DE102018116045A1 - Gas spring with a pressurized lubricant reservoir - Google Patents

Abstract

The invention relates to a gas pressure spring (1) comprising a housing (10) with a longitudinal axis (15) and a cylinder bore (17) extending in the longitudinal axis (15) with a wall (19), and a piston (30) is displaceably arranged in the cylinder bore (17) along the longitudinal axis (15), the piston (30) having an outer side (31), comprising an outer surface (32), a pressure side (33) and an end face (34), wherein between a gas compression chamber (20) is formed for the piston (30) and the housing (10), at least one piston seal (36) being arranged between the lateral surface (32) and the wall (19), the piston (30) having at least one lubricant reservoir (40) for a lubricant (4), the at least one lubricant reservoir (40) being connected to the outside (31) by at least one lubricant line (42) with at least one lubricant opening (43), and wherein the at least one lubricant medium reservoir (40) has at least one pretensioning means through which the lubricant (4) can be pressurized.

Description

The present invention relates to a gas pressure spring with the features of claim 1 with improved properties and an extended service life due to effective lubrication of a piston.

Gas pressure springs are known from the prior art in various configurations and typically comprise a housing with a cylinder bore and a longitudinal axis, a piston being movably arranged along the longitudinal axis in the cylinder bore and forming a gas compression chamber in the cylinder bore with the housing in which a Gas, preferably a large molecular size gas such as nitrogen is included. Gas pressure springs of this type are sufficiently known from the prior art and are used in a variety of ways in tools and machines and are distinguished by a high level of reliability. It has been shown that the service life is reduced due to insufficient lubrication or no continuous relubrication of the piston in the cylinder bore. In particular, it has been shown that due to inadequate lubrication of the piston in the cylinder bore, the seals used wear out and gas can therefore escape from the gas compression chamber.

It is therefore the object of the present invention to provide a gas pressure spring which has improved lubrication of the piston in the cylinder bore of the housing and is inexpensive to manufacture. In addition, the gas pressure spring according to the invention should have an unchanged outer geometry in comparison to conventional gas pressure springs, as a result of which gas pressure springs can be replaced in the event of signs of wear or in the event of a defect by the improved gas pressure spring according to the invention, without additional design changes to the tool or the machine being necessary.

According to the invention, these objects are achieved by a gas pressure spring with the features of claim 1.

Advantageous refinements and developments of the invention are specified in the appended claims.

The gas pressure spring according to the invention comprises a housing with a longitudinal axis and a cylinder bore extending in the longitudinal axis with a wall and a piston which is displaceable in the cylinder bore along the longitudinal axis. The piston has an outer side, which comprises a lateral surface, a pressure side and an end face, a gas compression chamber being formed between the piston and the housing. The gas compression chamber is consequently enclosed by the housing and the piston or its pressure side, the outer surface of the piston interacting with the wall of the cylinder bore and providing a gas-tight sliding bearing for the piston in the cylinder bore. In addition, the piston comprises at least one lubricant reservoir for a lubricant, the at least one lubricant reservoir being connected to the outside of the piston by at least one lubricant line with at least one lubricant opening, and the at least one lubricant reservoir having at least one pretensioning agent, through which the lubricant can be pressurized. The preloading means applies a pressure to the lubricant in the at least one lubricant reservoir and the at least one lubricant line, and thus displaces the lubricant from the at least one lubricant reservoir by means of the at least one lubricant line. The lubricant emerging from the lubricant opening ensures that the surfaces adjacent to the lubricant opening are wetted with the lubricant. The lubricant can be a viscous medium, for example an oil or a fat, which has a sufficiently high viscosity in the permissible temperature range of the gas pressure spring.

In a further preferred embodiment, the at least one lubricant reservoir comprises a movable lubricant piston. In this case, the preloading means further preferably applies a pressure, preferably an excess pressure, to the lubricant stored in the at least one lubricant reservoir in the lubricant reservoir by means of the lubricant piston. The lubricant piston is further preferably designed to completely displace the lubricant from the lubricant reservoir in order to achieve efficient use of the lubricant stored in the lubricant reservoir.

It is furthermore advantageous if the prestressing means is a compression spring which enables constant pressure to be applied to the lubricant stored in the lubricant reservoir. Compression springs are inexpensive on the one hand and particularly reliable on the other.

In addition, it has proven to be advantageous if the at least one lubricant reservoir is arranged along an axis, in particular along an axis parallel to the longitudinal axis of the housing. The lubricant reservoir can have any shape, for example a cylindrical, polygonal, elliptical shape, the lubricant reservoir being particularly preferred has a constant cross-section along the axis, which enables a lubricant piston to dispense the lubricant stored in the lubricant reservoir in a liquid-tight manner.

A further advantageous embodiment of the invention provides that the at least one lubricant reservoir has an insertion opening on the pressure side and / or the end face of the piston. The insertion opening forms a physical access to the lubricant reservoir in the piston and enables the prestressing means to be inserted into the lubricant reservoir in the manufacture of the gas pressure spring according to the invention. It is furthermore particularly preferred if a cross-sectional area of the insertion opening corresponds to at least one cross-sectional area of the lubricant reservoir, so that the prestressing means, in particular the lubricant piston and the compression spring, can be inserted into the lubricant reservoir through the insertion opening. In addition, after or before inserting the pretensioning agent into the lubricant reservoir, the lubricant can be introduced into the lubricant reservoir through the insertion opening.

In addition, it is also advantageous if the insertion opening is arranged on the pressure side of the piston and is closed with a pressure-tight cover. The arrangement of the cover on the pressure side of the piston does not restrict the fastening of the component to be actuated on the end face of the piston, in particular when replacing a conventional gas pressure spring with a gas pressure spring according to the invention.

The at least one lubricant line advantageously opens into the lateral surface between the pressure side and the end face. In addition, in the area of the lubricant opening, the piston can be provided with a radial groove, which enables the lubricant to be distributed over the circumference of the piston. The lubricant displaced from the lubricant reservoir is thus led directly into the area between the outer surface of the piston and the wall of the cylinder bore of the housing and thus reaches the points in need of lubrication directly.

In addition, it is particularly advantageous if at least one piston seal is arranged between the lubricant opening and the pressure side of the piston, by means of which the gas compression chamber is sealed by the piston and the cylinder wall in the region of the piston. In addition, the piston seal prevents the action of the gas pressure of the gas compression chamber on the lubricant stored in the lubricant reservoir. The lubricant in the lubricant reservoir is therefore not exposed to a pressure change when the gas pressure spring is actuated, as a result of which lubricant could possibly be pressed back into the lubricant reservoir in an uncontrolled manner or could escape in an uncontrolled manner.

In addition, it is also advantageous if a lubricant seal is provided between the end face and the lubricant opening on the lateral surface, by means of which an uncontrolled escape of the lubricant is prevented.

Furthermore, it is advantageous if a guide ring is provided between the pressure side and the end face on the lateral surface, by means of which a concentric and slide-guided guidance of the piston in the cylinder bore is ensured. The guide ring can be formed in one or more parts and can be placed as a band around the piston.

In particular, it has proven to be advantageous if a lubricant film body capable of absorbing lubricant is arranged on the outside of the piston and is in contact with the wall. The lubricant film body capable of absorbing lubricant can preferably be made of a material or a mixture of materials that is capable of transporting the lubricant with the capillary effect. For example, felt or fleece are suitable as the material. The lubricating film body can store the lubricant and distributes it evenly over the wall of the housing, as a result of which, in particular, the wall is uniformly wetted over the entire circumference. Furthermore, the lubricating film body absorbs excess lubricant and thus contributes to an effective and economical use of lubricant, as a result of which the lubricant stored in the lubricant reservoir is sufficient for a long time and protects the gas pressure spring according to the invention against wear.

The lubricating film body is preferably arranged in a recess, the at least one lubricant line particularly preferably opening into the recess. The recess can be designed such that it contributes to the volume of the lubricant and soaks the lubricating film body. The recess is more preferably a radial groove, which extends even more preferably over the entire circumference of the lateral surface.

A further advantageous embodiment of the present invention provides that at least one fill line is provided and that the at least one fill line opens into the at least one lubricant line or the at least one lubricant reservoir. The lubricant can particularly preferably flow from the end face of the piston into the lubricant reservoir be refilled, whereby the life of a gas pressure spring according to the invention can be extended many times by refilling with additional lubricant. When the lubricant is refilled, the preloading means, for example the piston and the compression spring, are returned to their original starting position in the lubricant reservoir and the refilled lubricant is pressurized.

It is particularly advantageous if the filling opening of the filling line is arranged on the end face of the piston or on a tappet arranged on the piston, as a result of which simple handling when refilling the lubricant is achieved. It is particularly preferred if the filling opening is closed with a valve.

In addition, it is advantageous if the cylinder bore has an undercut on a cylinder base. Unnecessary lubricant, old and / or contaminated lubricant and components thereof can accumulate in the undercut without these influencing the tribological system between the wall and the piston. Furthermore, the undercut can have both manufacturing advantages and design advantages, for example in the reduction of stress peaks.

A further advantageous embodiment of the present invention provides that the housing has at least one vent hole. It is particularly preferred if the at least one vent hole is set up to remove excess lubricant and old and / or contaminated lubricant from the cylinder bore, in particular from the undercut.

It is advantageous if the gas compression chamber is filled with nitrogen. Nitrogen is an inexpensive and safe to handle gas that does not react with the materials used for the gas pressure spring or the lubricant.

A further preferred embodiment according to the invention provides that the cylinder bore or the housing is closed with a cover or with a tank plate.

• 1: eine Schnittansicht eines ersten erfindungsgemäßen Ausführungsbeispiels einer Gasdruckfeder mit einem in dem Kolben angeordneten Schmiermittelreservoir, in welchem ein Schmiermittel durch wenigstens ein Vorspannmittel druckbeaufschlagt ist,
• 2: eine Schnittansicht eines zweiten erfindungsgemäßen Ausführungsbeispiels,
• 3: eine Schnittansicht eines dritten erfindungsgemäßen Ausführungsbeispiels.

Three exemplary embodiments of a gas pressure spring according to the invention are explained in detail below with reference to the accompanying figures. Show it:

• 1 1 shows a sectional view of a first exemplary embodiment according to the invention of a gas pressure spring with a lubricant reservoir arranged in the piston, in which a lubricant is pressurized by at least one preloading means,
• 2 1 shows a sectional view of a second exemplary embodiment according to the invention,
• 3 : A sectional view of a third embodiment of the invention.

Below, with reference to the 1 . 2 and 3 three preferred embodiments of a gas pressure spring according to the invention 1 described in detail, functionally identical parts being provided with the same reference numerals.

1 shows a sectional view of a first embodiment of a gas pressure spring according to the invention 1 , The gas pressure spring 1 has a housing 10 and a piston 30 and can be closed by a cover (not shown). The cover can be formed, for example, by a housing cover or a tank plate. The housing 10 is an essentially rotationally symmetrical body in the illustrated embodiment, which is along a longitudinal axis 15 is formed and a circular cylindrical cylinder bore 17 with a wall 19 has, which is coaxial to the longitudinal axis 15 in the housing 10 is incorporated or molded. The housing 10 also has a bottom part 21 with an opening 22 on, the bottom part 21 on the of the cylinder bore 17 facing side a cylinder bottom 18 having.

The piston 30 is in the cylinder bore 17 along the longitudinal axis 15 kept movable and includes an outside 31 made from a printed page 33 , a lateral surface 32 and a face 34 is formed. The shape of the piston 30 corresponds to the shape of the cylinder bore 17 , the piston 30 on the front 34 a pestle 70 which includes the opening 22 in the bottom part 21 be upheld. The piston 30 and the pestle 70 can be formed in one part or in several parts.

In the cylinder bore 17 is through the piston 30 and the wall 19 together with the cover (not shown) a gas compression chamber 20 formed, in which a gas, for example nitrogen, is arranged. The gas is released when the piston moves 30 along the longitudinal axis 15 compresses so that it is in the gas compression chamber 20 a pressure builds up. This pressure creates a restoring force against the pressure side 33 of the piston 30 acts. Such gas pressure springs 1 are used in particular in tools or machines and the like.

Around the gas compression chamber 20 to seal the piston 30 a piston seal 36 , which is inserted in a radial groove. The radial groove is in the lateral surface 32 of the piston 30 immediately adjacent to the printed page 33 incorporated. The piston seal 36 is in said Radial groove for gas-tight sealing of the gas compression chamber 20 educated. To do this, presses in the gas compression chamber 20 prevailing pressure the piston seal 36 on the one hand against the wall 19 of the housing 10 and on the other hand against the piston 30 ,

In the opening 22 is a dirt scraper 74 arranged which is the opening 22 against the pestle 70 closes so that no foreign bodies enter the gas pressure spring 1 can penetrate.

In addition, in 1 shown that both on the lateral surface 32 of the piston 30 as well in the opening 22 one guide ring each 38 . 72 is arranged, the sliding bearing of the piston 30 in the cylinder bore 17 or a sliding bearing of the ram 70 in the opening 22 allows.

The guide ring 38 is on the outer surface 32 of the piston 30 inserted in a radial groove and fixed there, during which the guide ring 72 in a radial groove in the opening 22 of the bottom part 21 of the housing 10 is arranged. The guide rings 38 . 72 can be made of a metallic material or a plastic.

In the flask 30 is a lubricant reservoir 40 incorporated or molded in that is set up a lubricant 4 take. The lubricant reservoir 40 is a circular cylindrical recess in the illustrated embodiment, which is coaxial to an axis 45 in the flask 30 is incorporated or molded. The axis 45 is still coaxial to the longitudinal axis 15 aligned. The circular cylindrical recess of the lubricant reservoir 40 is from the print side 33 in the flask 30 incorporated and points on the print page 33 an insertion opening 46 on that during the operation of the gas pressure spring 1 with a lid 48 , for example by means of a screw connection, is closed.

In the lubricant reservoir 40 is a preloading device for pressurizing the in the lubricant reservoir 40 stored lubricant 4 arranged, which is a lubricant piston 50 as well as a compression spring 52 includes. The compression spring 52 is on the one hand on the lubricant piston 50 and on the other hand on the lid 48 supported. The spring force of the compression spring 52 pressurizes this in the lubricant reservoir 40 stocked lubricants 4 ,

The insertion opening 46 provides physical access to the lubricant reservoir 40 and is used in the manufacture of the gas spring 1 for mounting the preload in the lubricant reservoir 40 needed. For this purpose, the insertion opening points 46 a cross-sectional area that is larger than a cross-sectional area of the lubricant reservoir 40 or the biasing means transverse to the axis 45 , The lid 48 to close the insertion opening 46 can then be sealed gas-tight and liquid-tight with the help of sealing agents.

The lubricant reservoir 40 is symmetrical to the longitudinal axis with at least two, in the present exemplary embodiment exactly two 15 arranged lubricant lines 42 with the outer surface 32 of the piston 30 connected. The lubricant 4 can on the lateral surface 32 through one lubricant opening each 43 into an annulus between the pistons 30 and the wall 19 escape. To improve the distribution of the lubricant 4 about the circumference of the piston 30 or the wall 19 can be reached in the area of the lubricant opening 43 a radial groove in the piston 30 be incorporated.

The two lubricant lines 42 flow into the from the lid 48 opposite side of the lubricant reservoir 40 into the lubricant reservoir 40 and can do that from the lubricant reservoir 40 through the lubricant piston 50 displaced lubricants 4 to the lateral surface 32 and the neighboring surfaces there, and especially the lateral surface 32 and the wall 19 with lubricant 4 wet.

It is also located between the front 34 and the lubricant opening 43 a lubricant seal 37 that together with the piston seal 36 closes an annulus, causing the lubricant 4 not unhindered the annulus between the outer surface 32 of the piston 30 and the wall 19 the cylinder bore 18 can leave.

The lubricant piston 50 can be provided with a seal, which on a lateral surface of the lubricant piston 50 a gap between the lubricant piston 50 and a wall of the lubricant reservoir 40 seals.

lubricant 4 can in the lubricant reservoir 40 by means of a filling line 60 be refilled. The filling line 60 extends from a free end of the plunger 70 on the front 34 facing side of the piston 30 from a filling opening 62 to the lubricant reservoir 40 , The filling line 60 is coaxial to the axis 45 and the longitudinal axis 15 aligned and opens into the center of the lubricant reservoir 40 , The filling opening 62 can be closed with a valve, in particular a one-way or non-return valve.

In the transition area between the wall 19 and the cylinder bottom 18 is in the housing 10 an undercut 24 arranged. The undercut 24 is a local cross-sectional expansion in the cylinder bore 17 that there is unnecessary, old and / or contaminated lubricant 4 allows you to sit down. The undercut 24 enables lubricant deposits and accumulations without affecting the functionality of the gas pressure spring 1 comes. The undercut 24 can also enable manufacturing advantages and design advantages. The undercut 24 can with a vent hole 25 be connected to the housing as a through hole 10 can be penetrated and closed with a stopper or a valve.

2 shows a longitudinal section through a second embodiment of the gas pressure spring 1 , the exemplary embodiments in the 1 and 2 in the formation of the lubricant reservoir 40 and the filling line 60 differ.

The lubricant reservoir 40 in 2 is a blind hole from the pressure side 33 in the flask 30 incorporated. The lubricant reservoir 40 is essentially circular cylindrical along the axis 45 educated. The axis 45 is parallel and spaced from the longitudinal axis 15 of the housing 10 arranged. Still is 2 that the lubricant reservoir 40 along the axis 45 has a substantially constant cross section. On the print page 33 is the lubricant reservoir 40 by means of the lid 48 locked.

In the lubricant reservoir 40 the biasing means is arranged, which in turn consists of a compression spring 52 and a lubricant piston 50 is formed. The compression spring 52 is supported at one end at the end of the blind hole and at the other end at the lubricant piston 50 , Accordingly, the lubricant piston 50 along the axis 45 biased, the direction of action of the compression spring 52 and the lubricant piston 50 towards the lid 48 or the lubricant line 42 is directed.

The gas pressure spring also points 1 according to 2 a refill line for refilling 60 on that are spaced apart from the longitudinal axis 15 and the lubricant reservoir 40 in the pestle 70 is incorporated or molded. The filling line 60 is designed as a blind hole and extends from the front of the plunger 70 down to the lubricant line 42 and flows into this. The filling opening 62 the filling line 60 is closed by a valve.

The longitudinal section in 2 shows two lubricant lines 42 , basically a lubricant line 42 sufficient to cover the outer surface 32 of the piston 30 with the lubricant 4 to supply. However, it has proven to be advantageous if several lubricant lines 42 in particular symmetrically about the longitudinal axis 15 are arranged, whereby on the one hand an even distribution of lubricant is achieved over the circumference and on the other hand no radial force between the wall 19 and the piston 30 is applied by the biasing means through which the piston may be 30 eccentric in the cylinder bore 17 could be moved.

3 shows a longitudinal section through a third embodiment of the gas pressure spring 1 , The third exemplary embodiment differs from the first two exemplary embodiments in accordance with 1 and 2 in that the piston 30 on the outside 31 at the mouth of the lubricant line 42 a film body 35 having.

The film body 35 is made of a lubricant-absorbent material, which is a capillary transport of the lubricant 4 can accomplish. In the exemplary embodiment shown, the lubricating film body is 35 a felt ring coming out of a recess 39 on the lateral surface 32 of the piston 30 protrudes and the wall 19 of the housing 10 contacted. The recess 39 can be used as a radial groove in the lateral surface 32 be incorporated or molded. The lubricant line 42 opens into the recess, the recess 39 through an appropriate design, the amount of in the piston 30 stored lubricant 4 can increase.

The capillary forces in the film body 35 distribute the lubricant 4 over the entire circumference of the lateral surface 32 , Furthermore, the lubricating film body limits 35 and promotes the controlled and resource-saving use of the lubricant 4 ,

In all three described embodiments, both the lubricant reservoir 40 as well as the fill line 60 anywhere in the piston 30 to be ordered. The prestressing means can also be designed and / or arranged in many ways, for example in the cover 48 , Furthermore, the insertion opening 46 on the front 34 of the piston 30 or on the front of the ram 70 be arranged. It is also conceivable that both the insertion opening 46 , as well as the filling opening 62 on a lateral surface of the ram 70 or the lid 48 are arranged.

LIST OF REFERENCE NUMBERS

1

Gas spring

4

lubricant

10

casing

15

longitudinal axis

17

bore

18

cylinder base

19

wall

20

Gas compression chamber

21

the bottom part

22

opening

24

Freeway

25

vent hole

30

piston

31

outside

32

lateral surface

33

pressure side

34

front

35

Lubricating film body

36

piston seal

37

lubricant seal

38

guide ring

39

recess

40

lubricant reservoir

42

lubricant line

43

lubricant opening

45

axis

46

insertion

48

cover

50

lubricant pistons

52

compression spring

60

filling line

62

fill opening

70

tappet

72

guide ring

74

wipers

Claims (19)

Gas spring (1) comprising: - A housing (10) with a longitudinal axis (15) and a cylinder bore (17) extending in the longitudinal axis (15) with a wall (19), and a piston (30) which is displaceable in the cylinder bore (17) along the longitudinal axis (15), - The piston (30) has an outer side (31), comprising a lateral surface (32), a pressure side (33) and an end face (34), - A gas compression chamber (20) is formed between the piston (30) and the housing (10), - The piston (30) has at least one lubricant reservoir (40) for a lubricant (4), - The at least one lubricant reservoir (40) is connected to the outside (31) by at least one lubricant line (42), and - The at least one lubricant reservoir (40) has at least one biasing means through which the lubricant (4) can be pressurized. Gas spring (1) after Claim 1 , characterized in that the at least one lubricant reservoir (40) comprises a movable lubricant piston (50) which can be pressurized by means of the preloading means. Gas spring (1) after Claim 1 or 2 , characterized in that the biasing means is a compression spring (52). Gas pressure spring (1) according to one of the preceding claims, characterized in that the at least one lubricant reservoir (40) is arranged along an axis (45), in particular that the at least one lubricant reservoir (40) along an axis (45) parallel to the longitudinal axis ( 15) is arranged. Gas spring (1) after Claim 4 , characterized in that the at least one lubricant reservoir (40) has a constant cross section along the axis (45). Gas pressure spring (1) according to one of the preceding claims, characterized in that the at least one lubricant reservoir (40) has an insertion opening (46) on the pressure side (33) and / or the end face (34). Gas spring (1) after Claim 6 , characterized in that a cross-sectional area of the insertion opening (46) corresponds to at least one cross-sectional area of the at least one lubricant reservoir (40). Gas spring (1) after Claim 6 or 7 , characterized in that the insertion opening (46) is arranged on the pressure side (33) and is closed with a cover (48). Gas pressure spring (1) according to one of the preceding claims, characterized in that the at least one lubricant line (42) opens on the lateral surface (32) between the pressure side (33) and the end face (34). Gas pressure spring (1) according to one of the preceding claims, characterized in that at least one piston seal (36) is arranged between the pressure side (33) and the end face (34) on the lateral surface (32). Gas pressure spring (1) according to one of the preceding claims, characterized in that at least one guide ring (38) is provided between the pressure side (33) and the end face (34) on the lateral surface (32). Gas pressure spring (1) according to one of the preceding claims, characterized in that at least one lubricant film body (35) which is capable of absorbing lubricant is provided and is in contact with the wall (19) of the housing (10). Gas spring (1) after Claim 12 , characterized in that the at least one lubricating film body (35) is arranged in a recess (39) on the outside (31) of the piston (30) and in that the at least one lubricant line (42) opens into the recess (39). Gas pressure spring (1) according to one of the preceding claims, characterized in that at least one filling line (60) is provided for refilling the lubricant (4), and that the filling line (60) in the at least one lubricant line (42) or the at least one lubricant reservoir (40) opens. Gas pressure spring (1) according to one of the preceding claims, characterized in that the at least one filling line (60) has a filling opening (62) on the end face (34) of the piston (30). Gas pressure spring (1) according to one of the preceding claims, characterized in that the cylinder bore (17) has an undercut (24) in the region of a cylinder base (18). Gas pressure spring (1) according to one of the preceding claims, characterized in that the housing (10) has at least one vent hole (25). Gas pressure spring (1) according to one of the preceding claims, characterized in that the gas compression chamber (20) can be filled with nitrogen. Gas pressure spring (1) according to one of the preceding claims, characterized in that the cylinder bore (17) is closed with a cover.

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