DE43416C - Compensating valve on pumps for air and gas - Google Patents

Description

IMPERIAL

PATENT OFFICE.

The present invention is intended to make it possible for air to pass from the compression space to let occur after the piston back more or less before or after the end of the piston stroke.

Fig. Ι shows the lever mechanism connected to the rod of the control eccentric for this purpose. With the rod of the eccentric E on the control shaft W , the push rod m is articulated at s , which engages at the lower end of the double lever η , whose pivot point χ can be set to different heights in the fixed backdrop K. If the point χ lies in the upper part of the fixed link K, the compensating slide B connected by the push rod / with the double lever η works with subsequent flows, i.e. when the crank rotating in the direction of the arrow is just at the dead center A , it is between the main channels e communicirenden equalization channels d is not produced by the compensating spool Communication, but the same holds the left-side channel d still covered. Only when the crank has passed the dead center at A a little and the slide B has moved somewhat to the left in the direction of the arrow drawn does communication between the two channels take place through the shell in the slide, that is, the compressed air flows in from one to the other Instead of the cylinder side. The moment of pressure equalization occurs at the same time as the opening of the suction and pressure channels by the main slide or a little earlier.

If the crank is at point A , the center of the eccentric is in i , and as the crank moves towards point A ¹ , the center of the eccentric is shifted from i to z ¹ . The center of oscillation of the upper end of the lever must in all cases be the center of oscillation of the slider B exactly on the center of the slider mirror respectively. Leave it in the middle between the two channels d so that the compensating slide opens and closes completely evenly on both sides of the cylinder. The curvature of the fixed link K is therefore to be chosen in such a way that this necessary condition is fulfilled in every position of the fulcrum χ in the same.

Is the fulcrum χ is illustrated in the center position as shown in Fig. 1, the inner edge of the flap cuts the slide B just with the edge of the left side channel d from when the crank is at the dead points A. In this position, the equalization channels d are currently in communication; after a certain slide path the same is interrupted again and after a further slide path the main slide opens suction and pressure channels. The deflection of the lever n,

thus also the slide travel, in this case is somewhat smaller than in the previous one, but the center of oscillation of the compensating slide B always remains immovable.

If the fulcrum χ is finally in its lower position in the backdrop K, the slide travel becomes even smaller. Here the equalization channels d are already brought into communication before the crank rotating in the direction of the arrow reaches dead center A. This is where pre-flow takes place. The end of the pressure equalization occurs after an even shorter slide path than in the previous case, and after a further path of the compensation slide B , the main slide opens suction and pressure channels. If the crank crosses dead center A \ on the left, the equalizing slide B moves from right to left, and opening and closing of the pressure equalization channels, i.e. pre-flow, takes place exactly as before. It is expressly noted that point s can also be selected on the eccentric ring or another point on the eccentric rod.

It is expedient to choose the slide push rod / so long that the slide movement can be influenced as little as possible when the lever pivot point χ is set up and down.

FIGS. 2 to 6 illustrate, as a further example, a ratchet mechanism for moving the compensating slide B and the attachment of the mechanism to the valve body. The slide pushrod / is provided with a pawl that can be automatically rotated by a fixed thrust curve ww ^x , which, depending on whether a pair of lugs PP ^{1 is set} on slide B , moves the slide to and fro more or less. The sleeve q of this pawl is freely rotatable between the stops a ^l b ^l on the slide rod / and carries a roller ν abutting the thrust curve w n> ^{1 at the top and a tooth ^ 1} under the action of the slide catches P P ¹ and a tooth at the bottom under the action of a bow spring r the slide rod standing tooth u, Fig. 2 and 3, the on the wart / f ^! the sleeve q , into which the pivot pin of the roller is screwed. Fig. 5 shows from above the thrust curve influencing the roller ν and thereby rotating the pawl, which is formed by a cutout in the housing t covering the slide. The eccentric to be connected to the slide rod / is in turn offset by about 90 ° from the crank.

Now, for example, the compensation slide B is in position Fig. 2, the lower teeth ^ ¹ is the ratchet sleeve q in the dotted position Fig. 3. For while the rolls ν the links transition, FIG. 2, n by the thrust Curve> ¹ of the housing t covering the slide, it got a little over the middle position 2, after puncturing Fig. 5, and the pressure of the bow spring r of the slide rod then hit the roller ν in the position 3, Fig. 5. Then there is no communication between the channels d, so there is no overflow from one cylinder side to the other. The slide is then displaced furthest to the left by previous action of the lower ratchet tooth ^ 'on the slide catch P, FIGS. 3 and 4. If the slide pushrod now moves in the direction from left to right, the latch nose ^ ¹ , which, as mentioned, assumes the dotted position in Fig. 3 according to the pin position according to the puncturing Fig. 5, behind the catch P 'and drags move the slider B to the right with you. At the same time, however, the roller ν rolls along the thrust curve w, which is inclined against the direction of the slide movement, Fig. 3 and 5. Towards the end of the movement, the roller is pushed by the thrust curve w in the opposite direction over the central position. It then hits the roller down into position 1, Fig. 5, as a result of which the pawl rotates around the slide rod / again in such a way that the slide remains in place for the time being, but during the next operation of the rod Z from left to right at its catch P ¹ is detected again and taken along. By adjusting the lugs P and P ¹ , you can change the slide travel. The same can be adjusted on the inclined edges ^, Fig. 4, by means of screws which pass through the slots in the lugs PP ¹ .

In order to relocate the pressure equalization before or after the dead center position of the piston, a specially adjustable eccentric F can be arranged on the main shaft according to the modification of FIG. 7, which moves the equalizing slide B independently of the distribution slide. By moving this eccentric forwards and backwards by means of the wing nut of a screw G in eccentric E reaching through a curved slot 5 of the eccentric, earlier or later opening of the compensating slide and thus earlier or later pressure equalization is also achieved.

Claims (2)

Patent claims: In the case of the No. 37746 patented compensating valve on valve pumps for air and gas the replacement of the compensating valve B, which is adjustably connected to the slide rod of the control valve, for controlling the channels d branching off from the channels e by a compensating valve B, which receives its movement either through 1. a lever n moved by the eccentric rod, the pivot point of which can be set at different heights in a fixed setting K , or 2. A ratchet mechanism, Fig. 2 to 6, consisting of the ratchet q rotatable around the slide rod, the lower tooth ^ ¹ of which is guided by the action of the roller ν guided on the thrust curve (w W ^) of the housing t and the spring r. and is rotated so that when the slide pushrod / alternately the slide catches PP ¹ are grasped by the tooth ^ ^{1, or}
by a special adjustable eccentric F, Fig. 7. For this purpose ι sheet of drawings.