JPS6137465B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention is a piston pump with automatic suction action, which has a drive camshaft, the cam of which drives a spring-loaded pump piston, which , in which the control edge controls the inflow of pressureless liquid from the tank during movement, and an outflow valve is provided for the outflow of the liquid.

Piston pumps of this type are known. However, this piston pump is extremely inefficient as a high-pressure suction pump for low viscosity media.

Furthermore, spring-loaded pump pistons and non-spring-loaded pump pistons, so-called free pistons, are also known for pumps.

The advantage of a spring-loaded piston is that it has a self-priming action and is constantly brought into contact by a spring with a drive cam or the like. The disadvantage, on the other hand, is that the sealing section is so short that a sufficient sealing cannot be achieved. In this case, therefore, leakage losses occur at the inlet valve that vary as a function of the pressure and reduce the efficiency of the pump at high pressures.

On the other hand, in free piston type pumps, the sealing section is relatively long, so good sealing can be expected. Furthermore, the free piston can be combined with an elastic seal as a piston seal. This pump is suitable for high pressures, has high efficiency, and delivers throughout the entire stroke. However, this pump has the disadvantage that it does not have an automatic suction action and requires a preload to press against the drive cam.

The object of the invention is to eliminate the drawbacks of the known pistons, which are characterized in that a free piston pump is connected in series to a piston pump with automatic suction action, and the inlet stroke of the piston pump with automatic suction action is synchronized with the transfer stroke of the free piston pump.

The advantage of the self-priming piston pump according to the invention is that the efficiency, especially in the high pressure range, is very high and that an inexpensive and space-saving drive motor can be used. Advantageously, the outflow valve of the pump with automatic suction action simultaneously forms the inflow valve of the free-piston pump. The conveying pressure of a spring-loaded pump piston can be applied to the free piston.

Furthermore, in the pump according to the invention, the leakage losses of the spring-loaded pump piston are extremely small even when the viscosity of the liquid is low, such as at high temperatures.
This is because in this case the conveyance only has to be carried out against a very low counterpressure. Furthermore, the known disadvantage of free-piston pumps, such as the need for a preload to press the piston onto the drive eccentric, is no longer a problem since the necessary pressure is provided by the spring-loaded piston.

The pump according to the invention is highly efficient and works satisfactorily over the entire temperature range.

Furthermore, the pump according to the invention can be stopped with the drive motor rotating using a simple member that engages the spring-loaded piston area.

The invention will now be explained with reference to the drawings: The piston pump 1 has a horizontal drive camshaft 2 rotated by a drive motor, not shown.
have. A drive eccentric 3 configured as a radial cam is seated on the drive camshaft 2 , on which a bowl-shaped pump piston 4 rests under the action of a spring 5 . The pump piston 4 is movable in a pump cylinder 6 to which a conduit 7 is connected laterally to a liquid tank 8 . The opening of the conduit 7 into the pump cylinder 6 forms a control edge 9 which is controlled by the end face 10 of the pump piston 4 . In this way, the control edge 9 and the end face 10 are connected to the inlet valves 9, 1 of the pump.
Configure 0. The pump piston 4 and the pump cylinder 6 are arranged such that the pump piston 4 is loaded with a spring 5 in the direction of the suction stroke, so that when the discharge stroke of the pump piston 4 given by the drive eccentric 3 is completed, liquid is removed from the liquid tank 8. automatically inhales,
Piston pump 1 with so-called automatic suction action
1.

A conduit 12 extends from the end of the pump cylinder 6, into which a check valve 13 is connected. This check valve 13 is the piston pump 11
as well as an outflow valve for the free piston pump 14
This is the inflow valve. This free piston pump 14
is arranged on the opposite side of the drive eccentric 3 from the piston pump 11 and coaxially with the piston pump 11.

Free piston pump 14 is free piston 1
5, the free piston 15 is pressed against the drive eccentric 3 by the pressure generated by the piston pump 11. free piston 15
is movable within the pump cylinder 16. This pump cylinder 16 is connected to the outlet valve 1 via a conduit 17.
8 and via this to a high pressure tank 19. Conduit 19a leads to the consumer.

The device of the invention works as follows. When the drive motor rotates the drive shaft 2, the pump piston 4 is reciprocated in cooperation with the action of the spring 5. In this case, the pump piston 4 takes up liquid from the liquid tank 8 via the inlet valves 9 , 10 and conveys it to the conduit 12 . Via the check valve 13 the liquid reaches the cylinder 16 of the piston pump 14 under pressure. This pressure serves to bring the free piston 15 into contact with the drive eccentric 3.

The pressure generated by the piston pump 14 reaches the high pressure tank 19 via the outflow valve 18;
Acts as a servo force for the hydraulic brake booster. A piston pump 11 in which the pump piston 4 is spring-loaded in the suction stroke direction and automatically sucks liquid.
By combining the piston pump 14 with the free piston 15, various advantages can be obtained. That is, as can be seen from the drawing, in a spring-loaded piston pump 11 the control edge 9
The seal section formed between the end surface 10 of the pump piston 4 is short, and has the disadvantage that leakage loss to the conduit 7 becomes large when trying to discharge liquid at a high discharge pressure. It is especially large when the viscosity of the liquid is low at high temperatures. However, in the present invention, since the free piston pump 14 is connected in series to the piston pump 11, there is no need for the piston pump itself to discharge high pressure. Based on this, the leakage losses are also small and the efficiency of the pump is improved.

On the other hand, the sealing section of the free piston pump 14 with the free piston 15 is formed between the end face of the free piston 15 and the end face of the pump cylinder 16 and is relatively large, so that the discharge pressure is high and the viscosity of the liquid is It has the advantage that the leakage loss is small even when the is small. The free piston pump 14 also has the disadvantage that it requires a pre-pressure in order to bring the free piston 15 into contact with the drive eccentric 3, but this pre-pressure is provided by the piston pump 11 in the present invention. .

In this way, the piston pump 11 has a high efficiency and operates satisfactorily over the entire temperature range. It is therefore possible to use a simple, compact and economical drive motor.

Furthermore, the piston pump 1 according to the invention has the following advantages: In FIG. It is becoming possible to do this. As a result, the entire piston pump 1 can be stopped without cutting off the drive motor. That is, when the rod 20 enters between the drive eccentric 3 and the pump piston 4, the pump piston 4 is no longer returned by the spring 5, and the pump piston 4 no longer performs the suction stroke.
Discharge from piston pump 11 is interrupted. The pressure which presses the free piston 15 of the free piston pump 14 against the drive eccentric 3 is therefore no longer built up in front of the free piston 15, so that the free piston 15 no longer performs a suction stroke and the free piston pump 14 is stopped. In this case, the drive eccentric 3 can continue to be rotated by the drive camshaft 2.

FIG. 2 is a sectional view of the casing 22 of the piston pump. Since the construction of this pump piston is substantially the same as in FIG. 1, the same reference numerals as in FIG. 1 are used in this case.

In this case, the pump piston 4' is provided with an annular groove 25 in its circumferential surface and a radial bore 26 and is arranged in the pump cylinder 6'. The control edge 10' of the annular groove 25 cooperates with the control edge 9' at the opening of the supply conduit 7' to form an inlet valve 9', 10'.

Also shown in FIG. 2 is a leakage conduit 24 extending from the housing chamber 23 which receives the drive eccentric 3'. This leak conduit 24 is returned to the supply conduit 7'. Other parts of the piston pump are shown with dashes added to previously used symbols. The free piston 15' cooperates with an elastic sealing sleeve 15a as a piston seal. In this case, the free piston 15' has a smaller diameter than the spring-loaded piston pump 4'.

FIG. 3 is a sectional view taken along the - line in FIG. 2.

In FIG. 4, another embodiment of the pump of the present invention is shown. In this case, the piston pump 31
has a vertical drive camshaft 32. On the drive camshaft 32 there is a radial cam 2 configured as a radial cam.
Two drive eccentrics 30 and 33 are seated. A bowl-shaped pump piston 34 is pressed onto one eccentric body 30 by the force of a spring 35. Piston pump 34 is movable within pump cylinder 36. Pump piston 34 and pump cylinder 3
6 forms a piston pump 37 as in the case of FIGS. 2 and 3.

Behind the piston pump 37 is a check valve 38,
An outflow valve for the pump piston 37 and an inflow valve for the free piston pump 39 are arranged. The free piston 40 of the free piston pump 39 is arranged parallel to the pump piston 34 of the piston pump 40. The free piston 40 of the free piston pump 39 is brought into contact with the other drive eccentric 33 by the conveying pressure of the piston pump 37. A check valve 41 and a high pressure tank 42 are arranged behind the piston pump 39.

The liquid tank 43 is connected via a passage 45 to a casing chamber 44 which is connected to an inlet valve 46 of the piston pump 37 . The oil leakage originating from the two piston pumps 37 and 39 collects in the housing chamber 44 and reaches the piston pump 37 again via the inlet valve 46 .

Since the mode of operation of this pump is substantially the same as that of the pump shown in FIGS. 1 to 3, it will not be described again here. The two pump pistons 4' and 15' as well as 34 and 40 are constructed in such a way that the spring-loaded pump pistons 4', 34 have a larger diameter in order to provide an extra supply of liquid from the low-pressure side. It's advantageous. This is because the spring-loaded pump piston has a certain displacement loss over the length of the inlet gap. This pump piston compensates for the insufficient conveying volume due to its large diameter. However, it is also possible to have different eccentric strokes and to provide both pump pistons with the same diameter.

Furthermore, the drive camshaft of the pump can also be constructed as a flat camshaft. In this case, the piston is moved like an axial piston pump.

Further, the drive camshaft may be rotated dryly or wetly as required.

[Brief explanation of the drawing]

The drawings show a plurality of embodiments of the present invention, and FIG. 1 is a schematic diagram of the first embodiment of the piston pump of the present invention, and FIG. 2 is a schematic diagram of the piston pump having the structure shown in FIG. 1. FIG. 3 is a sectional view taken along the - line in FIG. 2, and FIG. 4 is a sectional view of the casing of the second embodiment of the piston pump of the present invention. 1... Piston pump, 2... Drive camshaft, 3
...Drive eccentric, 4...Pump piston, 5...
Spring, 6... Pump cylinder, 7... Conduit, 8...
...Liquid tank, 9...Control edge, 10...End face, 1
1... Piston pump, 12... Conduit, 13...
Check valve, 14... Free piston pump, 15...
...Free piston, 16...Pump cylinder, 1
7... Conduit, 18... Outflow valve, 19... High pressure tank, 20... Rod, 21... Lever, 22... Casing, 23... Casing chamber, 24... Leakage conduit, 25... Ring groove, 26...radial hole,
30... Drive eccentric body, 31... Piston pump,
32... Drive camshaft, 33... Drive eccentric body, 34
...Pump piston, 35...Spring, 36...Pump cylinder, 37...Piston pump, 38...
...Check valve, 39...Free piston pump, 40
...Free piston, 41...Check valve, 42...
High pressure tank, 43...liquid tank, 44...casing chamber, 45...passage, 46...inflow valve.

Claims (1)

[Claims] 1. Automatic suction operation in which the pump pistons 4, 34 are loaded by springs 5, 35 in the direction of the suction stroke and driven by the drive camshafts 2, 32 in the direction of the discharge stroke. a piston pump having an inlet for pressureless liquid from the liquid tank 8, 43 is opened and closed by the control edge 10 of the pump piston 4, 34 when the pump piston 4, 34 moves. In the type in which liquid flows out from the piston pumps 4, 34 through an outflow valve, a free piston pump 14, 39 is provided downstream of the piston pump 11, 37 having an automatic suction action. The free piston pumps 14, 39 are connected in series and are configured to be driven by drive camshafts 2, 32 that drive the pump pistons 4, 34 of the piston pumps 11, 37 having automatic suction action. A piston pump 11 having an automatic suction action,
37 suction stroke is free piston pump 14,3
9, and the pump working chambers of the free piston pumps 14, 39 and the pump working chambers of the piston pumps 11, 37 having an automatic suction action are connected to each other during the suction stroke of the free piston pumps 14, 39. A piston pump having automatic suction action, characterized in that the free piston pumps 14 and 39 are not connected to each other during the discharge stroke. 2. The outflow valves 13 and 38 of the piston pump with automatic suction function simultaneously operate the free piston pump 1.
4. The piston pump according to claim 1, wherein the piston pump constitutes a 4.39 inlet valve. 3. The piston pump according to claim 1 or 2, wherein the drive camshafts 2, 2', and 32 are radial camshafts. 4. The piston pump according to claim 1 or 2, wherein the drive camshaft is a front camshaft. 5 Piston pump 11 with automatic suction action,
37 pump pistons 4, 4' and free pump 1
4, 39 free pistons 15, 15' are arranged coaxially, and a drive camshaft 2, 2' is provided between the pump pistons 4, 4' and the free pistons 15, 15'. Claim 1
The piston pump according to any one of items 3 to 3. 6 Piston pump 11 with automatic suction action,
37 pump pistons 4, 4' and free piston pumps 14, 39 free pistons 15, 15'
have the same drive eccentric 3, 3',
Piston pump as described in section. 7. A pump piston 34 of a piston pump having an automatic suction action and a free piston 40 of a free piston pump are arranged side by side parallel to each other, and drive the pump piston 34 or the free piston 40, respectively, on the drive camshaft 32. Piston pump according to claim 1 or 2 or 3 or 5, characterized in that it is provided with its own drive eccentric (30, 33). 8. The piston pump according to any one of claims 1 to 7, wherein the pump piston of the piston pump with automatic suction action and the free piston of the free piston pump have the same diameter. 9. A piston pump according to any one of claims 1 to 8, wherein the cam of the drive camshaft is sealed to the pump working chamber for dry rotation purposes. 10 Casing chamber 2 of drive camshaft 2', 32
The piston pump according to any one of claims 1 to 8, wherein the piston pumps 3 and 44 are connected to the liquid tanks 8' and 43. 11. Piston pump according to claim 10, wherein the free piston 15 is constructed without an elastic seal.