SE463732B - Pump for compressing air - Google Patents

Abstract

A pump for compressing air, which consists of an inner, fixed cylinder 1 and an outer cylinder 2 which can be displaced around the cylinder 1. Arranged in the inner cylinder 1 is a piston 3 which can be displaced in a reciprocating manner with the outer cylinder 2 and divides the space in the inner cylinder 1 into a first and a second chamber 8, 9. A third chamber 12 in the outer cylinder 2 communicates with the first chamber 8 via one or more openings 17 in the casing of the inner cylinder 1 and with the second chamber 9 via a throughflow duct 10 in the piston 3. The outer cylinder 2 is arranged so as, when displaced in one direction, to press the air in the third chamber 12 into the first chamber 8 and onward, via the throughflow duct 10 of the piston 3, into the second chamber, and, when displaced in the opposite direction, to cause the piston 3 to press the air in the second chamber 9, via a non-return valve 18, out through a nozzle 21. <IMAGE>

Description

463 732 In the following, the invention will be described in more detail with reference to the accompanying drawings, in which Fig. 1 shows a longitudinal section through the pump according to the invention in one position and Fig. 2 also a longitudinal section through the pump in another position.

The pump consists partly of an inner cylinder 1, which constitutes an elongate fixed pump housing, and partly of an outer cylinder 2, which is displaceable back and forth around the inner cylinder and forms a movable pump housing.

In the inner cylinder 1 a piston 3 is attached to one end of a piston rod 4, which extends through an end wall 5 to the inner cylinder and at its opposite end is arranged at an end wall 6 to the outer cylinder 2. By means of a pump handle 7, the outer cylinder 2 and the piston rod 4 with the piston 3 are displaceable back and forth.

The piston 3 divides the space of the inner cylinder 1 into a first chamber 8 behind the piston, seen in the pressure direction of the piston, and a second chamber 9 in front of the piston. The first chamber 8 communicates with the second chamber 9 via a flow channel 10 in the piston 3, which is provided with a valve 11, suitably in the form of a D-ring, which abuts tightly against the inner wall of the inner cylinder 1 in the channel 10. When the piston 3 is displaced in one or the other direction, this valve 11 will move by sliding friction against the inner wall from a channel 10 closing position to an opening position or vice versa.

The outer cylinder 2 forms a third chamber 12 around the inner cylinder 1 between an end wall 13 at the lower end of the outer cylinder and the end wall 5, which forms a partition wall in the outer cylinder and is provided with a seal 14 abutting against the inner wall of this cylinder. the wall 13 is provided with a connecting duct 15 between the third chamber 12 and the outside air. In this connecting channel 15, in the same way as in the flow channel 10 of the piston 3, a valve 16 is arranged, suitably in the form of an O-ring. This abuts tightly against the outer wall of the inner cylinder 1 and is moved by sliding friction against this wall to open or close the connecting channel 15 in depending on which direction the outer cylinder 2 is displaced. 463 732 Inside the end and partition wall 5, the inner cylinder 1 is provided with one or more openings 17, through which the third chamber 12 communicates with the first chamber 8 and through the channel 10 with the second chamber 9. The latter chamber 9 is at the bottom closed by means of a non-return valve, which consists of a seal 18 sliding towards the inner wall of the inner cylinder 1, which under the influence of an overpressure in the chamber 9 against the walls of a spring 19 opens a channel 20, which leads out through a nozzle 21.

This nozzle extends in the embodiment shown in the drawing through the bracket to a foot bracket 22 or the like, of which only its fastening portion is shown.

The function of the pump will be described in the following, first referring to Fig. 1. By pulling the pump handle 7 (in the direction of the arrows 23), the outer cylinder 2, the piston rod 4 and the piston 3 are displaced upwards. The valve 16 will move through said sliding friction so that it closes the channel 15, and the valve 11 opens the connection between the chambers 8 and 9. The end wall 13 approaches the fixed end or partition wall 5, which means that the chamber 12 gradually decreases.

The air in this chamber will therefore flow over into the chamber 8 through the opening or openings 17 and further via the flow channel 10 of the piston to the chamber 9. At the same time the air is compressed, so that the pressure in the chamber 9 becomes approximately 7-8 times greater than in the chamber 12 .

When the pump handle 7 is then pressed down (in the direction of the arrows 24, see Fig. 2), during the downward movement of the outer cylinder 2, the piston rod 4 and the piston 3, the valve_16 will move to a position opening the channel 15, while the valve 11 closes the duct 10. The piston 3 will now serve as a pump piston and increase the pressure in the chamber 9 so much that the non-return valve 18 opens, whereby the air in the chamber 9 flows out through the nozzle 21. As soon as the pressure in the chamber 9 drops below a certain value, it closes spring 19 again valve 18.

During this pumping movement, air simultaneously flows through the duct 15 into the chamber 12. When the pump handle 7 is pulled again, the chamber 12 is filled with air and the non-return valve 18 is closed, as described above while closing the valve 16 and opening the valve 11 the air flows from the chamber 12 over into the chamber 8 and on to the chamber 9 and the process is thus repeated.

Through the constructive embodiment according to the invention, a pump has been obtained which is extremely efficient. During tests it has been shown that you can only inflate the pressure in a smaller container to 500 - 600 N with just a few pump movements. compressor and pressure tank due to the lack of a sufficiently efficient hand pump.

By choosing the design of the pump, you can determine how much overpressure you want to reach in the chamber 9. Thus, if the outer cylinder 2 is made large and wide, while the inner cylinder 1 is made very narrow, a strong overpressure is quickly achieved. . If the spring 19 in the non-return valve 18 is not made too strong, it can be made to open already during the upward pump movement, which means that air is pumped out of the nozzle 21 during both pump movements.

The invention is not limited to the embodiment shown and described, but several variants are conceivable within the scope of the appended claims. This mainly applies to the various valve arrangements. The pump can of course be used to pump gases other than air. You can also imagine using the construction in another way than as a hand pump.

Claims (3)

463 732 P A T E N T K R A V A pump for compressing air with an inner fixed cylinder (1), in which a reciprocating piston (3) is arranged, which divides the space of the cylinder (1) into a first chamber (8) behind the piston (3), seen in the pressing direction of the piston (3), and a second chamber (9) in front of the piston (3), characterized in that the pump is further provided with an outer cylinder (2), which is displaceable back and forth around the inner cylinder. (1) and forms a third chamber (12) with a volume several times larger than that of the first and second chambers together between an end wall (13), through which the third chamber (12) communicates with the outside air via a valve (16) , at one end and a partition wall (5) sealing against the inner wall of the outer cylinder (2) at the opposite end of the inner cylinder (1), through which a partition wall (5) runs with the piston (3) and the outer cylinder (2) connected piston rod (4), which coordinates the movements of the piston (3) and the outer cylinder (2), and that the third chamber one (12) communicates with the first chamber (8) via one or more openings (17) in the jacket of the inner cylinder (1) and with the second chamber (9) via a valve (11) in the piston (3), and that the outer cylinder (2) is arranged to push the air in the third chamber (12) via the opening or openings (17) in the jacket of the inner cylinder (1) into the first chamber (8) via displacement in one direction and via the valve (11) of the piston (3) into the second chamber (9) during pressure increase in this chamber and when displaced in the opposite direction cause the piston (3) to force the air into the second chamber (9) after further pressure increase via a non-return valve (18) out through a nozzle (21). Pump according to claim 1, characterized in that the valve (16)) the end wall (13) constitutes a one-way valve which abuts tightly against the outer wall of the inner cylinder (1) in a connecting channel (15) through this end wall. (13) and is arranged to move by sliding friction against this outer wall to a connecting channel (15) closing position when displacing the outer cylinder (2) for transferring air to the first and second chambers (8, 9) and in the same way automatically moving to a position opening a connecting duct (15) when the outer cylinder (2) is displaced in the opposite direction to allow new air to flow into the third chamber (12). Pump according to claim 1, characterized in that the valve (11) of the piston (3) constitutes a one-way valve which abuts tightly against the inner wall of the inner cylinder (1) in a flow channel (10) through the piston (3) and is arranged to automatically move by sliding friction against this inner wall to a position opening this channel (10) when displacing the outer cylinder (2) for transferring air to the first and second chambers (8, 9) during pressure increase in these and in the same way automatically move to a position closing a flow channel (10) when the outer cylinder (2) is displaced in the opposite direction and in this position cause the piston (3) to further compress the air in the second chamber (9), until the non-return valve (18) opens.