step of reducing the housing corresponding to the GBD value of the mat. Typically, the GBD value refers to the amount of compression of the mat between the catalyst carrier and the housing.

On the other hand, a sizing device for reducing the outer diameter of the housing is shown in FIG. In this conventional sizing apparatus, as shown in FIG. 1, the upper die 1 is fixedly disposed at the upper side, and the plurality of split jaws 2 are disposed at the lower side of the upper die 1 in the servo system 3. It is installed and configured to be movable up and down by). The split jaws 2 are installed to be movable in the radial direction, and the plurality of split jaws 2 are moved upwardly by the servo system 3 to pressurize the outer diameter of the catalyst converter housing 5 while moving in the inner diameter direction. It is comprised so that the housing 5 may be appropriately reduced in diameter.

However, the conventional sizing device applies a high capacity servomotor to the servo system 3 as the upper die 1 is configured to lift only the split jaws 2 by the servo system 3 while the upper die 1 is fixed. As a result, the manufacturing cost is high, and a high load is generated during the shaft machining of the split jaws 2, which causes excessive load on the servo motor side, resulting in shortening of lifespan and increasing maintenance cost.

The present invention has been made in view of the above, and the lower die load and the lower die drive of the upper die during shaft diameter machining of the catalytic converter housing, thereby reducing the load capacity of the servo system to reduce the manufacturing cost The purpose of the present invention is to provide a sizing device for the catalytic converter that can reduce the cost and extend the service life and reduce the maintenance cost.

The preferred embodiment of the present invention for achieving the above and the object,

An upper die assembly having an upper die installed to be movable up and down by a hydraulic system and having a tapered surface formed on an inner diameter surface thereof; And

It is installed so as to be movable up and down by a servo system, and has a plurality of split jaws, and a tapered surface is formed on the outer surface of each divided jaw, and the tapered surfaces of the divided jaws are in sliding contact with the tapered surface of the upper die. Including a lower die assembly;

The servo system includes a servo motor, a first driving block moving in a horizontal direction by driving of the servo motor, and a second driving block moving in a vertical direction by the second driving block. The lower die assembly is moved up and down by vertical movement.

The drive screw has a male screw portion on its outer circumference, a through hole is formed in a horizontal direction inside the first driving block, a female screw portion is formed on an inner diameter surface of the through hole, and the male screw portion of the female screw portion is relative to the female screw portion. Characterized in that the screw is installed to move.

A tapered surface is formed on an upper surface of the first driving block, a tapered surface is formed on a lower surface of the second driving block, and the tapered surface of the first driving block slides in contact with the tapered surface of the second driving block. .

The upper die assembly,

An upper die plate installed up and down by a hydraulic cylinder;

An upper support fixedly mounted to a lower portion of the upper die plate; And

And an upper die fixed to the lower portion of the upper support, the upper and lower openings having a cylindrical shape, and having a tapered surface on an inner diameter surface thereof.

The lower die assembly,

A lower die plate installed to be movable up and down by a servo system;

A lower support block installed on an upper portion of the lower die plate and configured of first to third support plates stacked in a vertical direction; And

It includes; a plurality of split jaw installed on the upper portion of the lower support block to be movable in the radial direction.

The first support plate is installed on the upper surface of the lower die plate, the second support plate is installed on the upper surface of the first support plate, the third support plate is installed on the upper surface of the second support plate, the third A bulge protrudes from the center of the support plate, a guide pin is radially installed at the ridge, and an annular frame having an "a" shaped cross section is installed at the edge of the third support plate.

The divided jaws are divided in the circumferential direction, and the outer diameter end of each divided jaw is supported by an annular frame, and the plurality of divided jaws are individually guided by the guide pins.

According to the present invention as described above, the upper die assembly is driven up and down by the hydraulic system, the lower die assembly is driven up and down by the servo system to significantly reduce the energy consumption or load capacity of the servo system to reduce the manufacturing cost and In addition, there is an advantage that can be implemented to extend the service life and reduce the maintenance cost.

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

2 to 4 is a view showing a sizing device of the housing for the catalytic converter according to an embodiment of the present invention.

As shown in FIG. 2, the sizing apparatus of the housing for a catalytic converter according to the present invention includes a sizing frame 100, an upper die assembly 10 and a sizing frame installed so as to be movable up and down on the sizing frame 100. A lower die assembly 20 is installed to be movable up and down at the bottom of the 100.

The sizing frame 100 is composed of an upper block 110 and a lower block 120 spaced a predetermined distance below the upper block 110, a plurality of guides between the upper block 110 and the lower block 120. 130 is installed in the longitudinal direction.

The upper die assembly 10 includes an upper die plate 11, an upper support 12 provided below the upper die plate 11, and an upper die 13 fixed to the lower portion of the upper support 12. .

The hydraulic cylinder 15 is provided in the upper part of the upper die plate 11, and the upper die plate 11 is being fixed to the rod 15a of this hydraulic cylinder 15. As shown in FIG. Thus, the upper die plate 11 moves up and down by driving the hydraulic cylinder 15.

The upper support 12 is fixedly mounted to the lower portion of the upper die plate 11, and a through hole 12a is formed in the lower center of the upper support 12, and an upper die is formed around the through hole 12a. (13) is fixedly mounted.

The upper die 13 is formed in a cylindrical shape with an open top and bottom, and a tapered surface 13a is formed on the inner diameter surface thereof.

The lower die assembly 20 includes a lower die plate 21, a lower support block 22 fixed to an upper portion of the lower die plate 21, and a plurality of radially movable upper portions of the lower support block 22. It includes a split jaw (23) of.

A servo system 30 is installed below the lower die plate 21, and the lower die plate 21 moves upward and downward by the servo system 30.

The lower support block 22 is installed on the upper portion of the lower die plate 21, the lower support block 22 is composed of the first to third support plates 22a, 22b, 22c stacked in the vertical direction, The first support plate 22a is fixed to the upper surface of the lower die plate 21 through fasteners, and the second support plate 22b is fixed to the upper surface of the first support plate 22a through fasteners, and the second The third support plate 22c is fixed to the upper surface of the support plate 22b through the fastener. In the center of the third support plate 22c, a ridge 22d protrudes from the center thereof, and the ridge 22d is provided with a guide pin 23b to be described later radially. At the edge, an annular frame 22e having a "a" shaped cross section is fixed through the fastener. Thus, as the lower support block 22 adopts a structure in which the plurality of support plates 22a, 22b, and 22c are laminated and assembled together, the assembly jaw 23 is improved and the assembly of the divided jaws 23 is performed. Replacement or repair can be facilitated.

The divided jaws 23 are divided in the circumferential direction as shown in FIG. 4, and the outer diameter end of each divided jaw 23 is supported by the annular frame 22d. The plurality of split jaws 23 are installed to be movable in the radial direction, and the respective divided jaws 23 are guided individually by the guide pins 23b, so that the radial movement thereof can be precisely performed.

In addition, each of the divided jaws 23 has a tapered surface 23a on its outer surface, and the tapered surface 23a is provided to slide while contacting the tapered surface 13a of the upper die 13.

The cylindrical housing 101 of the catalytic converter is mounted on the inner diameter surfaces of the plurality of split jaws 23, and the plurality of split jaws 23 move in the inner diameter direction to press the outer circumferential surface of the cylindrical housing 101. Accordingly, the cylindrical housing 101 may have its outer diameter reduced in correspondence with the catalyst carrier and the mat.

The servo system 30 includes a servo motor 31, a drive screw 32 rotating by the servo motor 31, a first drive block 33 moving horizontally by rotation of the drive screw 32, The second drive block 34 which moves in the vertical direction by the first drive block 33, and the transmission mechanism 35 for transmitting the driving force of the servo motor 31 to the drive screw 32 side.

The servo motor 31 is a control electric motor having a range of fast response and wide speed control, and may be composed of various kinds of servo motors such as a DC servo motor and an AC servo motor according to its power source.

The drive screw 32 has a male screw portion 32a on its outer circumferential surface, and the male screw portion 32a is provided so as to move relative to the female screw portion 33c side of the first driving block 33 described later. By the rotation of the drive screw 32, the male screw portion 32a and the female screw portion 33c relatively move, and thus the first driving block 31 moves in the horizontal direction. The servo motor 31 is connected to the rear of the drive screw 32 through the electric mechanism 35.

The first driving block 33 is installed to be movable in the horizontal direction, and a tapered surface 33a is formed on the upper surface of the first driving block 33, and penetrates in the horizontal direction inside the first driving block 33. The hole 33b is formed, and the female screw part 33c is formed in the inner diameter surface of this through hole 33b. The female screw portion 33c of the first driving block 33 is provided so that the male screw portion 32a of the driving screw 32 is relatively screwed.

The second driving block 34 is fixedly installed on the lower surface of the lower die plate 22 through a fastener, etc., and a tapered surface 34a is formed on the lower surface of the second driving block 34, and the second driving block A tapered surface 33a of the first drive block 33 is slid while contacting the tapered surface 34a of 34.

The transmission mechanism 35 is interposed between the servo motor 31 and the driving screw 32 and is composed of various transmission mechanisms such as a gear transmission mechanism and a belt transmission mechanism to drive the driving force output through the output shaft of the servomotor 31. It can be delivered to the screw 32 side.

By the configuration of the servo system 30, when the servo motor 31 is driven, the driving force of the servo motor 31 is transmitted to the drive screw 32 side through the transmission mechanism 35, and thus the drive screw 32 Rotates. By the rotational driving of the driving screw 32, the male screw portion 32a of the driving screw 32 and the female screw portion 33c of the first driving block 33 perform a relative screw movement, and thus the first driving block ( 33) moves in the horizontal direction.

As the first driving block 33 moves in the horizontal direction, the tapered surface 33a of the first driving block 33 slides while contacting the tapered surface 34a of the second driving block 34. One driving block 33 is moved in the vertical direction by the relative sliding operation of the tapered surfaces (33a, 34a), in conjunction with the lower die assembly 20 can move in the vertical direction.

The operating relationship of the present invention configured as described above will be described in detail as follows.

First, the housing 101 for the catalytic converter is mounted on the inner diameter surfaces of the split jaws 23 of the lower die assembly 20, and in this state, the lower die plate of the lower die assembly 20 by the servo system 30 is mounted. 22) to the upper position to a certain position.

In such a state that the lower die assembly 20 moves upward, the upper die assembly 10 is moved downward by the hydraulic cylinder 15. In more detail, when the rod 15a is lowered by the driving of the hydraulic cylinder 15, the upper die plate 11 is also lowered, so that the taper surface 13a of the upper die 13 is divided into a jaw ( Sliding in contact with the tapered surfaces (23a) of the 23, thereby the plurality of split jaws (23) can move in the inner diameter direction. As the plurality of split jaws 23 move in the inner diameter direction, the inner diameter surfaces of the split jaws 23 may press the outer surface of the housing 101 for the catalytic converter to reduce the outer diameter of the housing 101.

As described above, the present invention has an advantage of reducing the outer diameter of the catalytic converter housing 101 more precisely by applying a structure for lowering the upper die assembly 10 after the operation of raising the lower die assembly 20. .

In addition, the present invention raises the lower die assembly 20 in a state where the housing 101 for the catalytic converter is simply seated in the lower die assembly 20 (that is, under a low load), and a load is applied (ie As the upper die assembly 10 is configured to be lowered by the hydraulic cylinder 15 in the reduction operation of the housing 101, not only the load capacity of the servo system 30 is greatly reduced, but also its power consumption is reduced. It consumes less, and therefore, there is an advantage that it is possible to extend the service life or to reduce the maintenance cost.

In particular, the lower die assembly 20 of the present invention has a structure in which the upper movement proceeds in a state where the housing 101 for the catalytic converter 101 is simply seated on the inner diameter surfaces of the plurality of split jaws 23, that is, the load capacity is small. By applying, the servomotor 31 of low capacity can be applied. As a result, since the power energy or load state required on the servomotor 31 side is small, the manufacturing cost and maintenance cost are greatly reduced.

1 is a cross-sectional view showing a sizing apparatus of a housing for a catalytic converter according to the prior art.

Figure 2 is a front sectional view showing a sizing device of the housing for the catalytic converter according to an embodiment of the present invention.

3 is an enlarged view of an arrow A portion of FIG. 2.

FIG. 4 is a view along the line B-B in FIG. 2.

Brief description of symbols for the main parts of the drawings

10: upper die assembly 11: upper die plate

12: upper support 13: upper die

20: lower die assembly 21: lower die plate

22: Lower support block 23: Split jaw

Claims (6)

An upper die assembly having an upper die installed to be movable up and down by a hydraulic system and having a tapered surface formed on an inner diameter surface thereof; And It is installed so as to be movable up and down by a servo system, and has a plurality of split jaws, and a tapered surface is formed on the outer surface of each divided jaw, and the tapered surfaces of the divided jaws are in sliding contact with the tapered surface of the upper die. Including a lower die assembly; The servo system includes a servo motor, a first driving block moving in a horizontal direction by driving of the servo motor, and a second driving block moving in a vertical direction by the second driving block. Sizing device of the catalytic converter housing, characterized in that the lower die assembly moves up and down by vertical movement. The method of claim 1, The drive screw has a male screw portion on its outer circumference, a through hole is formed in a horizontal direction inside the first driving block, a female screw portion is formed on an inner diameter surface of the through hole, and the male screw portion of the female screw portion is relative to the female screw portion. Sizing device for a catalytic converter housing, characterized in that the screw movement is installed. The method of claim 1, A tapered surface is formed on an upper surface of the first driving block, a tapered surface is formed on a lower surface of the second driving block, and the tapered surface of the first driving block slides in contact with the tapered surface of the second driving block. Sizing device for a catalytic converter housing, characterized in that. The method of claim 1, The upper die assembly, An upper die plate installed up and down by a hydraulic cylinder; An upper support fixedly mounted to a lower portion of the upper die plate; And The upper die is fixed to the lower portion of the upper support, the upper and lower is formed in a cylindrical shape, the upper die having a tapered surface on the inner diameter surface; the sizing apparatus of a housing for a catalytic converter. The method of claim 1, The lower die assembly, A lower die plate installed to be movable up and down by a servo system; A lower support block installed on an upper portion of the lower die plate and configured of first to third support plates stacked in a vertical direction; And And a plurality of split jaws installed radially movable on the upper portion of the lower support block. The method of claim 5, The first support plate is installed on the upper surface of the lower die plate, the second support plate is installed on the upper surface of the first support plate, the third support plate is installed on the upper surface of the second support plate, the third A bulge protrudes from the center of the support plate, a guide pin is radially installed at the ridge, and an annular frame having an "a" shaped cross section is installed at the edge of the third support plate. The split jaws are divided in the circumferential direction, the outer diameter end of each split jaw is supported by an annular frame, the plurality of split jaws are guided individually by the guide pins, the sizing apparatus of the housing for the catalytic converter .

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