SE521271C2 - Inset shaft with upper and lower section - Google Patents

Abstract

The present invention relates to an insertion chute (1) of the separate type. An upper chute portion (3) of such an insertion chute is made at least essentially independent of the chute discharge valve (7) and its operation by directly or indirectly attaching not only the chute discharge valve but also a valve operating means (9) exclusively to the lower chute portion. Accordingly, the invention offers flexibility both with regard to the upper, normally visible chute portion and to the lower chute portion that is normally hidden and that may be called upon to serve as an expanded temporary storage space.

Description

l5 20 25 30 521 271 outdoors as in the basement or on the ground floor of a building or a building complex, such as shopping malls, sports halls, etc. With this increased interest in the “separate” type of inlet shaft and the expanded area of use has followed a need for greater ibil flexibility as regards the general design of the upper shaft part as well as specifically with respect to the length of the lower shaft part. In the case of the upper shaft part, the required flexibility refers to both the aesthetic appearance of the visible part of the shaft and its practical design. In the latter case, for example, it may be a question of providing opportunities to have a number of inlet openings for receiving different fractions and still maintain a relatively narrow or slim design. The flexibility of the lower shaft part mainly refers to the possibility of varying the storage capacity of the shaft, but also affects the possibility of modifying the length of the lower shaft part. This may be required to properly connect the shaft to a transport line laid at a specific depth in the ground.

The prior art solutions do not take into account such considerations as the aesthetic appearance or the varying need for storage capacity. In fact, the basic design solution for these prior art shafts makes it completely impossible to provide such flexibility. Due to the placement of the valve actuator on the upper shaft part, this will thus inevitably become relatively bulky.

In the case of the lower shaft part, an extension thereof will quickly require an unacceptably long transfer between the actuator on the upper shaft part and the shaft valve which must be placed at the free end of the lower shaft part.

Consequently, there is a need in this area for an inlet shaft of the separate type, which has an increased flexibility both in terms of an upper shaft part thereof and a lower shaft part thereof.

SUMMARY The invention eliminates the above problems in an efficient and satisfactory manner.

A general object of the invention is to provide a solution to the problem of providing a high degree of flexibility for a separate type inlet shaft. More specifically, it is an object of the invention to provide an insertion shaft which offers such flexibility both in terms of an upper, normally visible shaft part and a lower shaft part which is normally hidden and which can be used as an expander! temporary storage space.

Briefly, the above object is achieved by making the upper shaft part at least substantially independent of the shaft valve and its operation. More specifically, this is achieved by directly or indirectly fitting not only the shaft valve but also the valve actuator exclusively to the lower shaft part. Accordingly, the invention provides an insertion shaft where the upper shaft portion can be designed to be completely independent of any limitation or reservation relating to the shaft valve and its operation. At the same time, the length of the lower shaft part and consequently its storage capacity can be varied within reasonable limits without the need for any unacceptable modification of either the actuator or the shaft valve.

In an embodiment of the invention, the valve actuator controls the shaft valve via a transmission which is likewise supported exclusively by the lower shaft part. As a result, the transfer does not have to be affected by any variation in the length of the lower shaft part. Thus, in applications where the length of the lower shaft portion is modified, it will be optional whether the length of the transmission changes accordingly or whether the actuator fl is surface.

In another embodiment of the invention, the valve actuator is located in a suction transport environment. This means that no special sealing arrangements will need to be made for the actuator or - where applicable - for the transmission, thereby reducing the total manufacturing costs.

In a further embodiment, the actuator is a hydraulic cylinder which is connected to the valve via a link system which serves as a transmission. In accordance with the invention, the link system is designed so that a piston rod of the hydraulic cylinder is in a retracted position when the shaft valve is closed. This greatly reduces the risk that waste transported in the pipeline will interfere with the work of the valve actuator. 10 20 25 30 521 271 4 According to a further embodiment, the valve is operated by an electric motor which is connected to the valve via a gear unit. This gives a very compact valve arrangement which adds even more flexibility to the lower shaft part.

In accordance with yet another embodiment of the invention, at least one air inlet duct is arranged in connection with a central waste supply duct, said air supply duct (s) serving to supply air substantially at atmospheric pressure during an emptying phase of the shaft. Such an extra supply of air in the area of the emptying valve will increase the ibil feasibility of the upper shaft part by ensuring appropriate emptying of the total waste even in a case where increased amounts of waste or waste of various kinds must be handled. As an example, this allows a design of the upper shaft part so that it has a number of inlet openings for different waste fractions.

The air inlet duct (s) are preferably arranged at the outer circumference of the lower shaft part, so that it (they) at least partially surround the latter, and it (they) communicate with the air outside the upper shaft part through an interface unit between the upper and lower the shaft parts and with the branch. Thereby, it / they will be connected to the pressure below atmospheric pressure in the waste transport line by operating the emptying valve. With such a presently preferred design of the extra air supply, the dimensions of the lower shaft part can be maintained relatively compact.

In yet another embodiment of the invention, the basic design of the shaft is such that the lower shaft portion is releasably connected to the branch, for the purpose of allowing removal of this lower shaft portion therefrom for inspection, maintenance and repair. In a further embodiment, however, the serviceability is further improved by providing an access or access opening which allows inspection of and / or access to the interior of the branch and thus at least to the valve actuator and the transmission. The inspection / access opening is suitably located in an interface unit which joins the upper and lower shaft parts as well as the branch and is provided with a removable lid which in the closed state provides a gas-tight seal of the opening.

Furthermore, a protective interface section with an openable door can be provided, in particular in cases where the upper shaft part does not enclose the access opening and its lid. 10 15 20 25 30 521 271 This protective interface section prevents rain, sand and dirt from entering the boundary of the recirculation and the interface unit. The openable lid allows access preferably lockable to prevent tampering or vandalism.

Another object of the invention is to provide an improved method for increasing the flexibility in the design or construction of waste collection shafts of the separate type.

These and other objects of the invention are achieved by means of the invention as set forth in the appended claims.

Advantages achieved by the present invention, in addition to those described above, will be apparent upon reading the following detailed description of embodiments of the invention.

BRIEF DESCRIPTION OF THE DRAWINGS The invention, together with further objects and advantages thereof, will be most apparent by reference to the following description taken in conjunction with the accompanying drawings, in which: Fig. 1 is a highly schematic illustration of a pressurized waste transport system of the invention; general type in which the invention may be practiced; Fig. 2A is a partially sectioned side view of a first embodiment of the insertion shaft according to the invention; Fig. 2B is a view similar to that of Fig. 2A, but with parts of a mounting bracket removed to expose a transmission link system; F ig. Fig. 2C is a view similar to that of Fig. 2A illustrating a shaft valve for the intake shaft, in its closed position; Fig. 3A-C illustrates details of the interface unit between the upper and lower shaft parts Fig. 4A Fig. 413 Fig. 4C Fig. 5 Fig. 6A Fig. 613 Fig. 6C Fig. VA-B as well as the branch, at the insertion shaft illustrated in fi g. 2A; is a partial side view of the upper parts of the branch and of the lower shaft part, illustrating a protective interface section of the interface unit for the inlet shaft illustrated in fi g. 2A; is a top plan view of the interface unit illustrated in fi g. 4A; illustrates an alternative embodiment of the protective interface section in a view corresponding to that in fi g. 4A; is a partially sectioned side view illustrating the valve and valve actuator at a second embodiment of the intake shaft of the invention; illustrates a third embodiment of the insertion shaft according to the invention, in a view corresponding to that in fi g. 2A; is a partial view of the lower shaft portion of the insertion shaft illustrated in fi g. 6A, seen from the right side in fi g. 6A; is an end view from above of the lower shaft part, at the third embodiment according to fi g. 6A; and illustrates a superstructure attached at the branch to the insertion shaft according to the invention.

DETAILED DESCRIPTION OF EMBODIMENTS Referring primarily to fi g. 1 and 2A-2C, the basic principles of the insertion shaft according to the invention will now be described by means of a first embodiment illustrated in these urer gures. At the same time, the differences compared to conventional inlet shafts of the separate type will be explained. Fig. 1 is a schematic illustration of a vacuum-collecting waste collection system 20 of the general type where the separate inlet shafts 1, 1 ”according to the invention can be used to advantage. Such a system 20 may comprise both the separate type of throw-in shaft 1, 1 ”according to the present invention and the type of throw-in shaft 26 for your floors illustrated in the upper-floor building 21, such as a residential building, a hospital or an office. The latter Shaft 26 normally extends through all floors of the building 21 and has a closable inlet opening 27 on each floor, through which waste can be introduced. It is further provided with an air inlet 30 adjacent the upper end thereof. At its lower end, the shaft is connected to an underground transport line 2 via an emptying valve 28. Waste introduced into the transport line 2 by opening the emptying valve 28 is transported by means of negative pressure through the transport line 2 and into a container 24 which is normally arranged in a collection center 23 which also contains the necessary equipment 25 for generating the negative pressure, for filtering the air, etc. The filtered air is finally discharged through an air outlet 29. Conventionally, the collected waste is transported from the center 23 by means of special vehicles which are not illustrated.

In one and the same system 20, separate inlet shafts 1, 1 ”can be connected to the same transport line 2 as the discussed fl upper shafts 26 or to separate branches thereof, are not illustrated. These separate insertion shafts can be used in different applications, two of which are illustrated in fi g. 1, namely as a free-standing shaft 1, 1 "located outdoors and also connected to the underground transport line 2, and as a similarly free-standing shaft 1 ', 1" placed, for example, on the ground floor of a larger public building complex 22, such as a shopping center, a sports hall etc. In the illustrated example, a branch 2 'of the transport line in this case is located in the basement of the building complex 22, this branch having a separate air inlet which is generally denoted by 31. In this case the separate inlet shafts 1, 1' extend through the ground floor floor F and directly connected to the branch 2 'in the basement, so that no excavation work will be required for this.

Fig. 1 also illustrates that the separate insertion shafts may be "stripped", the shaft 1 ', or designed, the shaft 1, for aesthetic or other reasons.

A first embodiment of the separate insertion shaft 1 according to the invention will now be described with particular reference to fi g. 3A, 2B and 2C, which contain detailed views of parts of an inlet shaft 1 for use in the type of waste collection system 20 illustrated in Figs. The inlet shaft 1 basically consists of an upper shaft part 3 or 103, see further below, and a lower shaft part 4 which are connected to each other by an interface unit 8. The upper part 3 or 103 of the inlet shaft 1 has only been sketched in Fig. 2A, and in fact, the design of details thereof does not form part of this invention other than indirectly. More specifically, as a result of the invention, the upper shaft part 3, 103 can be designed very freely, and optionally in view of its aesthetic appearance and / or mainly for practical reasons, such as with a number of inlet openings 5, only one is shown, for different waste fractions. Thus, this upper shaft part 3, 103 is shown only with a schematically illustrated inlet opening 5 and a similarly schematic upper waste supply channel SA for connection to a corresponding lower waste supply channel 4A in the lower shaft part 4. To further exemplify this fl flexibility with respect to the design obtained by utilizing the invention, two alternative designs 3 and 3, respectively, are sketched. 103 of the upper shaft part in Fig. 2A. In the first example 3 the upper shaft part is designed very narrow or slender so that it in fact only covers a part of the interface unit 8 and exposes an inspection hatch 50. In the second example the upper shaft part 103 has a wider design which covers the entire interface unit 8 .

The upper 3, 103 and lower 4 shaft parts, and in particular their respective waste feed channels 5A and 4A are interconnected by an interface unit 8 which will be described in more detail below, in connection with fi g. 3A-C and 4A-C. In particular, the connection between the supply channels 5A, 4A comprises a joint 8A, such as a flange-type joint, between the resp. the waste feed channels 5A and 4A and optionally an fl uidum-tight seal (not illustrated). When mounted, the intake shaft 1 is located with an upper end 4B of the lower shaft portion 4 and the interface unit 8 located just above the ground level G, or alternatively, the level of the floor F in the embodiment at the building complex 22 according to Fig. 1.

The lower shaft part 4 is received in a branch 6 of a transport line 2, the branch 6 extending substantially perpendicular to the line 2. In the illustrated embodiment, the branch 6 has a generally rectangular upper end 6B (see fi g. 3A ) which is wider than the diameter of the transport line 2. More specifically, the lower shaft part 4 is releasably connected to the branch 6, see further below, at the upper end 4B thereof, so that the lower shaft part 4 is in fact surrounded by the branch 6. At the opposite lower end 4C thereof, the lower shaft part 4 is provided with a shaft emptying valve 7. This valve 7 is of the conventional valve type with a pivotable valve 7A which in a closed position CP, see fi g. 2C, engages a valve seat 7B at the lower end 4C of the lower shaft portion 4 and sealingly closes this lower end. The movement of the valve 7 between its open and closed positions OP resp. CP is regulated by means of an actuator 9 via a transmission 10.

The lower shaft part 4 has a smaller cross section than the branch 6 and is eccentrically placed in the branch, so that space is provided for mounting the drain valve 7 as well as the actuator 9 therefor and the transfer 10. The drain valve 7, the actuator 9 therefor and the transfer 10 are all boom exclusively of the lower shaft part 4.

In the illustrated embodiment, more specifically, they are all articulated on a fastening or mounting assembly 11 which is attached to the outside of the lower shaft part 4.

The mounting assembly 11 is preferably mounted to the lower shaft portion by means of screws or bolts 11A to thereby allow easy removal of the valve and its actuators as a unit. Within the scope of the invention, however, the mounting assembly ll could likewise be welded to the lower shaft part 4. More specifically, the mounting assembly 11 consists of a mounting plate 11B which articulatedly supports the actuator 9 and a mounting bracket or bracket consisting of two separate plates 11C and 11C and II. fi g. 6B, which articulated supports the transmission 10.

All the moving parts of the valve as well as of the valve actuator 9 and the transmission 10, i.e. the means for regulating the movement of the valve, are thus located in the space between the branch 6 and the lower shaft part 4. Consequently, they are all located in the waste transport environment with negative pressure, i.e. pressure below atmospheric pressure. No specific sealed bushings are required for the transfer of movement between any of the moving parts, and this not only reduces the costs but also increases the flexibility of the upper as well as the lower shaft parts 3, 103 resp. In other words, both of these can be designed optimally for their resp. purpose, without having to consider any sealing problems or other problems related to the control or regulation of the valve operation.

In the illustrated embodiment, the actuator 9 is an outer cylinder which is hingedly supported at its rear end. The transmission 10 is a link system that is best seen in fi g. 2B where one of the plates 11C, 11B of the bracket, namely the plate 11C, has been removed. The link system 10 consists of a first angled link 10A which at one of its ends is connected to a piston rod 9A of the outer cylinder 9 and which at the opposite end is connected to a second, straight link 10B. The first link 10A is rotatably supported in the plates 11C, 11D of the bracket at a position between its ends. At its other end, the second link 10B is rotatably connected to one end of a third link 11C which at its other end carries the valve flap 7A and which is rotatably supported in the plates 11C, 11D of the bracket at a position between its ends. With the illustrated design of the link system 10, the advantageous effect is achieved that the piston rod 9A of the outer cylinder 9 is only extended during the short time for emptying the associated shaft 1, i.e. when the valve 7 is open in the manner illustrated in frg. 2A and 2B. In other words, the piston rod is retracted into the cylinder and thereby protected from the probably harmful waste transport environment in the transport line 2 during all other phases of the system cycles, namely when the valve 7 is closed as illustrated in Fig. 2C.

Details of the interface unit 8 between the upper 3 and lower 4 shaft parts will now be described with particular reference to fi g. 3A-C and 4A-B. As mentioned above, the purpose of the interface unit 8 is mainly to provide a sealed, releasable connection between the upper and lower shaft parts 3, 103 and 4 and between the lower shaft part and the branch 6. These releasable connections are arranged in order to allow removal of said upper shaft part 3 from the lower shaft part 4 and to allow lifting of the lower shaft part 4 from the branch 6. More specifically, with reference to fi g. 3A-B and also to fi g. 7A-B, the upper end 6B of the branch 6 is provided with an upper cover plate 42 which is hermetically connected to a part of the branch which is exposed to the waste transport environment in the transport line 2. This part of the branch 6 is particularly emphasized in fi g. 3B by means of the thick dashed line RCE which marks the contours of this seen from above. The remaining part of the branch 6, seen from above, consists of a superstructure 40, see Figs. 7A-B, which is attached to the branch 6 and which forms a space 40A which is open to the interface unit and which thus settles at atmospheric pressure. This superstructure 40 and its purpose will be described in more detail below in connection with Figs. 7A-B. The upper cover plate 42 is provided with an opening 42A through which the lower shaft part 4 is inserted into the branch 6. A seal 43 (illustrated in Fig. 3A but removed in fi g. 3B) surrounds the opening 42A to provide a gas-tight seal between the cover plate 42 and a mounting fl end 44 disposed at the upper end 4B of the lower shaft portion 4, see fi g. 3C. 10 l5 20 25 30 ll The mounting end 44 is fixed to the upper cover plate 42 by means of releasable fastening means, such as the bolts 47 indicated in fi g. 3C. Furthermore, an access opening 45 is provided in the mounting end 44, in an area thereof which in the mounted condition is located substantially vertically above the valve actuator 9, in order to make it possible to access it. A cover 46 is releasably attached to the mounting end 44 by means of fasteners such as the illustrated bolts 48. When fitted to the mounting end 44, the cover 46 completely seals the access opening with respect to the waste transport environment within the branch 6. When removed, on the other hand, it provides possibility of access at least to the valve actuator 9 for less complicated maintenance and repair work from a place above the lower shaft part 4 and the branch 6.

I fi g. 4A and 4B illustrate a protective interface section 49 which covers the upper plate 42 of the branch and the mounting end 44 with its access opening 45 and the cover 46 thereof, i.e. the lower interface parts. The purpose of this interface section 49 is to prevent water, sand and dirt from penetrating into the area of the lower interface parts and into the space 40A of the superstructure 40 at atmospheric pressure. Thus, it is not required that the interface section 49 form any hermetic or gas tight seal either with the lower interface portions or with the branch. In fact, it may be attached to the upper end of the branch 6 in any suitable releasable manner, such as bolted or clamped. The protective interface section 49 consists of a stationary part 51 and an openable door 50 which is rotatably mounted on the interface section 49 by means of hinges 50A, so that it can be pivoted to an open position (illustrated by dash-dotted lines in fi g. 4A). This provides access to the access opening 45 and its lid 46, as well as to the space 40A with its later described control equipment box 41 and to a detachable coupling unit 38 for fl leads and electrical leads 39, 39 ”, all of which will be described in more detail below in connection with fi g. 7A and 7B. Instead of the illustrated door 50 which can be opened by twisting, another type of completely removable door can be provided. The door 50 is suitably provided with a locking means (not illustrated) which in its simplest form may be a padlock and which protects the inner parts of the interface unit 8 from tampering, in particular in combination with the narrower embodiment of the upper shaft part 3 which does not cover the area of the access opening 45. 10 15 20 25 30 521 271 12 I fi g. 4C illustrates an alternative embodiment of the upper protective interface section 49 'which is here formed in one piece with the upper shaft part 3' and which is rotatably mounted at the branch 6 by means of hinges 50A °. The entire unit consisting of the upper shaft part 3 'and the protective interface section 49' can thus be pivoted to the side in the manner illustrated by dash-dotted lines in fi g. 4C. The door 50 'is here attached by means of a kind of snap connection, so that it lifts slightly at an edge and is then pulled out, as is also indicated in fi g. 4C. The upper and lower shaft parts 3 'resp. 4 can be simply pushed together because they are not required to form a particularly tight or sealed connection. The main requirement is that such a connection should not form any edges on which waste can accumulate. Of course, the unit consisting of the upper shaft part 3 'and the protective interface section 49' can also in this case be designed without the hinge 50A 'so that it is simply lifted off the branch 6 when the associated fastening means have been loosened.

I fi g. 5 illustrates an alternative embodiment of the valve actuator. Here, a highly schematically illustrated electric motor 109 is used for operating the valve 7 between its open OP and closed CP positions. Advantageously, the motor 109 in this case is located immediately adjacent to a joint 112 on which the valve flap is supported for its oscillation between said positions OP, CP. In a presently preferred embodiment, the valve flap would be fixed to the link 112 which in turn would be pivoted in a bearing, not illustrated, by the electric motor 109 via a transmission 110 consisting of a similarly very schematically illustrated gear 110.

In the embodiment of the insertion shaft 1 according to the invention illustrated in fi g. 6A, 6B and 6C, the lower shaft portion 204 comprises a number of air inlet ducts 15, 16 in addition to the waste feed duct 204A. Here, the lower shaft portion 204 includes two air inlet ducts 15, 16 (see fi g. 6B) disposed on the outer periphery of the lower shaft portion 204, spaced apart from each other around its circumference and each partially surrounding the waste feed channel 204A. More specifically, the inlet ducts 15, 16 are located on each side of the valve actuator 9 and its transmission 10. This location is chosen mainly in order to minimize the additional space required for the ducts 15, 16 in the branch 6. The air inlet ducts 15, 16 extends from the upper 204B to the lower 204C end of the lower shaft portion 204 and serves to supply air at atmospheric pressure to the area of the drain valve 7. More specifically, air is taken at atmospheric pressure from inside the upper shaft portion 3, 103 (see Figs. 2A) through channel openings 15A, 16A in the interface unit 8.

The channels 15, 16 open inside the waste feed channel 204A in the lower shaft part 204, at the lower end 204C thereof immediately upstream of the emptying valve 7. In this way the air inlet channels 15, 16 communicate with the branch 6 and thereby with the suction transport line 2 through the valve 7, more specifically, the supply of air at atmospheric pressure to the branch 6 and thus to the transport line 2 is regulated by the discharge valve 7.

In other words, the supply of extra lu fi is coordinated with the opening of the valve 7 for emptying waste which has been collected in the shaft 1. Such a supply of extra lu fl during an emptying phase of the shaft has proven to be advantageous to ensure efficient emptying of the collected waste. Empty in a case where increased amounts of waste of various kinds have to be handled. Although two air inlet ducts 15, 16 are provided in the example, it should be emphasized that the number of ducts can be varied according to what is suitable for different applications, from one and upwards. Likewise, the positions of the channels 15, 16 can be varied in a suitable manner.

The inlet shaft 1 is preferably provided with a space 40A for receiving control equipment for regulating the work of the emptying valve 7. Figures 7A-B thus illustrate an embodiment of an inlet shaft 1 according to the invention which comprises a superstructure 40 which receives a box or box 41 which contains control equipment in a space 40A which is open at the upper part and which is at atmospheric pressure. The superstructure 40 and the space 40A formed therein have been made particularly clear by means of thick dashed lines in Figs. 7A and 7B. The superstructure 40 is part of the branch 6 and is more precisely formed by a partition wall 6D of the branch - the shape of the partition wall 6D is clearly indicated in Fig. 3B and it specifically forms the space required for receiving the actuator 9, the transmission 10 and the valve 7 outer walls 6C, 6E and 6F of the branch and a bottom plate 37. The bottom plate 7 is formed by an upper portion and a lower portion which are connected by means of an inclined portion, as illustrated in Fig. 7B. The purpose of this is mainly to provide a smooth and soft bend for supply or supply lines 33, 34 which are inserted into the space through the lower part of the bottom plate, which will be described below. The bottom plate 37 closes the space 40A downwards and should be watertight to prevent groundwater from entering the space 40A through the lower portion of the bottom plate, which is exposed to the surrounding ground G.

The above-mentioned control equipment is not specifically illustrated in the drawings but usually comprises valves for supplying and discharging fluid, normal compressed air, to resp. from the actuator 9 for the emptying valve 7. Furthermore, the equipment comprises a simple control system for regulating opening and closing of the valve 7 during an emptying phase as well as for determining the interval between such emptying phases for the shaft 1 in the system. Details of such control equipment have been omitted from this description and from the drawings as they do not in themselves form part of the invention.

The emptying phases can be performed based on the time elapsed since the previous emptying phase or based on a sensed waste level in shaft 1. Control signals can also be supplied through wires (not shown specifically) in the protective pipes 32 for electric supply lines 33 as well as for fl discharges 34 which are often placed along the transport line. 2. Said pipe 32 contains the electric supply lines 33 for supplying, for example, electric limit switches (not shown) which are normally used to regulate the stroke of the valve 7, and fluid supply lines 34 for supplying compressed air to the actuator 9.

The tubes 32 for the measurement are laid down along the transport line 2 and enter the branch 6 through the above-described lower portion of the bottom plate 37, adjacent a side thereof, as indicated by 6A. In this lower part of the bottom plate 37 are arranged releasable couplings or an individual bushing 36 for each pipe 32. Electrical supply lines 33 as well as id uid supply lines 34 located in the pipes 32 are extended from the releasable couplings 36 and into the space 40A where they connect to the control equipment box 41. The internal connections to the control equipment in the box 41 are not illustrated as they are specific to each application and are also made in the manner known to those skilled in the art. The supply and supply lines 33, 34 enter the electronic equipment box 41 through an individual, sealed bushing or by means of likewise sealed connections generally designated by the reference numeral 35. Fluid discharge lines and electrical control lines, both generally indicated by the reference numeral 39, from the control equipment thereafter. The box 41 in a similarly sealed manner to provide fl uid to the cylinder 9 resp. to supply the limit switches.

With the above-described shape of the partition wall 6D, the control equipment space 40A is in practice divided into two main compartments, one for receiving the control equipment box 41 and the other for connecting the protective tubes 32. Between these two main compartments a narrow connection is formed in which the supply and supply lines 33, 34 are extended from the couplings 36 to the box 41. This is best seen in ñg. 3B.

An easily accessible and detachable coupling must be provided somewhere in the discharge lines and the electrical lines to allow removal of the lower shaft part 4 from the branch 6 for service and repair purposes. In the embodiment according to Figs. 7A-B where the body 40 is attached to the branch 6, according to the invention a specific solution is provided which consists of a detachable coupling or connection unit 38 which is schematically illustrated in said drawings. This connection unit 38 is used to cause the conduits 39 to releasably bridge the joint between the separable upper mounting end 44 of the lower shaft part and the upper cover plate 42 of the branch 6. The fluid outlet conduits and the electrical control conduits 39 exiting the drawer 41 more precisely pass through the open top. side of the space 40A, see especially ñg. 3A, and are releasably connected to the connection unit 38. Continuation lines 39 ”of said fl outlet lines and electrical control lines 39 are in turn also releasably connected to the opposite side of the connection or connection unit 38.

From there they are passed through the mounting shaft part 4 of the lower shaft part 4 and down to the cylinder 9 resp. to the limit switches. It will now be appreciated that by detaching the fluid outlet lines and the electrical control lines 39 from their continuation lines 39 'at the connection unit 38, the lower shaft part 34 is free to be removed from the branch 6 once the relevant fastening means have been loosened. By placing the connection unit 38 in the manner described, below the removable or openable cover 50, it will be easy to perform such disconnection. Although a separate connection unit 38 has been discussed above, it should be emphasized that the essential thing is to provide an easily accessible and easily releasable connection in the fl outlets and the electrical wires between the control box and the actuator. Thus, the invention is not limited to the use of such a specific connection unit, but encompasses the use of any other type of suitable. releasable couplings or connections arranged in the fluid lines resp. the electrical wires, so that they are easily accessible from above and functionally provide a detachable bridge between the branch and the lower shaft part.

With the above-described design of the superstructure 40 and its space 40A for receiving control equipment, these are received exclusively in the branch. Thus, the flexibility with respect to the design of the upper shaft part is further improved by separating from the upper shaft part not only the valve with its actuators and the transmission, but also the control equipment therefor.

The valve actuator 9 as well as the transmission 10 and the valve 7 have been illustrated and described herein in practical embodiments where they are all indirectly supported by the lower shaft part 4 through the mounting assembly 11. It should be emphasized, however, that the invention is not limited to such a specific assembly thereof. It is within the scope of the invention to arrange the valve actuator 9, the transmission 10 and the valve 7 separately, directly at the lower shaft part.

The above description of the insertion shaft according to the invention has referred exclusively to applications in the type of collection system which comprises a relatively large number of insertion shafts which are collected by means of transport lines and branches thereof in a central collection station. Such systems are often called "stationary vacuum systems". It should be emphasized, however, that the throw-in shaft according to the invention can likewise be incorporated in so-called "Mobile vacuum systems" where one or a small number of shafts are directly connected to a storage tank which is emptied by means of a "vacuum vehicle".

It will be appreciated by those skilled in the art that various modifications and changes may be made in the present invention without departing from the scope thereof, which is defined by the appended claims.

Claims (15)

10 15 20 25 30 521 271 i? PATENT REQUIREMENTS Inlet shaft (1) for connection to a suction transport line (2) in a waste transport system (20) and comprising separate upper and lower shaft parts (3; 103; 3 ', 4; 204) which are operably connected to each other via an interface unit (8), the upper part (3; 103; 3 ') of the shaft having at least one inlet opening (5), and the lower part (4; 204) of the shaft having a valve (7) supported therefrom for regulating the connection between the inlet shaft (1) and the suction transport line, the valve being connected to a valve actuator (9; 109) and the lower shaft part (4; 204) being at least partially received in and surrounded by a branch (6) extending from the suction transport line, whereby the valve is located in a waste transport environment inside the branch, characterized in that the valve actuator (9; 109) is likewise located in the waste transport environment inside the branch (6) and is directly or indirectly supported exclusively by the lower shaft part (4; 204). Inlet shaft (1) according to claim 1, characterized in that the valve (7) is connected to the valve actuator (9; 109) via a transmission (10; 110) which is likewise supported exclusively by the lower shaft part (4; 204) . Inlet shaft (1) according to claim 2, wherein the valve upper member (9) is an outer cylinder which, via the transmission (10), operates the valve (7) between an open (OP) and a closed (CP) position, characterized in that the outer cylinder (9) are connected to the valve (7) via a link system (10) consisting of links (10A, 10B, 10C) which are so rotatably connected to each other that in the closed position (CP) of the valve (7) a piston rod (9A) is located of the id uid cylinder in a retracted position. Inlet shaft (1) according to claim 3, characterized in that the valve actuator (9) is an electric motor (109) which operates the valve (7) between an open (OP) and a closed (CP) position via a transmission (10) which consists of a gear (110). Inlet shaft (1) according to one or more of Claims 1 to 4, characterized in that the lower shaft part (204) comprises, in addition to a waste feed channel (204A), at least one lu fi inlet channel (15, 16). 10 15 20 25 30 521 271 IS ” Inlet shaft (1) according to claim 5, characterized in that the air inlet duct or ducts (15, 16) partially surround the waste feed duct (204A). Inlet shaft (1) according to claim 5 or 6, characterized in that the air inlet duct or ducts (15, 16) at one end thereof open into the upper shaft part (3; 103; 3 ') via the interface unit (8) and at another end thereof opens into the waste feed channel (204A). Inlet shaft (1) according to claim 7, characterized in that the air inlet duct (s) (15, 16) are connected to the suction transport line (2) and in that this connection is likewise regulated by the valve (7). Inlet shaft (1) according to one or more of Claims 1 to 8, characterized in that the lower shaft part (4; 204) is releasably connected to the branch (6) in order to allow the lower shaft part to be intercepted from the branch. Inlet shaft (1) according to one or more of Claims 1 to 9, characterized in that the interface unit (8) is provided with an access opening (45) which allows inspection of and / or access of the actuator (9; 109) from a location. above the lower shaft portion (4; 204). Inlet shaft (1) according to one or more of Claims 1 to 10, characterized in that a removable cover (46) is provided for closing and gas-tight sealing the access opening (45). Inlet shaft (1) according to claim 10 or 11, characterized in that the interface unit (8) comprises a protective section (49; 49 ') which covers an upper end of the branch (6) and which is provided with a removable or alternatively openable door. (50; 50 ') covering the access opening (45). Inlet shaft (1) according to claim 12, characterized in that the protective section (49 ') covering an upper end of the branch (6) is formed in one piece with the upper shaft part (3') and is rotatably or alternatively removably attached at an upper end (6B) of the branch (6). 10 521 271 l? Inlet shaft (1) according to one or more of Claims 1-3 and 5-13, characterized by a mounting assembly (1 1) arranged at the lower shaft part (4; 204) is supported by the valve actuator (9), the transmission ( 10) and the valve (7) located at a lower end (4C; 204C) of the lower shaft portion (4; 204). Inlet shaft (1) according to one or more of Claims 1 to 14, characterized in that the branch (6) comprises a superstructure (40) forming a space (40A) which is open to the interface unit (8) and which houses a control equipment box. (41) for regulating the operation of the drain valve (7).