EP0298315B1 - Scroll-type displacement engine - Google Patents

Abstract

In a rotary-piston displacement machine, to seal the flat sealing planes between the end faces of the displacement body (5), executing a circular motion, and the side faces (20) of the stationary housing (7) which run parallel thereto, the end faces of the displacement body (5) are provided with a groove (13) in which an elastic sealing strip (14) made of slideable material is inserted. The sealing strip is pressed by a silicone tube (15) against the side wall (20).

Description

The invention relates to a rotary piston displacement machine for compressible media, with at least one conveying space delimited by spiral, circumferential walls axially extending from a side wall, which leads from an inlet to an outlet, and with a spiral-shaped displacer projecting into the conveying space, with respect to is mounted on the conveying space for executing a circular twist-free movement and the center of which is eccentrically offset relative to the center of the peripheral walls such that the displacement body always touches both the outer and the inner peripheral wall of the conveying space at at least one progressive contact point, which touches the Side wall bordering end faces of the displacer are provided with a groove in which a sealing strip made of elastic and slidable material is inserted, and wherein between the bottom of the groove and the underside of the sealing strip e is arranged in the spring element.

EP-A-0 124 114 discloses the use of a hose made of an elastic material to form a spring element in a rotary displacement machine. In this solution, however, the element does not form the base for an elastic sealing strip, but at the same time exercises the function of the necessary sealing element.

A displacement machine of the type mentioned is known from US 3,994,636. In order to achieve an effective radial seal between the end faces of the displacer and the side walls of the delivery chamber, an effective axial contact must be made between the two elements. For this purpose, the displacer is provided with a groove on its end face; the seat is for a sealing strip lying therein. This sealing strip consists of an elastic, slidable material and is dimensioned such that it can be moved axially and slightly radially within the groove. It is underlaid by a force-exerting spring element, which is a metallic spring band with a U-shaped cross section.

With small spiral loaders, however, the design of the groove is limited. If, for example, the displacer only has a total thickness of 4 mm, the groove width can be a maximum of 2 mm. In this case, the design mentioned has two shortcomings: On the one hand, the spring element must, if it is to cover the entire Nutresp. Extend sealing length, mechanically pre-bent to adapt to the spiral course of the groove; On the other hand, the achievable spring travel is extraordinarily small, as can be seen in the rest of FIG. 8 of said document; This has an unfavorable effect on the constancy of the contact pressure due to the spring characteristics.

From this same publication it is known to achieve greater spring travel through the use of helical springs, of which a certain number are evenly distributed in corresponding bores in the groove over the sealing length (FIGS. 5, 6 of US Pat. No. 3,994,636). This solution, however, increases the cost of manufacturing the displacer and makes the assembly of the charger considerably more difficult.

From the same US 3,994,636 it is also known to use rubber cords as spring-elastic means. However, such round cords have the disadvantage that they have a relatively flat spring characteristic, i.e. are relatively stiff. They are only able to compensate to a limited extent for the tolerances that arise during the manufacture and assembly of the machine. In addition, they have a tendency to change or even lose the spring properties as a result of settling phenomena that occur over the course of the operating time.

The invention is therefore based on the object to provide a soft spring element in a rotary piston displacement machine of the type mentioned, which also allows easy handling, and with its spring force a safe and flawless sealing of the work spaces is guaranteed over longer operating times.

According to the invention, this is achieved with the characterizing features of patent claim 1.

The advantage of the invention is to be seen in particular in the fact that the multi-part hose, which is easy to produce, can follow any radius of curvature in the intended bending plane without twisting, and that it can withstand temperatures of up to 150 ° C. without further ado.

An embodiment has proven to be particularly expedient in which the inlet end of the hose is closed, while its outlet end is open. The inside of the hose is thus acted upon by the respective boost pressure. At partial load, the contact pressure of the sealing strip against the corresponding wall and thus also the friction loss is reduced in particular. Such a solution is known in principle from DE 31 40 512 AI. This resulted in a particularly advantageous embodiment of the sealing strip with a rear channel which can be pressurized. In an easy-to-implement form, the sealing strips have the form of rectangular sealing strips, which are embedded in a channel that matches the width, but which, at depth, keeps a rear channel space free. This rear channel space can be connected to the pressure side of the displacement machine and is intended to provide a uniform pressurization of the sealing strips from the rear and thus a uniform contact of the sealing strips even with increasing wear. However, it should not be overlooked that with this solution the sealing strips must also fit very tightly on the sides so that the pressure does not escape from the rear area into the work area.

• Fig. 1 einen Querschnitt durch den Rotationskolbenverdichter mit stirnseitiger Ansicht des Verdrängungskörpers,
• Fig. 2 einen etwas vergrösserten Teilschnitt durch die Ebene A-A in Fig. 1, und
• Fig. 3 einen Schnitt in Perspektive durch eine Dichtanordnung.

In the drawing, an embodiment of the subject of the invention is shown schematically. It shows:

• 1 shows a cross section through the rotary piston compressor with an end view of the displacement body,
• Fig. 2 is a somewhat enlarged partial section through the plane AA in Fig. 1, and
• Fig. 3 shows a section in perspective through a sealing arrangement.

In the drawing, all parts that are insignificant for understanding the invention, such as, for example, the drive, the bearing and the guidance of the rotor, the inflow and outflow of the working medium are omitted.

The machine shown is shown for the sake of simplicity with only one delivery chamber 6 and only one displacer 1. It goes without saying, however, that the displacer can have a whole system of spirals in the same plane, each of which, for example, can convey a common outlet 3 from its own inlet 2.

For an explanation of the operation of the compressor, which is not the subject of the invention, reference is made to DE 26 03 462 C3. Only the machine structure and process flow necessary for understanding the invention are briefly described below.

The disk-shaped displacer is designated as a whole by 1. Spiral displacement bodies 5 are arranged on both sides of the disk 4. These engage in a delivery chamber 6 of the fixed housing 7. The conveying space 6 is, for example, incorporated into the housing 7 in the manner of a spiral slot. It extends from an inlet 2 arranged on the outer circumference of the spiral in the housing to an outlet 3 arranged inside the housing. It has essentially parallel circumferential walls 8, 9 which are arranged at a constant distance from one another and which, like the displacement body, has a spiral of more than 360 ° include. The displacement body 5 is held between these peripheral walls 8, 9. Its curvature is dimensioned so that it touches the inner and outer peripheral walls in several places. For this purpose, the center 10 of the displacement body 5 is offset eccentrically with respect to the center 11 of the delivery chamber 6.

During operation of the machine, the eccentric drive of the disk-shaped rotor having the displacement body 5 results in a circular movement of each of the points of the displacement body, this circular movement being limited by the peripheral walls of the delivery chamber. As a result of the multiple, alternating approach of the displacer body to the inner and outer circumferential walls, crescent-shaped work spaces 12 enclosing the working medium result on both sides of the displacer body, which are advanced by the eccentric drive of the displacer body through the delivery space in the direction of the outlet. The volume of these working spaces is reduced and the pressure of the working fluid increases accordingly.

To seal the flat sealing planes between the end faces of the displacement body 5 and the side surfaces 16 of the delivery chamber 6 running parallel thereto, the displacement bodies are now provided on the end face with a circumferential groove 13, in which an elastic sealing strip 14 made of slidable material lies.

It can be seen from FIG. 2 that this groove 13 has a rectangular shape and receives the likewise rectangular sealing strip 14. As an example of an actual design, the cross-section of the sealing strip is approximately 1.8x2.3 mm with a groove width of approximately 2 mm. With parallel walls, this ensures both axial (outward) and slightly radial displaceability of the sealing strip.

If the sealing strip should protrude about 0.4 mm over the edge of the end face during normal operation, the corresponding groove depth results from the sealing strip height remaining in the groove plus the space required for the force-exerting spring element.

3 shows the configuration of this spring element 15 and its arrangement in the groove.

It is a thin tube of silicone rubber, such as that used throughout the medical sector. In the present case, its outside diameter is 2 mm.

A particular advantage is the property that the hose can easily follow any curve.

Furthermore, due to its all-round contact, the hose cannot slip in the longitudinal direction of the groove.

It is not difficult to see that for a given total spring height, which basically corresponds to the outside diameter of the hose, the choice of wall thickness is a simple means to set the required spring force. However, it should be noted that there is in principle no deformation and therefore no change in the spring load during operation. Nevertheless, the spring according to the invention is particularly effective even with greater abrasion of the sealing strip 14, since - starting from the compressed state, in which it has a height of twice the wall thickness - it is able to relax to its full diameter with an approximately constant spring force .

Of course, it is quite possible to use a multi-part hose with different wall thicknesses within a spiral groove. A greater wall thickness than inlet 2, where the tightness requirements are low, could be installed, for example, in the zone from outlet 3, since there are higher working pressures in the delivery chamber 6 and greater pressure on the sealing strip 14 on the side wall 16 may be desirable.

In another embodiment, not shown, the groove 13 has on the pressure side, i.e. at the outlet end of the spiral, an outlet part that either extends beyond the area of the sealing strip or by which the sealing strip is shorter than the groove. In this area the hose is open so that the inside of the machine is pressurized with the final pressure. As a result, a uniform contact of the sealing strip over the entire length thereof is achieved on the side surface 20. So that the pressurization inside the hose but at the other hose end does not lead to a constant loss of working fluid, the end on the inlet side is closed.

It can also be seen from FIG. 2 that not only the end faces of the displacement body 5 are sealed in accordance with the invention, but that the type of seal can also be used for the adjoining surfaces of the disk 4 exerting the circular movement and the standing rib of the housing 7.

Claims (2)

1. Rotary-piston displacement machine for compressible media, comprising at least one delivery space (6) which is defined by spiral-shaped peripheral walls (8, 9), extending axially from a side wall (20), and leads from an inlet (2) to an outlet (3), and comprising a spiral-shaped displacement body (5) which protrudes into the delivery space (6) and is mounted with respect to the latter for executing a circling, torsion-free motion and at its centre (10) is offset eccentrically relative to the centre (11) of the peripheral walls (8,9) in such a way that the displacement body (5) always touches both the outer and the inner peripheral wall (8 and 9 resp) of the delivery space (6) at at least one advancing contact point each, wherein the end faces of the displacement body (5) which adjoin the side wall (20) are provided with a groove (13) in which a sealing strip (14) made of an elastic and slideable material is inserted, and wherein a spring element (15) is arranged between groove root and the underside of the sealing strip (14), characterized in that the spring element is a tube of silicone rubber and in that the tube is made up of a plurality of parts of different wall thickness.

2. Rotary-piston displacement machine according to Claim 1, characterized in that the tube (15), extending over the entire length of the groove (13), is closed at its end on the suction side and is open at its end on the pressure side.

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