KR850000547B1 - Process for cryogenic shot-blasting - Google Patents

Abstract

A shot-blasting method in the low temperature is characterized by eliminating in low temperature selected substance on the group of paint, other materials and their mixture from a material object by an suitable medium. This method is composed of fourth steps followed. The first step transfers the selected substance through applied part maintained in the state of low temperature, the second step passes a freezing material through applied part, the third step throwes the above substance in high speed in applied part and the last step removes object which completely eliminated the above selected substance from applied part.

Description

Low temperature shot-blasting method

1 is a front view of an apparatus for practicing the method of the present invention.

2 is a plan view of the device of FIG.

3 is a cross-sectional view taken along line 3-3 of FIG.

4 (a) and 4 (b) are diagrams showing two examples of a seal mechanism used in the present invention.

5 is a partially enlarged view of a seal mechanism used in the present invention.

6 is an enlarged cross-sectional view taken along line 6-6 of FIG.

FIG. 7 shows shielding means for protecting the sealing mechanism of FIG. 4 from being damaged by a high speed shot medium.

8 shows the effect of using two projection wheels rotating in the same direction.

9 is a diagram showing advantages obtained by using a double inverted projection wheel.

The present invention relates to a cryogenic shot-blasting method, and more particularly to a cold shot-blasting method which is particularly suitable for the treatment of relatively large objects, relatively heavy objects and / or objects with relatively sophisticated tips. The present invention is also adapted to achieve such an object in continuous operation, and the present invention relates to Korean Patent Application No. 81-867 (Low Temperature Shot Blasting Device) filed on March 17, 1981. .

Conventionally, low temperature flash removal techniques have been used to remove flash from molded synthetic resins and rubber products or to remove paint or coatings from various products. However, the prior art has only been applied to relatively small parts such as 0-rings, bushings, and other articles small enough to be held by a palm. The technique involves contacting the object with a cryogen, such as liquid or gaseous nitrogen, to lower the temperature of the object to the point where the main body of the object is large and not brittle and relatively thin flashes are brittle. It is common to include things to be done. Similarly, the coated article is contacted with a refrigerant to break the coating or to lower the aggregate strength of the coating on the object. Thereafter, a high speed flash removal media flow is applied to the object where the flash or cladding is brittle by low temperatures. However, representative of the medium is granulated steel or plastic shot.

Typical devices for achieving this result operate in a batch or semi-batch manner, in which the object to be treated is introduced into an insulated chamber containing an endless belt. The endless belt is designed so that in its operation the objects roll and tumble together. Then, the objects in the insulated chamber are contacted with a refrigerant to break the flash on the object, and then a high speed flash removal media flow is applied to the object group. After a reasonable time of operation, the introduction of the refrigerant and the collision with the short are stopped and the flash-removed product is withdrawn from the flash removal chamber.

When processing oversized articles or flash-removing articles with denser elements than plastic or rubber, such tumbling techniques, which are very satisfactory for small objects, are also not practical. One of the reasons is that the size of the chamber must be undesirably large to cool down to low temperatures in order to tum that object when each object is large. This will undesirably increase the operating costs, capital and required floor space of the required process. Another problem with large objects occurs when the size of the object is equal to or larger than the size of the short injection type applied to the object. When an object is small compared to its short spray form, irregular tumbling of the object may be suitable to allow the flash to be fully exposed to short flow for a significant amount of time, but for relatively large objects, irregular tumbling may cause Proper adjustment of short application to all required areas can be provided.

Another problem exists when there is a difference in the density of parts such as metal hubs and automotive steering wheels with metal spokes and plastic rims. In such a case, tumbling the steering wheels may cause at least wear of the plastic rim when the plastic team of one steering wheel hits the metal hub of the other steering wheel.

Another problem exists when the product to be treated is heavy, but has delicate tips that cannot withstand the rugged contact of tumbling.

Accordingly, what is needed is a method and apparatus that can perform an advantageous low temperature flash removal operation to properly expose the flash to the flow of the shot medium without requiring tumbling techniques unsuitable for relatively large bodies such as steering wheels, and also batch operation. It has been desired to perform flash removal operations on such objects more effectively and continuously than by expressions.

The present invention provides a method for performing shot blasting on an object under cold conditions. The device claimed in the earlier application mentioned at the outset includes a housing for the introduction, the application and the discharge. Means for continuously conveying the object to be shot blasted from the inlet to the outlet via the application are provided in connection with the housing, and means for introducing a refrigerant into the application to keep the application low temperature. It is connected. The apparatus also has means for applying a high speed medium to the article while the object to be processed is transported through the application. The apparatus for carrying out the method of the present invention also acts to rotate the object while the object is transported through the application so that the flow of media contacts all parts of the object.

In one embodiment of such a device, the housing also has an inlet through which the inlet communicates with the outside of the housing, and an outlet through which the outlet communicates with the outside of the housing. The inlet and outlet and the structure and relative positions of the applicator are arranged such that the applicator is located between the inlet and the outlet and at a lower position than the inlet and outlet. This structure forms a recessed receptacle for containing the refrigerant in the device, in particular in the application. In addition, the inlet and outlet are located higher than the application, the outlet being located higher than the inlet, such that the refrigerant injected into the device first fills the application and then rises in the device until an escape means is found. Is formed. In this device, the escape means through which the ascending refrigerant can escape for the first time is an inlet. Thus, a situation arises where the refrigerant injected into the device attempts to escape through the inlet at the lower position, but the object from which the flash is to be removed is pushed away from the inlet by moving the object from the inlet to the outlet through the flash remover. Some mechanical sweeping action is done. If the difference in their positions is sufficient, a flow of refrigerant in the reverse direction to the direction of movement of the object can occur.

The specific means used in this apparatus for applying the medium to the object to be treated may be conventional means used in the present technology such as, for example, wheels for throwing. Various specific structures for such devices are well known in the art.

In general, such a device is operated by sending a shot medium to a partitioned rotary device so that the shot medium is given an angular velocity of the projection wheel, and the medium is blown to the projection wheel by a centrifugal force applied to the shot medium. Will crash. In this field, it is preferable to use a plurality of such wheels for applying the shot medium to the object to be processed. In particular, this device uses rotating projection wheels discharged to rotate in the horizontal plane.

As will be explained in more detail later, a projection-shaped "shade" may be formed behind the object when using multiple projection wheels that rotate in the same direction while moving the object through the flash removal portion. To counteract this, the present invention uses two projection wheels that rotate in opposite directions. In order to eliminate the problems which may be caused by the overlap of the projection directions of the shot medium, the rotary projection wheels in this example are arranged to rotate on different parallel faces. This avoids the problems caused by projecting the shot medium by the other projection wheel directly to the shot medium projected by one projection wheel. In addition, the use of the projection wheels on the other sides allows the shot medium to be projected on a large portion of the object.

The specific means for transferring the object to be processed through the instrument includes a mounting rod extending through a throat formed in the wall of the housing. The slot passes through the entire distance that the object will be transported through the application, and preferably the slot passes over the entire part of the device from the inlet to the outlet. One end of the mounting rod is located in the housing and is adapted to engage the object to be processed. The other end of the wood rod is located on the side of the housing and is connected to means such as a sprocket chain for moving the mounting rod through the application. Typically, as with a sprocket chain, this means is used to move the mounting rod out of the device from one outside point of the device past the inlet, application and outlet.

In the apparatus for carrying out the method of the present invention, the means for rotating the object is connected to the mounting rod to rotate the rod, thereby rotating the object engaged at one end of the mounting rod. The means for rotating the object have an outer periphery suitable for engaging the track so that the coaxially mounted wheel is rotated to rotate the mounting rod, for example when moved coaxially on the mounting rod. The particular way in which a coaxially mounted wheel engages a track may be a frictional engagement between the outer periphery of the wheel and the track, or the wheel may have a series of teeth on its periphery, such as a gear that engages a rack-shaped track.

It will be understood, of course, that in order to prevent the escape of the refrigerant from the device, in particular from the flash removal part, in the slot of the device wall, a seal is provided which acts to pass the mounting rod but prevent the escape of the refrigerant. will be. Particularly preferred forms of such seals will be described in more detail later in connection with the description of the accompanying drawings. The method of the present invention for the low temperature removal of undesirable substances selected from the group consisting of flashes, paints, other coatings and mixtures thereof from an object by means of a suitable medium, such as a shot, comprises: (1) Rotating an object with a substance that is not in the material, passing it through an application kept at a low temperature, (2) passing a refrigerant through the application so that the undesirable substance on the object is brittle, and (3) the object is applied. Projecting the medium at high speed within the application unit in such a way as to maximize the number and angle of impact of the medium on the rotating object when it is transported through the unit, and (4) applying the object from which the undesirable substance is actually completely removed. It consists of steps to remove from.

The invention is described in more detail below with reference to the accompanying drawings.

1 and 2 show front and plan views of an apparatus for implementing the method of the invention suitable for removing the flash by shot blast. The device has an insulating housing 10 containing its essential elements, in particular parts which are kept under cold conditions.

In general, the device can be described as having a central flash remover 12. On the right side of FIG. 1, an introduction tunnel 14 extending from the flash removing unit 12 to the upper right is shown, and on the left side of FIG. 1, an outlet tunnel 16 extending from the flash removing unit 12 to the upper left is shown. Tunnels 14 and 16 form the inlet and outlet, respectively, described above. The entire device is shown as being positioned at a convenient height above the floor by a support angle 18.

The refrigerant removal tube 20 is installed in the flash removing unit 12, and the introduction tube 20 is connected to the refrigerant manifold line 22 in the flash removing unit 12, and the manifold has two outlets 23. In addition, the flash removing unit 12 is provided with hoppers 24 and 26 for receiving and retaining the shot medium before being transferred to the projection wheels 32 and 34 through the supply lines 28 and 30, respectively. The projection wheels 32 and 34 are arranged to rotate in the horizontal plane, and the projection wheels are arranged up and down with each other.

The drive motor 36 is connected to the projection wheels 32 and 34 by rings 38 and 40, respectively. In operation, the shot medium from the hoppers 24 and 26 moves down vertically via feed lines 28 and 30, respectively, and is introduced into the projection wheels 32 and 34, respectively. As shown in FIG. 2, the projection wheels 32 and 34 contra-rotate with the projection wheel 32 shown to rotate counterclockwise. On the other hand, the projection wheel 34 is shown to rotate clockwise.

1 and 2, a pair of parallel endless drives 42 and 44 are shown.

The drive chain is adapted to move through corresponding passages of parallel vertical surfaces on the same side of the housing 10. The drive chain 42 is located closely to the housing 10 and the drive chain 44 is located away from the housing.

The drive chains run along an endless passage around the idler wheel 46 and the drive wheel 48. The idler wheel 46 and the drive wheel 48 may be sprocket wheels designed to engage drive chains 42 and 44. The endless passageway through which the drive chains 42-44 pass, starts at drive wheel 48, moves upwards around the idler wheel 46, runs clockwise, passes through the inlet tunnel 14, enters the flash removal unit 12, and then travels left. Return to drive wheel 48 via discharge tunnel 16. The slots 50 extending through the common front wall 52 and the tunnels 14 and 16 of the housing 10 are arranged on the same surfaces formed by the drive bodies 42 and 44, generally coincident with the passages of the drive bodies 42 and 44. Thus, the mounting rod 54 can engage the drive body 42,44 and extend through the slot 50 into the housing 10 and the tunnel 14,16. Specific functions and operating methods of the mounting rod will be described later with reference to FIG.

An auger 56 designed to transport the shot medium with the removed flash dropped to the bottom of the housing 10 is disposed along the bottom of the housing 10. The auger 56 operates to move the short-flash mixture to the right as shown in FIG. 1, at the right part of which the mixture is removed from the housing 10 via conduit 58 and then to the short medium separator 60. Is sent. After the short medium is separated from the removed flash pieces, the separated medium is transferred to the absorbers 24 and 26 via the supply line 62.

As can be seen in FIGS. 1 and 2, inlet tunnel 14 is provided with inlet 64 and outlet conduit 16 with outlet 66. Its inlet and outlet are shown in more detail in FIG. 2 and provide a means for the introduction and ejection of an object to be flash removed in housing 10. It can be seen from FIG. 1 that the outlet 66 is located above the flash remover 12. This structure provides a "storage space" in housing 10 for the collection of refrigerant injected into the flash remover 12 through the refrigerant outlet 23. It can also be seen that the outlet 66 is arranged higher than the inlet 64. In addition, since the inlets and outlets 64 and 66 are located higher than the inlet 64, the refrigerant flows from the flash removing section 12 to the inlet tunnel 14 and is discharged out of the housing 10 through the inlet 64. This ensures an active flow of refrigerant in this direction, precooling the objects to be flash-removed as they enter the housing 10 through the introduction tunnel 14.

Other features of the invention are shown in detail in FIG. The figure shows an enlarged cross-sectional view of the flash remover 12 taken along the line passing through the absorber 24 and the projection wheel 32. In the figure, the supply line 28 is shown filled with the shot medium 29 supplied to the projection wheel 32. Also shown in FIG. 3, the lower portion of the flash remover 12 consists of a short medium and sidewalls concentrating in a V-shape which serve to concentrate the removed flash toward the auger 56. As shown in FIG.

In particular, FIG. 3 shows a steering wheel 68 to be mounted on one end of the mounting rod 54 and positioned within the housing 10. The drive rods 42 and 44 are engaged with the mounting rod 54 on the outer side of the housing 10 opposite to the end of the mounting rod 54 on which the steering wheel 68 is mounted. The mounting rod is also shown as passing through slot 50 of the front wall 52 of the housing 10.

The wheel 70 coaxially mounted to the mounting rod at one point of the mounting rod 54 between the outside of the housing 10 and the portion of the mounting rod passing through the slot 50 and the portion of the mounting rod engaging the drive chain 42 is detailed in FIG. 3. Is shown. A track 72 is mounted just below the slot 50 on the outer surface of the front wall 52. The wheel 70 and the track 72 are sized so that the outer circumference of the wheel 70 frictionally engages the track 72 and are arranged side by side. In addition, the engagement of the mounting rods 54 to the drive bodies 42 and 44 is such that the mounting rods can move laterally along the length of the slot 50 while rotating about the longitudinal axis thereof.

However, wheel 70 is secured to mounting rod 54 such that wheel 70 frictionally engages track 72 when mounting rod 54 is moved laterally along slot 50, causing wheel 70 and its attached mounting rod 54 to rotate. . Thus, the steering wheel 68 rotates as it moves through the flash removal unit 12.

It is important to the effective operation of the present invention that a means to prevent freeze escape escape through slot 50 from within housing 10 is provided. For this purpose, a seal mechanism is provided in slot 50. The seal shown in FIG. 3 consists of two strips of material that are flexible at low temperatures. As shown in FIG. 3, flexible strips 74 and 75 are mounted on the outer surface of the front wall 52 directly adjacent to both axes (upper and lower) of the slot 50. As shown in FIG. Each of these flexible strips 74,75 is sized to extend to at least half the width of the slot 50 and is at least equal to the diameter of the mounting rod 54. In addition, each of the strips is bent to extend into the opening inner axis of slot 50 toward the interior of the housing such that portions of the surfaces of strips 74 and 75 face to each other to achieve a seal. Also shown in FIG. 3 are elastic brushes 76 and 77 disposed in slot 50 and supported on flexible strips 74,75.

In operation, when the mounting rod 54 moves along the length of the slot 50, the flexible strips 74, 75 are forcibly separated from one another so that the mounting rod 54 can pass through the slot 50. After mounting rod 54 passes through a specific portion of slot 50, elastic brushes 76,77 again contact the separate portions of flexible strips 74 and 75 to form a seal. In this way, the mounting rod 54 can pass freely along the length of the slot 50 while keeping the seal along the length of the slot 50 to prevent refrigerant from escaping from the interior of the housing 10.

Specific examples of sealing means are shown in more detail in FIG. 4 (a). The figure shows an enlarged, cross-sectional view of slot 50 along a line through sidewall 52. As shown in this figure, the flexible strips 74,75 are supported on the surface of the mounting rod 54, and this shape is held by the elastic brushes 76,77 to hold the seal around the mounting rod 54.

5 is another view of the seal mechanism seen from the front wall 52. As shown in this figure, the flexible strips 74,75 mounted adjacent to the upper and lower edges of the slot 50 are forced to face contact by the brushes 76,77 to retain the seal. Mounting rod 54 also causes the flexible strip 74,75 to fall off as he passes along slot 50.

FIG. 6 is an enlarged cross-sectional view taken along line 6-6 of FIG. 5 showing flexible strips 74,75 which face each other to form a seal. In this figure, it can be seen that the brushes 76,77 force the flexible strip 74,75 to maintain such a face contact relationship.

과 동일하고 장착봉 54의 직경보다 큰 길이만큼 슬로트 50을 가로질러 하방으로 연장하여 있다. 가요성 스트립 74에서와 같이, 이 가요성 스트립 74(b) 역시, 슬로트 50내측으로 연장하고, 장착봉 54의 상부부분에 지탱되어 있도록 휘어있다. 제4(b)에서, 슬로트 50의 하측으로부터 연장하는 가요성 스트립이 설치되지 않고, 그 슬로트 50의 하연부를 따라 낮은 마찰계수의 가스켓트 78이 취부되어 있다. 그 가스켓트는 장착봉 54의 하측에서 그 장착봉에 접촉하여 그 장착봉 54와 밀봉관계를 유지하도록 설계되어 있다.In Fig. 4 (b), another structure of the sealing mechanism is shown, and as described in connection with Figs. 3, 4 (a), 5 and 6, the front just above the slot 50 is shown. A flexible strip 74 (b) is attached to the barrier 52, which is attached to the flexible strip 74 (b), and the flexible strip 74 (b) has at least the width of the slot 50.

And extends downward across slot 50 by a length greater than the diameter of mounting rod 54. As with the flexible strip 74, this flexible strip 74 (b) also bends inwardly extending to the slot 50 and supported by the upper portion of the mounting rod 54. In the fourth (b), a flexible strip extending from the lower side of the slot 50 is not provided, and a gasket 78 having a low coefficient of friction is attached along the lower edge of the slot 50. The gasket is designed to contact the mounting rod under the mounting rod 54 to maintain a sealing relationship with the mounting rod 54.

In FIG. 7, another embodiment is shown with shielding means to protect the flexible strips 74 and 75 from being excessively exposed to a high speed flash removal medium flow. As shown in FIG. 7, a series of eccentric pandulum shield plates serving as individually rotating shutters are arranged adjacent to the slot 50. As shown in FIG. In practical operation, the shield plates extend beyond the full length of slot 50 in flash removal 12, but for the sake of illustration only four Fendurum shield plates 80,82,84,86 are shown. These pendulum shield plates are rotatably mounted to the inner surface of the front wall 52 directly above the slot 50 by mounting pins 88, 90, 92 and 94, respectively. These shielding plates are mounted superimposed along the length of slot 50 so that they are normally placed on the flexible strips 74,75 and cover the strips. When the mounting rod 54 moves laterally along the length of slot 50 and contacts the pendulum shield, the shield pivots about its mounting pin and moves out of the passage of mounting rod 54. As shown in FIG. 7, the mounting rod 54 moves outward from the left side and is shown as the pendulum shield 84 rotates about the mounting pin 92 to rotate counterclockwise away from the passage of the mounting rod 54. have. As also shown, the mounting rod 54 has already passed through the pendulum shield 82 under the mounting pin 90, so that the pendulum shield 82 moves the shield 54 to the right and moves the shield 82 to the flexible strip 74,75. When it is rotated to the position to protect, it is supported by the rod 54 and rotates downward.

8 and 9 illustrate one of the advantages to be obtained by the use of the double inverted projection wheel. In Fig. 8, an insulating housing 100 is shown surrounding the flash removal portion. On one side of the housing, the object 102 to be shot blasted is located, and on the side of the housing opposite the object 102, the projection wheels 104 and 106 are located. In FIG. 8, the projection wheels 104, 106 are shown to rotate clockwise. On each of the projection wheels 104 and 106 are shown two tangent lines representing the direction in which the shot medium is projected by each projection wheel. The shot medium projected in such a form generates a force represented by arrow 108. This allows a significant portion of the object to be in the "shade" which is not in contact with the flow of the high speed shot medium. The surfaces within the "shade" are shown in parentheses 110 and 112 in FIG.

In FIG. 9, the same housing 100 and the object to be treated 102 are shown. Similarly, projection wheels 104 and 106 are provided. However, as shown in FIG. 9, the projection wheels make a double inversion rotation in which the projection wheel 104 rotates clockwise and the projection wheel 106 rotates counterclockwise. This causes the shot medium flow from the two projection wheels to be imparted from both sides to the object 102 as indicated by arrow 108. Thus, the portion of the object 102 that is in the "shade" is significantly reduced.

Various modifications to the aforementioned arrangements can be made. For example, the projection wheels may be arranged to rotate about the same vertical axis. However, even if the wheels are satisfactorily short-listed, the overall length of the application portion can be increased. Projection wheels are shown mounted on one side of the application but of course this is not essential.

The following examples illustrate preferred embodiments of the invention and do not limit its scope.

EXAMPLE

An injection molded steering wheel 68 of approximately 15 inches (about 38 cm) in diameter with a 0-2 inches (about 5 cm) flash having a thickness of 0-0.02 inches (0.05 cm) is shown in FIG. Mounted on 54; The steering wheel 68 drives about 6 feet of flash removal unit 12, containing about -115 ° F (about -82 ° C) of refrigerant at a rate of about 24 inches per minute. It was transported past. At the same time, the steering wheel 68 was rotated at about 2.5 rpm on the mounting rod 54. The flash removal medium consisted of a cylindrical polymer compact having a diameter of 0.045 inches (0.11 cm) and a length to diameter ratio of about 3: 1. The medium was projected by the wheels 32 and 34 at a speed of 8,000-10,000 feet / minute (2400-3000 m / minute) in the manner as shown in FIG. The wheels can operate at line speeds as low as 3000 feet / minute (900m / min) and as high as 20,000 feet / min (6,000m / min). The resulting flashless steering wheel was removed from mounting rod 54 when exiting outlet 66. Another hot wheel 68 from the injection molding machine was mounted adjacent to outlet 66, allowing it to cool as it passed over the top of housing 10 before entering inlet 64.

Although only one embodiment has been described, it is clear that the invention can be operated under a wide range of operating conditions. For example, the device can be designed with a long flash removal and a large number of wheels, so it can be operated at high feed rates to achieve high production wheels. The refrigerant temperature may vary from about 0 ° F (about −17.8 ° C.) to as low as about −250 ° F (about −157 ° C.), depending on the temperature at which the molded plastic or rubber product is brittle.

Claims (10)

A method for low temperature removal of a material selected from a group consisting of flash, paint, other coatings and mixtures thereof from an object by a suitable medium, (a) rotating the object with the selected material, passing it through the application held at a low temperature, (b) passing the refrigerant through the application so that the selected material on the object is brittle, and (c) Projecting the medium at high speed within the applicator in such a way as to maximize the number and angle of impact of the medium onto the rotating object when it is transported through the applicator, and (d) applying the object from which the selected material has been substantially removed. Cold shot-blasting method, characterized in that consisting of the steps of removing from. The method of claim 1 wherein the object is a molded product. The method of claim 1, wherein the undesirable material is a flash. The method of claim 1, wherein the medium is a flash removal medium. The method of claim 1, wherein the medium is a short medium. The method of claim 1, wherein the low temperature is in the range of about 0 ° to about −250 ° F. 10. The method of claim 1, wherein the medium has a rapidity of about 3,000-20,000 feet per minute. The method of claim 1 wherein the object is a relatively large plastic molded article. The method of claim 1 wherein the object is a steering wheel. A continuous method for removing a flash of a molded article at low temperature by means of a flash removing medium, the method comprising: (a) rotating an object with a flash, passing it through an application part held at a low temperature, and (b) flashing the flash on the object. Passing the refrigerant through the applicator to be liable to grip, and (c) the flash in the applicator in such a way as to maximize the number and angle of impact of the medium on the object when the rotating object is transported through the applicator. Projecting a removal medium at high speed, and (d) removing the product from the application from which the flash has actually been completely removed.

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