FR2739900A1 - Air or gas compressor of hypotrochoidal construction - Google Patents

Abstract

The compressor has a facility (53,54,55) for altering the angular position, in the circumferential direction, of the metering edge (44a) of the inlet port (40) of the eccentric shaft (14) which establishes start of the compressor. The facility has a device which is dependent upon the RPM of the eccentric shaft. The inlet port is divided in the axial direction into two sections (41,42), with one section (41) provided in the shaft, and the other accommodated in a sleeve (55) which is rotatable in the circumferential direction on the shaft.

Description

The invention relates to a compressor of hypocycloidal construction comprising a rotor housing, in which rotates a rotary piston rotor, which is mounted on a hollow eccentric shaft, which is provided with an inlet opening limited in the peripheral direction. by means of substantially axially extending control edges defining the start of the suction and the start of the compression, with which are associated radial suction channels of the rotary piston rotor, which open into chambers formed between the rotary piston rotor and the rotor housing, the rotor housing being provided in the region of these chambers with exhaust openings controlled by means of pressure valves.

A known compressor of the aforementioned type is currently used as an air pump. Its flow rate directly depends on the drive rotation speed at which the eccentric shaft is driven. At high drive speeds there is a high flow rate, while at low drive speeds there is a low flow rate.

The old refrigerant compressors also exhibited a similar behavior, that is to say that in these also the flow of the refrigerant directly depended on the rotational speed of the drive, i.e. the momentary speed of the motor. Since this direct dependence is unfavorable on the one hand for driving comfort and on the other hand also for the action of an air conditioning installation of a motor vehicle, the automobile industry currently requires that in compressors of refrigerant the flow is variable regardless of the current drive rotation speed, for example is kept constant for a variable rotation speed. In practice, this behavior is only achievable for swash plate piston compressors , in which the piston stroke and therefore the flow are varied, by means of a different oblique position of the swash plate.

The object of the invention is to configure a compressor of hypocycloidal construction of the aforementioned type, so that its flow rate does not only depend on the speed of rotation of the drive, but can be kept constant or modified independently of the speed of rotation of training. This object is achieved in that a device is provided for varying the angular position in the peripheral direction of the control edge, defining the start of compression, of the intake opening of the eccentric shaft.

Thanks to this configuration, it is possible, by varying the angular position of the control edge, defining the start of compression, to vary the degree of filling of the different chambers, which also modifies the flow rate. It is to be expected that a compressor of this type, of hypocycloidal construction, will offer considerable advantages compared to the known swash plate piston compressors with variable position of the swash plate because, on the one hand there is no masses moving in a reciprocating movement, so that much higher speeds of rotation are possible, while on the other hand the manufacture becomes less expensive.

In another variant of the invention, it is provided that the device contains means, depending on the speed of rotation of the eccentric shaft, for varying the angular position of the control edge, defining the start of compression, from the admission opening. It is thus possible to adjust the compressor flow rate so that it is kept constant, regardless of the speed of rotation.

In an advantageous embodiment, it is provided that the intake opening is divided axially into two portions, one portion of which is provided in the eccentric shaft, while the other portion is housed in a sleeve placed rotating in the peripheral direction on the eccentric shaft. By rotation of this sleeve relative to the eccentric shaft one can quite simply modify the angular position of the control edge defining the start of compression.

According to other characteristics of the invention - the sleeve can rotate by means of an adjustment device placed inside the eccentric shaft, - the adjustment device contains weights rotating with the shaft eccentric, which act on the sleeve, by means of a transmission mechanism, containing a return spring, - the transmission mechanism contains an axially sliding rod, which is provided with a rod, which is axially sliding guide in the eccentric shaft and which engages in a guide slot, extending obliquely to the longitudinal axis, of the sleeve, - on the eccentric shaft are mounted weights, which are connected with the rod which can slide axially.

- the eccentric shaft, the rotary piston rotor and the rotor housing are placed in a housing, which, with the exception of a suction connection, a pressure connection and an inlet for the the eccentric shaft is closed in a pressure-tight manner, and in that in the entrance area there is a shaft seal for the eccentric shaft, the pressure connection is connected, by a sealed flow path, with the open end of the hollow eccentric shaft, and in that the pressure connection is connected with the rotor housing, by a sealed flow path, - the shaft eccentric consists of two assembled parts, each having a centered shaft journal and an eccentric bearing seat for the rotary piston rotor, the areas of the eccentric bearing seats being hollow and nested one inside the other , - the exhaust openings are located in the area of the chamber angles located at the front ant, - the exhaust openings are placed in lateral parts which axially cover the rotary piston rotor.

Various other characteristics of the invention will also emerge from the detailed description which follows.

An embodiment of the invention is shown by way of non-limiting example in the accompanying drawings.

Fig. l is an axial section view of a compressor according to the invention for a refrigerant,
Fig. 2 is a view in partial radial section of the compressor of FIG. 1.

Fig. 3 is a perspective view of part of the eccentric shaft of FIG. 1, in the area of a variable intake opening.

The compressor, shown in FIG. 1, of hypocycloidal construction, has an external casing 10 in the form of a pot, the open side of which is closed by means of a cover 11. The cover 11 penetrates with a flange 12 into the cylindrical casing 10 The collar 12 is provided with a sealing ring 13 inserted. In the casing 10 is mounted an eccentric shaft 14, the drive end 15 of which comes out of a flange 16 from the bottom of the casing 10.

The eccentric shaft 14 is sealed in the appendix 16 in the form of a collar, with respect to the outside, with a shaft seal 17 on the market, in particular a seal with a sliding ring.

The eccentric shaft 14 is made up of two assembled parts. Each of these parts has a centered shaft pin 18, 19, with which the eccentric shaft 14 is mounted in two lateral flanges 20, 21. The shaft pins 18, 19 are each mounted by means of a rolling bearing 22, 23 in bearing seats 24, 25 of the lateral flanges 20, 21. The lateral flanges 20, 21 are placed in an axial cutout of the casing 10 and are made watertight with respect thereto, by rings of sealing 26, 27, 28. The lateral flange 20 bears axially against a shoulder 29 of the casing 10.

Between the shaft journals 18, 19, the two parts of the eccentric shaft 14 are each provided with a cylindrical extension 30, 31, in the form of a sleeve, which are placed eccentric with respect to the tree journals 18 , 19. The sleeve-shaped part 30 is threaded into the sleeve-shaped part 31 and is assembled therewith by means of a tight fit. On the two parts 30, 31 in the form of a sleeve is mounted rotating a rotary piston rotor 32, by means of rolling bearings 33, 34, preferably needle bearings, so that the two extensions 30, 31 in the form of sleeves form eccentric bearing seats. The rotary piston rotor 32, the shape of which is visible in FIG. 2, rotates in a rotor housing 35, the inner contour of which is also visible in FIG. 2. The rotary piston rotor 32 and the rotor housing 35 form a rotary piston machine, of hypocycloidal construction (classification KIII-5 "Einteilung der
Rotationskolbenmaschinen "F. Wankel). The rotor casing 35 is kept fixed in the casing 10, between the lateral flanges 20, 21. A plate 36 is also provided between the lateral flange 21 and the rotor casing 35, against which is applies on one side the rotor casing 35 and on the other side, the side flange 21. The group consisting of the eccentric shaft 14, side flanges 20, 21, of the plate 36 and of the piston rotor 32 and the rotor housing 35, is pre-assembled as a construction unit, which is introduced from the open side, into the housing 10 and which is then fixed by means of the cover 11.The cover 11 is fixed so not shown in detail, by means of clamping screws, on the casing 10.

The shaft pin 19 is hollow and forms a connection between the interior volume of the eccentric extensions 30, 31 of the eccentric shaft and a suction chamber 37, in the region of the cover 11. This suction chamber 37 is provided with a suction connection 38. The eccentric extensions 30, 31 of the eccentric shaft are provided with an inlet opening 40, which is limited in the peripheral direction, by control edges 43, 44. The inlet opening 40 is associated with suction channels 45 of the rotary piston rotor 32, which periodically connect the inlet opening 40 with the chambers, which are located between the rotary piston rotor 32 and the rotor housing 35. The rotor housing 35, which has the internal shape of a hypocycloid with a 7: 6 ratio, has, in the front corners - in the direction of rotation A of the eccentric shaft 14 - intake openings 47, with which pressure valves 48 are associated. The pressure valves 48 consist of a resilient valve plate 49 and a stroke limitation 50, which are fixed together with a screw 51. In the area of each of the front corners, there are intake openings 47 of this type with pressure valves 48 which, for simplicity, are not shown in FIG. 2.

When the eccentric shaft 14 rotates around the centered axis 52, in the direction of arrow A, the rotary piston rotor turns in the rotor housing 35 in the manner of a toothed wheel, its direction of rotation B being opposite to the direction of rotation A of the eccentric shaft 14.

With each rotation of the eccentric shaft 14, the volume of all the chambers changes, going from a minimum to a maximum and again to the minimum. The inlet opening 40 is designed, that is to say that the angular positions of the control edges 43, 44 are fixed so that in the case of an increase in volumes, it releases the connection to the channels 45 and close it in case of reduced volumes. It therefore occurs during the increase in volumes, aspiration and during the reduction in volumes, compression. The pressure valves 48 in this case determine, on the basis of their design, the maximum compression pressure. The fluid transported by the compressor reaches, through the pressure valves 48, in pressure channels 71, which are provided on the periphery of the rotor casing 35 and the casing 10. The following plate 36 is provided with openings 72, assigned to these pressure channels 71, so that the compressed fluid flows in an annular channel 73, formed by the lateral flange 21. The casing 10 is provided, in the region of this annular channel 73, with a connection pressure 74, which is in connection with the annular channel 73, through an opening.

To obtain that the flow rate of the compressor described does not depend exclusively on the speed of rotation of the eccentric shaft and therefore on the drive speed of a drive motor, it is provided that the angular position of the edge of command 44, which determines the start of compression, is variable. If the angular position of the control edge 44 is moved back in the opposite direction to the direction of rotation A, the connection between the intake opening 40 and the suction channel 45 of the chambers is open over a fairly large angular distance and therefore for a fairly long period of time, so that there is already a reduction in the volumes of the rooms, without there being compression. The degree of filling of the chambers is thus reduced, so that the flow rate is reduced accordingly. In an extreme case, the control edge 44 can be moved back in the opposite direction to the direction of rotation A, so far that it there is absolutely more traffic.

The variation of the angular position of the control edge 44 of the intake opening 40 is described in more detail with reference to the view in FIG. 3. As shown in fig. 3, the intake opening 40 is divided into two portions 41, 42 juxtaposed axially. The portion 41 is placed in the eccentric extensions 30, 31 of the eccentric shaft 14. It also extends axially on the portion 42, which is an integral part of a sleeve 53, placed rotating on the eccentric extension 30. The portion 41 is therefore fixed relative to the eccentric extensions 30, 31, while the portion 42 can rotate in the peripheral direction.

The control edge 43 consists of a control edge 43a of the portion 42 and a control edge 43b of the portion 41. When the sleeve 43 is rotated in the opposite direction to the direction of rotation A of the 'eccentric shaft 14, the control edge 43b always determines the start of suction. The variation of the angular position of the control edge 43a remains here without influence. The control edge 44 consists, correspondingly, of the control edge 44a, of the portion 42, of the sleeve 43 and of the control edge 44b of the portion 41. The angular position of the control edge 44a defines the start of the compression, when it does not coincide, as in the view of figs. 2 and 3, with the angular position of the control edge 44b.

The rotation of the sleeve 53 and therefore the variation of the angular position of the control edge 44a is effected by means of an adjustment device, which is shown in FIG. 1. This adjustment device is above all dependent on the speed of rotation, that is to say that when the speed of rotation increases, the angular position of the control edge 44a is moved in the opposite direction to the direction of rotation A of the eccentric shaft 14, so that the start of compression is delayed. It is thus possible, by appropriate sizing, to keep the flow constant, regardless of the drive rotation speed. The sleeve 53, placed on the eccentric extension 30, which is applied axially against the front end of the extension 31 and which is fixed by means of a locking ring, is provided with a slot 54 extending obliquely to the longitudinal axis, in which engages a rod 55, which is guided in two axial slots 56, 57 of the extension 30. The rod 55, placed in a guide element 58, engages in an eyelet of a pull-up bar 59. The other end of the pull-up bar 59 is provided with a tip 60 in the form fork, in which engage the trainers 61 of weights 62, 63. The weights 62, 63 can pivot around axes 64, 65, which are placed in the end of the shaft journal 19 of the shaft d eccentric 14. The drawbar 59 is surrounded by a return spring 66 prestressed, which is placed between a guide sleeve 67, surrounding the drawbar 59, bearing against the guide element 58, and a ring 68, provided with cutouts of large area. The ring 68 is fixed by means of a locking ring inside the shaft journal 19.

The counterweights 62, 63 rotating with the eccentric shaft 14, urge the rod 55 against the return spring, with a force depending on the speed of rotation of the eccentric shaft 14. The dimensioning of the counterweights 62, 63 and of the return spring 66 is such that the rod 55 is moved axially, so that it displaces the sleeve 53 peripherally, so that even when the speed of rotation varies, the flow rate of the compressor is as constant as possible.

The eccentric shaft 14 is balanced by means of compensation discs 69, 70, which are fixed to the shaft journal 18, 19.

In an alternative embodiment it is preferred that the drawbar 59 comes out from the inside of the casing, and that on the drawbar 59 acts an adjustment control or an adjustment regulation. In this case it is possible to dispense with the counterweights 62, 63 and / or to superimpose an additional adjustment function on the adjustment by means of the counterweights 62, 63.

In the embodiment shown, the suction connection 38 and the pressure connection 74 are arranged radially. It is obviously also possible to provide, in the region of the cover 11, axially directed connections, a connection then having to be provided in a cover of this type, between its pressure connection and the suction channels 71.

In another alternative embodiment, there are provided, instead of the substantially radial exhaust openings 47 of the rotor housing 35, exhaust openings, which are shown in dashed lines in FIG. 2, in the lateral flange 20 and the plate 36, which are then also provided with pressure valves 48.

Claims (12)

1. Compressor of hypocycloidal construction comprising a rotor housing, in which rotates a rotary piston rotor, which is mounted on a hollow eccentric shaft, which is provided with an inlet opening limited in the peripheral direction by means of control edges extending substantially axially, defining the start of suction and the start of compression, with which are associated radial suction channels of the rotary piston rotor, which open into chambers formed between the piston rotor rotary and the rotor housing, the rotor housing being provided in the region of these chambers with exhaust openings, controlled by means of pressure valves, characterized in that a device (53, 54, 55) is provided for varying the angular position in the peripheral direction of the control edge (44a), defining the start of compression, of the intake opening (40) of the eccentric shaft (14). 2. Compressor according to claim 1, characterized in that the device (53, 54, 55) contains means (59, 62, 63), depending on the speed of rotation of the eccentric shaft (14), for varying the angular position of the control edge (44a), defining the start of compression, of the intake opening (40). 3. Compressor according to any one of claims 1 or 2, characterized in that the intake opening (40) is divided axially into two portions (41, 42), a portion (41) of which is provided in the eccentric shaft (14), while the other portion (42) is housed in a sleeve (53) placed rotating in the peripheral direction on the eccentric shaft (14). 4. Compressor according to claim 3, characterized in that the sleeve (53) can rotate by means of an adjustment device (55, 59, 62, 63), placed inside the eccentric shaft ( 14). 5. Compressor according to claim 4, characterized in that the adjustment device contains weights (62, 63) rotating with the eccentric shaft (14), which act on the sleeve (53), by means of a transmission mechanism (55, 59, 60), containing a return spring (66). 6. Compressor according to claim 5, characterized in that the transmission mechanism contains a rod (59) sliding axially, which is provided with a rod (55), which is guided sliding axially in the eccentric shaft (14 ) and which engages in a guide slot (54), extending obliquely to the longitudinal axis, of the sleeve (53). 7. Compressor according to claim 6, characterized in that on the eccentric shaft (14) are mounted weights (62, 63), which are connected with the rod (59) which can slide axially. 8. Compressor according to any one of claims 1 to 7, characterized in that the eccentric shaft (14), the rotary piston rotor (32) and the rotor housing (35) are placed in a housing ( 10, 11) which, with the exception of a suction connection (38), a pressure connection (74) and an inlet for the eccentric shaft (14), is closed so pressure-tight, and in that in the entry area there is a shaft seal (17) for the eccentric shaft (14). 9. Compressor according to claim 8, characterized in that the pressure connection (38) is connected, by a sealed flow path, with the open end of the hollow eccentric shaft (14), and in that that the pressure connection (74) is connected with the rotor housing (35), by a sealed flow path (71, 72, 73). 10. Compressor according to one of claims 1 to 9, characterized in that the eccentric shaft (14) consists of two assembled parts, which each have a centered shaft journal (18, 19) and a seat eccentric bearing housing (30, 31) for the rotary piston rotor (32), the areas of the eccentric bearing seats being hollow and nested one inside the other. 11. Compressor according to one of claims 1 to 9, characterized in that the exhaust openings (47) are located in the area of chamber angles located at the front. 12. Compressor according to one of claims 1 to 11, characterized in that the exhaust openings (75) are placed in lateral parts (20, 36) which axially cover the rotary piston rotor (32).