SU1595942A1 - Apparatus for removing defective coatings - Google Patents

Abstract

The invention relates to devices for removing mechanically defective enamel and paint coatings from the inner surfaces of cylindrical horizontally arranged tanks having an opening in one of the ends of the tank, and can be used, for example, in the food industry. The aim of the invention is to increase the reliability of operation. The device contains a drive station 1, a shaft 3 mounted in supports 4 and 6, on which a support 8 with driving rollers 9 mounted at an angle to the axis of the shaft 3 is mounted. On the support 8 there is a faceplate which contains pneumatic cylinders, on which rods are fixed forks with pneumatic turbines and support rollers. A working tool is attached to the shaft of the pneumatic turbine. Compressed air is supplied to the pneumatic turbine and pneumatic cylinder through an air preparation system and a grooved collector 25 with a sealing system. The operation of the device is carried out with the rotation of the shaft 3, causing the movement of the support 8, on which the chuck rotates. When compressed air is supplied, the pneumatic cylinder rod extends, the support roller abuts against the wall of reservoir 5, and the working tool begins surface treatment. The proposed solution allows the surface treatment of the tank to be performed in a constant dynamic mode, which makes it possible to increase the reliability of the device. 1 hp f-ly, 6 ill.

Description

The invention relates to devices for removing mechanically defective enamel and paint-and-lacquer-HbiJK coatings from the inner surface of cyl: indric-horizontally liberated reservoirs having a lug at one of the ends of the reservoir, and: can be used for example, in the food industry.

The aim of the invention is to increase the reliability of operation. .

FIG. 1 schematically shows the proposed device, a general view; in fig. 2 is a view A of FIG. one; in fig. 3 is a section B-B in FIG. one; in fig. 4-fork of pneumatic cylinder rod with peivmoturbina, working tool and support roller; in fig. 5 is a diagram of the installation of propeller rollers on a rotating shaft; in fig. 6 - kinematic-k4 device diagram.

The device for removing defective covers contains a drive station 1 with a reversible motor, through chain transmission 2 a rotating shaft 3 having a bearing support 4, adjustable in height and located outside the reservoir 5. The second end of the shaft 3 has a support containing a rotating axis 6 and divided into two parts, one of which is made in the form of a magnetic plate 7, and the other in the form of a plate made of a ferromagnetic alloy for fastening the support to the end wall of the tank.

On the shaft 3, a caliper 8 is installed with the possibility of reciprocating movement supported on two pairs of propulsive rollers 9 installed at an angle to the axis of the shaft 3. At the end of the caliper 8, face plate 10 is installed. which through the gear 11 can rotate the drive 12 of the face plate Yu

Three pneumatic cylinders 13 are installed on the Yu faceplate, the rods 14 of which contain plugs 15, on which pneumatic turbines 16 with a working

tool 17, eccentric axes 18 with support rollers 19,

The compressed air is supplied to each of the pneumatic turbines 16 from a compressor (not shown) or a workshop system via a pressure regulator 20, a receiver 21, an oil sprayer 22, an inlet fitting 23, an air channel 24, and a 25-type collector sealed by a sealing system 26 on the support body 8, through the air. Channels 27 in the Playground 10, dispensing fitting 28 and pressure hoses 29. Compressed air to pneumatic cylinders

13 is supplied through an additional pressure regulator 30 and throttle 31. Made sro for supplying compressed air to the working cavity of pneumatic cylinder 13 with the minimum working pressure necessary to move the rod

14 and keeping it in position. The throttle 31 makes it possible to adjust the speed of movement of the rod 14,

FIG. 2 shows only one pair of pressure arms 29 supplying compressed air to a pneumatic cylinder and a pneumatic turbine.

The device works in the following way.

Ball 3 with a caliper 8 mounted on it without pneumatic cylinders 13- is installed in a bearing support 4 and on a rotating axis 6 fixed on the wall of the tank 5 by a magnetic plate 7 so that the axis of the shaft 3 coincides with the horizontal axis of the cut of the lee 5. Install chain transmission 2 between the drive sprocket drive station 1 and the driven sprocket shaft 3.

In advance, the driving rollers 9 on the caliper 8 are set at such an angle to the axis of the shaft 3, so that the step of moving the caliper 8 by one turn of the shaft is equal to the working width of all working tools 17, based on

tg fD:

where c is the angle of rotation of the rollers relative to the shaft axis; S is the total width of the working tools; Dg is the shaft diameter. Using the eccentric axis 18, the required machining depth (similar to the cutting depth) of the working tool 17 is set, i.e. the difference between the extreme line of the working tool 17 and the surface of the support roller 19 (size P on

FIG. i).

Rotating shaft 3, the caliper 8 is inserted with the help of propeller rollers 9 inside the tank 5 and inside the tank mounted on the faceplate 10 pylevmo cylinders 13 and fixed pressure sleeves 29.

Having set the caliper 8 to the initial position, the drive 12 of the faceplate is turned on and, through gear 11, drives it into rotation.

Pneumatic turbines 16 and pneumatic cylinders 13 rotating to the faceplate 10 are squeezed through air through the compressed air preparation unit, which includes a pressure regulator 20, a receiver 21 and an oil distributor 22,

At the same time, the air is compressed on the pneumatic turbines 16 through the inlet fitting 23 on the caliper housing 8, the air passage 24. -the collector 25, the air passage 27 in the faceplate, the distributor fitting 28 and the caper sleeves 29 connected to the air turbines 16 "

The sealing system 26 prevents compressed air from leaking from the manifold 25 of the caliper 8 into the channels 27 of the faceplate 10, Compressed air to the pneumatic cylinders 13 from the collector 25 goes to the pressure regulator 30 and the throttle 31 through which the pressing force is adjusted. supporting rollers 19 to the surface of the tank and the speed of movement of the rod 14, to achieve a smooth supply of the working tool to the surface of the tank 5,

95942

Turning on the drive station 1, the shaft 3 and the caliper 8 are rotated, thanks to the rollers-motion-turn. tel) 9 begins to move around

lou j.

In this case, the pneumatic turbines 16 rotating on the face plate 10 with the working tools 17 make the surface treatment. If it is necessary to reprocess by reversing the drive station 1, the caliper is moved in the opposite direction to the right

If the need for additional 5 i -th processing does not arise; the caliper is returned to its original position with the compressed air supply turned off and the drive 1 2 faceplate.

The proposed device allows 20 to treat the surface of the tank in a constant dyng mode, without constant bending of the pressure hoses, leading to their advanced wear.

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rmula of invention

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five

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Claims (1)

1, A device for removing defective coatings, containing a drive station, a working tool with a drive in the form of a pneumatic turbine with a compressed air supply system mounted on a rod, a pneumatic tubing, characterized in that with 1; the objective of increasing reliability of operation, the eye is provided with supports, a drive shaft mounted in the supports, a support with Rollers-Movers and a faceplate mounted rotatably, pneumatic cylinders with a shaft, and a fork with support rollers mounted on the faceplate, and the support is located on the shaft with the possibility of reciprocating movement by means of propeller rollers located at an angle to the axis of the driven shaft, and the supporting rollers are installed in a fork with eccentricity; 2, the device according to claim 1, characterized in that one of the supports of the drive shaft is made in two parts, one of the panels consists of a magnetic plate, and the other is made of a plate of a ferromagnetic alloy. 28 7J YU 28 2 2-B Fi.Z G7. g 18 Oh nineteen TO and sixteen 15 FIG. it FIG. five go 30 FIG. 6 / J J