SU878572A1 - Pneumatic hammer - Google Patents

Description

body 1 stroke (plunger stroke). Moreover, the valve 8 is placed on the guide 5 with the possibility of axial movement. At the same time, the valve 9 is arranged to move its inner seating surface along the valve 8. The cavity 13 is enclosed between the upper part of the valve 8 and the housing 1.

In the lower part of the housing 1 is placed the shank of the working tool 14, I perceive, his blows drummer 15.

The hammer works as follows.

During the working stroke of the striker 15, the valves 8 and 9 are in the extreme upper position. The main air from the pressure line 10 flows under the valve 9 into the chamber 12. The valves 8 and 9 are held in the upper position under the action of excess force from below because the cavities 7 and 13 through the channels 3 and 4 are connected to the atmosphere. Under the pressure of compressed air in chamber 12, the impactor 15 moves downwards. The compressed air from the chamber 12 penetrates through the channel 3 into the cavity 7. Under the action of the resultant force (pressure of the main air and dynamic forces), the valve 9 is displaced downwards and occupies the lowest position, and the access of the main air to the chamber 12 is stopped (the compressed air is cut off from the network ) before the upper edge of the firing pin 15 passes the exhaust port 2.

After the hammer 15 closes the exhaust port 2, the air in the chamber 11 is compressed, and the air pressure is transmitted through channel 4 to the cavity 13. With the further movement of the drummer 15, the exhaust port 2 opens downwards, due to which the pressure in the chamber 12, The channel 3 and in the cavity 7 fall sharply, as a result, the valve 8 under the action of excess force from the compressed air pressure from the cavity 13 moves to the lowest position. Following the perekidka valve 8 is the impact of the striker 15 with the shank of the working tool 14.

When the striker 15 is idling, the main air passes over the valve 8, enters the cavity 13 and enters the chamber 4 through the channel 4. Under the pressure of compressed air, the plunger-hammer 15 moves upwards. After the drummer 15 takes the upper position, the compressed air from chamber 11 through channel 3 enters cavity 7. Under the influence of the total force from the pressure of compressed air from the side of the pre-valve chamber 7 to valve 8, the latter moves upward and closes access to the main air in chamber 11 before the exhaust from it.

Upon further upward movement of the striker, the air in chamber 12 is compressed, and the force on valve 9 from below increases to such a value that the resultant force acting on valve 9 changes direction. This also contributes to the fall

air pressure in chamber 11, channel 4 and cavity 7 after exhaust. The valve 9 moves up and takes up a position corresponding to the beginning of the working stroke. Subsequently, the cycle is repeated.

The design of the pneumatic hammer air distribution system in the form of two coaxially positioned valves with the possibility of axial movement of one valve relative to the other distinguishes the proposed hammer from the known one, since the proposed hammer has a potentially unlimited throughput of the air distribution system.

Using the described pneumatic hammer in the national economy significantly reduces compressed air leakage and increases efficiency.

Claims (2)

1. USSR author's certificate No. 120196, cl. In 25D 9/166, 1958. 2. USSR author's certificate No. 432286, cl. In 25D 9/00, 1972 (prototype).