Reservoir for a lubricant pump

Abstract

The invention relates to a storage reservoir for receiving grease or the like lubricant for a lubricant pump with a, for example, cylindrical side wall (2) and a cover wall (3) closing off the reservoir interior space (5) at the top, in which a pressure compensation device (4) is disposed such that the reservoir interior space (5) is flow-connected with the reservoir exterior space (6) via an air-permeable but water-impermeable membrane.

Description

[0001] The invention relates to a storage reservoir for receiving grease or the like lubricant for a lubricant pump.

[0002] The task of the present invention is to implement such a storage reservoir such that a dependable pressure compensation during operation is possible even under water.

[0003] This task is solved in such a storage reservoir with, for example a cylindrical side wall and a cover wall closing the reservoir interior space at the top, thereby that in the cover wall a pressure compensation device is disposed such that the reservoir interior space is flow-connected with the reservoir exterior space via an air permeable but water impermeable membrane.

[0004] This ensures that an underpressure generated in the reservoir interior space, if lubricant is drawn from the storage reservoir by the lubricant pump, can at any time be compensated by the slip-streaming air. However, due to the properties of the membrane, water cannot penetrate into the reservoir interior space.

[0005] For simple assembly the membrane can advantageously be integrated into a machine screw which, in the proximity of a throughlet channel of the pressure compensation device can be screwed in.

[0006] Said air-permeable but water-impermeable membrane can comprise, for example, a textile material, onto which polytetrafluoroethylene (PTFF available for example under the tradename Teflon) is applied. Such materials are known, for example, under the brand name “Goretex”.

[0007] So that, in the event the storage reservoir is overfilled with lubricant, not only the displaced air but also lubricant can reach the reservoir exterior space via the pressure compensation device, in a further development of the inventive idea the pressure compensation device comprises an outlet valve which opens in the event of overfilling with lubricant.

[0008] Said overfill outlet valve for air and lubricant preferably comprises a radial shaft sealing ring, which under pressure from outside forms a seal and whose soft sealing lip under pressure from inside lifts from a seal seat.

[0009] For the purpose of simple assembly and reliable functional operation the pressure compensation device can be tightly clamped in an opening of the cover wall.

[0010] The pressure compensation device can for this purpose comprise an upper part and a lower part, which can be clamped in an opening of the cover wall by interspacing a sealing ring in order to avoid leakage.

[0011] To obtain a compact structure it is of advantage if the upper part coaxially penetrates through the lower part with a center plug, on which the seal seat for the radial shaft sealing ring is developed, leaving free a minimal annular escape gap for air and lubricant.

[0012] In further development of the inventive idea a check valve can be disposed in the throughlet channel comprising the membrane of the pressure compensation device, viewed from the direction of the reservoir interior space in front of the membrane, which valve closes under overpressure obtaining in the reservoir interior space, which prevents that the membrane located further toward the outside comes into contact with lubricant.

[0013] For the purpose of simple assembly and reliable functional operation, the pressure compensation device can be tightly clamped in an opening of the cover wall.

[0014] The invention further proposes that for easier assembly the upper part can be centered with a circumferential edge on the lower part.

[0015] Additional objectives, characteristics, advantages and application feasibilities of the invention are evident based on the following description of embodiment examples in conjunction with the drawing. All described and/or graphically represented characteristics by themselves or in any combination form the subject matter of the invention, independently of their summarization in the claims or their reference back.

[0016] In the drawing depict:

[0017] FIG. 1 a storage reservoir comprising the invention in oblique view,

[0018] FIG. 2 a top view onto a pressure compensation device in the upper cover wall of the storage reservoir according to FIG. 1,

[0019] FIG. 3 a vertical section through the pressure compensation device along line B-B in FIG. 2,

[0020] FIG. 4 a side view of the pressure compensation device according to FIG. 2, and

[0021] FIG. 5 a vertical section through the pressure compensation device along line A-A in FIG. 4.

[0022] The depicted storage reservoir 1 serves for receiving grease or the like lubricant for a (not shown) lubricant pump. The storage reservoir 1 has a cylindrical side wall 2 and a cover wall 3 closing off the reservoir internal space 5 at the top. A pressure compensation device 4 is disposed in the cover wall 3.

[0023] The pressure compensation device 4 comprises in a throughlet channel 17 a membrane, which extends in an upper part 12 of the pressure compensation device 4 coaxially to it and integrated in a machine screw [head] 23, which can be screwed in from above, which membrane is air-permeable but water-impermeable. The machine screw 19 is sealed off at its periphery by means of a sealing ring 21.

[0024] In the throughlet channel 17 beneath the membrane is disposed an overpressure valve 27, whose valve body 7 under overpressure in the reservoir interior space 5, occurring, for example, when filling the storage reservoir 1 with fresh lubricant, is placed upwardly against a sealing seat. This prevents lubricant from reaching the membrane and impairing its function. If, in contrast, lubricant is drawn out from the reservoir interior space 5 by a (not shown) lubricant pump, the generation of underpressure in the reservoir interior space 5 is avoided thereby that air can slip-stream from the reservoir exterior space 6 into the reservoir interior space 5 through a supply slot 24, remaining free beneath the machine screw head 23, and the membrane. In the process the overpressure valve 27 opens. The movement path of valve body 7 is delimited by a sleeve 18 of synthetic material placed from below into the throughlet channel 17.

[0025] The upper part 12 comprises a circumferential edge 20, with which it is centered on a lower part 13 of the pressure compensation device 4. Upper part 12 and lower part 13 have a somewhat greater diameter than an opening 11 in the cover wall 3. In this way, upper part 12 and lower part 13 by interspacing a sealing ring 14 can be tightly clamped on the edge of the opening 11 by means of clamping screws 25.

[0026] The upper part 12 projects with a center plug 15 through the lower part 13 leaving free an escape gap 16 for air and lubricant in the event of overfilling. Above the escape gap 16 on the center plug 5 [sic: 15] is developed a sealing seat 10 for a radial shaft sealing ring 9, such that an outlet valve 8 is formed. As evident in FIG. 3, the radial shaft sealing ring 9 has a sealing lip above the escape gap 16, which, under pressurization from the inside, can become raised from the sealing seat 10, such that excess air and lubricant can escape through radial outlet channels 26.

[0027] In this way a storage reservoir for a lubricant pump is provided, in which an air pressure compensation takes place during filling as well as also during emptying of the reservoir interior space with lubricant. Yet, utilization under water is possible. When overfilling [the reservoir], further the escape of lubricant via the pressure compensation device is ensured without the air-permeable but water-impermeable membrane coming into contact with lubricant and is impaired in terms of its function. The pressure compensation device forms an easily mountable structural unit.

List of Reference Numbers

[0028] 1 Storage reservoir

[0029] 2 Side wall

[0030] 3 Cover wall

[0031] 4 Pressure compensation device

[0032] 5 Reservoir interior space

[0033] 6 Reservoir exterior space

[0034] 7 Valve body

[0035] 8 Outlet valve for air and lubricant

[0036] 9 Radial shaft sealing ring

[0037] 10 Sealing seat

[0038] 11 Opening

[0039] 12 Upper part

[0040] 13 Lower part

[0041] 14 Sealing ring

[0042] 15 Center plug

[0043] 16 Escape gap for air and lubricant

[0044] 17 Throughlet channel for air

[0045] 18 Sleeve

[0046] 19 Machine screw with integrated membrane

[0047] 20 Circumferential edge

[0048] 21 Sealing ring

[0049] 22 Threads

[0050] 23 Machine screw head

[0051] 24 Supply slot for air

[0052] 25 Clamping screws

[0053] 26 Outlet channels for air and lubricant

[0054] 27 Overpressure valve

Claims

1. Storage reservoir for receiving grease or the like lubricant for a lubricant pump, with a, for example, cylindrical side wall (2) and a cover wall (3) closing the reservoir interior space (5) at the top, in which a pressure compensation device (4) is disposed such that the reservoir interior space (5) is flow-connected with the reservoir exterior space (6) via an air-permeable but water-impermeable membrane.

2. Storage reservoir as claimed in claim 1, characterized in that the membrane is integrated in a machine screw (19), which can be screwed in in the proximity of a throughlet channel (17) of the pressure compensation device (4).

3. Storage reservoir as claimed in claim 1 or 2, characterized in that the membrane comprises a textile material onto which polytetrafluoroethylene (Teflon) is applied (Goretex).

4. Storage reservoir as claimed in one of claims 1 to 4 [sic: 3], characterized in that the pressure compensation device (4) comprises an outlet valve (8) which opens if [the reservoir] is overfilled with lubricant.

5. Storage reservoir as claimed in claim 4, characterized in that the outlet valve (8) comprises a radial shaft sealing ring (9), which under pressure from the outside forms a seal and whose soft sealing lip under pressure from the inside lifts from a sealing seat (10).

6. Storage reservoir as claimed in one of the preceding claims, characterized in that the pressure compensation device (4) is tightly clamped in an opening (11) of the cover wall (3).

7. Storage reservoir as claimed in one of the preceding claims, characterized in that the pressure compensation device (4) comprises an upper part (12) and a lower part (13), which can be tightly clamped in an opening (11) of the cover wall (3) by interspacing a sealing ring (14).

8. Storage reservoir as claimed in one of the preceding claims, characterized in that the upper part (12) coaxially penetrates through the lower part (13) with a center plug (15), on which the sealing seat (10) for the radial shaft sealing ring (9) is developed, leaving free a minimal annular escape gap (16) for air and lubricant in the event of overfilling.

9. Storage reservoir as claimed in one of the preceding claims, characterized in that in the throughlet channel (17) of the pressure compensation device (4) in which the membrane is disposed, viewed from the reservoir interior space (5) in front of the membrane a check [sic?: overpressure] valve (27) is disposed which closes under overpressure obtaining in the reservoir interior space (5).

10. Storage reservoir as claimed in one of the preceding claims, characterized in that the upper part (12) can be centered on the lower part (13) with a circumferential edge (20).