WO2017076457A1 - Suction head - Google Patents

Abstract

The invention relates to a suction head (10) for suctioning drill cuttings accumulated when introducing a bore into an underlying surface (32), comprising a housing (12) which has a drill receiving area (28) for inserting a drill (30), a suction channel (36) that runs from the drill receiving area (28) to a suction connection (38) for a suction assembly, and a suction hood (60) that is surrounded by a sealing element (56) in a peripheral direction, can be placed on the underlying surface (32) with the interposition of the sealing element (56), and is fluidically connected to the suction channel (36). The aim of the invention is to develop the suction head (10) such that the risk of the suction head (10) detaching from the underlying surface (32) due to pressure fluctuations occurring in the suction channel (36) is reduced. According to the invention, this is achieved in that a non-return valve (72) which opens in the direction of the suction channel (36) is arranged in the flow path between the suction hood (60) and the suction channel (36).

Description

 suction head

The invention relates to a suction head for sucking boring dirt accumulating when a bore is introduced into a substrate, comprising a housing which surrounds a drill receptacle for inserting a drill, a suction channel leading from the drill receptacle to a suction connection for a suction device and a sealing element circumferentially and with the interposition of the sealing element can be applied to the ground suction hood, which is in flow communication with the suction channel.

Such suction heads are from the utility model DE

20 2008 008 561 Ul known. With their help, when drilling a hole in a subsoil accumulating Bohrschmutz, that is, the drilling material and Bohrstaub be sucked. For this purpose, the suction cups have a housing which has a drill receptacle for inserting a drill and a suction channel leading from the drill receptacle to a suction port. To the suction connection, a suction device, such as a vacuum cleaner can be connected. The suction head can be placed against the ground so that the drill bit holder assumes a position at the desired drilling position. The suction head has a suction hood, which is surrounded by a sealing element and is in flow communication with the suction channel and can be applied with the interposition of the sealing element to the substrate. Under the action of a suction flow provided by the suction device, a negative pressure forms within the suction hood, under the action of which the suction head is pressed against the negative pressure. The user therefore does not have to hold the suction head with one hand at the drilling point when introducing the hole, but the suction head adheres under the effect of prevailing in the suction hood vacuum automatically on the ground.

For the adhesion of the suction head to the negative pressure during the introduction of a bore, it is essential that in the suction hood permanently there is a sufficient negative pressure. However, it is not guaranteed in all cases that the suction device connected to the suction connection is interrupted. provides a suction flow, which ensures the necessary for the adhesion of the suction head vacuum. For example, suction devices are known which have a filter which is cleaned from time to time with the aid of a cleaning device, whereby the filter is briefly flowed through with air against the flow direction prevailing during the normal suction operation, so that dirt particles detach from the filter. This can lead to the formation of pressure fluctuations in the suction channel, with the risk that the vacuum prevailing in the suction hood will weaken so much that the suction head will detach from the substrate.

Object of the present invention is therefore to develop a suction head of the type mentioned in such a way that the risk of detachment of the suction head from the ground is reduced due to prevailing in the suction pressure fluctuations.

This object is achieved in a suction head of the generic type according to the invention that in the flow path between the suction hood and the suction channel opening in the direction of the suction check valve is arranged.

If there is a short-term reduction in the suction pressure provided by the suction device in the suction head according to the invention within the suction channel, so that the negative pressure in the suction hood is greater than the negative pressure in the suction channel, the check valve automatically assumes its closed position and thereby interrupts the flow connection to the suction channel. The prevailing in the suction hood vacuum is thereby substantially maintained and it is ensured that the suction head does not detach from the ground. Then, the negative pressure in the suction increases again, so that the negative pressure in the suction is greater than the negative pressure in the suction hood, the check valve automatically assumes its open position and releases the flow connection to the suction hood again. The check valve is designed in an advantageous embodiment of the suction head according to the invention as a diaphragm valve. This allows a particularly compact design.

It is advantageous if the suction channel is in fluid communication with the suction hood via a suction chamber, wherein by means of the check valve, a suction opening is releasable and closable, via which the suction hood is connected to the suction chamber. In such an embodiment, a suction chamber is arranged between the suction hood and the suction, through which passes the flow path from the suction hood to the suction channel. The suction chamber is connected on the one hand to the suction channel and on the other hand to the suction hood. The flow connection from the suction chamber to the suction hood via a suction port, and at the suction port, the check valve is positioned. The provision of the suction chamber has the advantage that Bohrschmutz, which is sucked from the drill receptacle on the suction, not readily to the check valve and can get over this in the suction hood.

The check valve, preferably a diaphragm valve, is advantageously positioned within the suction chamber. The provision of the check valve therefore does not result in a reduction in the interior of the suction hood, and the check valve is protected against mechanical damage that could occur when the vacuum hood is applied to the vacuum.

It is particularly advantageous if the suction chamber is connected to the suction channel via a connecting channel. By providing the connecting channel, the risk is further reduced that at a momentary weakening of the pressure prevailing in the suction channel Bohrschmutz reaches the check valve and the suction port in the suction hood.

It is particularly advantageous if the connecting channel is arranged offset to the suction opening, because this is in the suction chamber a kind Strö- formed mung labyrinth, which further reduces the risk that unintentionally Bohrschmutz from the suction channel in the suction hood.

The connecting channel conveniently projects into the suction chamber so that it does not form a flow obstacle within the suction channel.

As already mentioned, it is ensured by means of the sealing element that forms a negative pressure within the suction hood when it is applied to the ground and sucked. It is advantageous if the sealing element is elastically compressible and protrudes in the unloaded state by at least 3 mm over an edge of the suction hood. A supernatant of at least 5 mm has proven to be particularly advantageous. If, under the effect of the suction flow provided by the suction device, a vacuum is formed in the suction hood, the suction hood is pressed against the ground and the sealing element is compressed so that the volume of the interior of the suction hood is reduced. If, for example, due to a filter cleaning process of the suction device, a reduction of the negative pressure prevailing in the suction channel, the check valve automatically moves from its open position to its closed position. During the transition from the open position to the closed position, the flow connection from the suction channel to the suction hood, which initially still exists for a short time, also results in a slight lowering of the negative pressure prevailing inside the suction hood. Due to the elasticity of the sealing element, this has the consequence that it expands, so that the volume of the interior of the suction hood is slightly increased. This increases the pressure prevailing in the suction hood negative pressure and the transition of the check valve in its closed position is accelerated. The provision of the elastically compressible sealing element, which projects at least 3 mm, in particular at least 5 mm beyond the edge of the suction hood, thus results in a further reduction of the risk of unintentional detachment of the suction hood from the substrate. In an advantageous embodiment of the invention, the suction hood has a ventilation opening which can be selectively released and closed by means of a ventilation valve. By opening the ventilation valve, the suction hood can be ventilated to remove the suction head from the substrate after the drilling process has been completed. The vent valve is conveniently manually operated.

Preferably, the vent valve is designed as a spring-loaded check valve, which automatically assumes its closed position under the action of a return spring and is movable by the user against the action of the return spring in an open position.

It is particularly advantageous if the housing of the suction head has a ventilation chamber which communicates with the surroundings of the housing via at least one inlet opening and with the suction hood via the ventilation opening. From the suction channel, the ventilation chamber is fluidically separated. There is therefore no risk that Bohrschmutz can get from the suction through the vent in the suction hood. The ventilation of the suction hood is rather with external air, which can pass through the at least one inlet opening in the ventilation chamber and from this via the ventilation opening in the suction hood, if the venting valve assumes its open position.

To achieve a particularly compact design of the suction head, it is advantageous if the suction channel has two channel arms, between which the ventilation chamber is arranged. For example, a first channel arm may extend along a first side of the breather chamber, and a second channel arm may extend along a second side of the breather chamber, with the two sides conveniently facing one another.

It is advantageous if the ventilation chamber is designed substantially triangular in relation to a plan view. As mentioned above, a suction device can be connected to the suction connection. Conveniently, the suction port is designed in the form of a suction, at the free end of a suction line of the suction device is connected, for example, a suction hose. The suction line is in flow communication with a suction unit of the suction device, so that a suction flow is formed under the action of the suction unit in the suction line and the suction channel. The suction line connected to the suction nozzle exerts a tilting moment on the suction head due to its weight. In order to prevent the suction head from detaching from the substrate under the effect of the tilting moment, it is advantageous if the sealing element surrounding the suction hood in the circumferential direction has a rectilinear sealing element section aligned transversely to a longitudinal axis of the suction nozzle below the suction nozzle. The rectilinear sealing element section forms a support, which counteracts detachment of the suction head from the substrate due to the tilting element exerted by the suction line.

In an advantageous embodiment, the housing of the suction head on an upper housing part and a lower housing part, which together form the Bohreraufnahme and at least one immediately adjacent to the drill holder input section of the suction channel.

The drill receptacle can be designed in the manner of a passage or channel with a peripheral wall which completely surrounds the drill used in the circumferential direction, but it can also be U-shaped or C-shaped in plan view and form a kind of fork, which the drill in the circumferential direction only incompletely surrounds.

The upper housing part is preferably mechanically connectable to the lower housing part. For example, it can be provided that the upper housing part can be latched or screwed to the lower housing part.

Preferably, the lower housing part forms the suction hood and a receptacle for the sealing element. The suction hood, for example, an inner edge and have an outer edge, which form between them the receptacle for the sealing element.

Preferably, the lower housing part is designed in areas plate-shaped. This facilitates the production of the lower housing part and allows a particularly compact design of the suction head.

In an advantageous embodiment, the lower housing part and the upper housing part together form the ventilation chamber, via which the suction hood can be ventilated if necessary.

In an advantageous embodiment, the ventilation chamber is penetrated by a valve tappet of a ventilation valve. The valve stem expediently immersed in the suction hood and carries within the suction hood a valve plate which closes in the closed position of the ventilation valve extending between the ventilation chamber and the suction hood ventilation opening and moves by means of the valve stem against the action of a return spring in an open position spaced from the ventilation opening can be.

The return spring of the ventilation valve conveniently surrounds the valve stem in the circumferential direction and is supported on the one hand on the lower housing part and on the other hand on the valve lifter or an associated with the valve lifter actuator, such as a printing plate.

In a preferred embodiment of the invention, the suction head has an intermediate part arranged between the upper housing part and the lower housing part, which defines at least one longitudinal section of the suction channel.

The intermediate part may be formed as a hollow body.

It is particularly advantageous if the intermediate part forms two channel arms of the suction channel, between which the ventilation chamber is arranged. As already mentioned, it is advantageous if the flow connection from the suction channel to the suction hood takes place via a suction chamber. It is advantageous if the intermediate part and the lower housing part define the suction chamber. The intermediate part may, for example, a ceiling wall and the lower housing part may form a bottom wall of the suction chamber and side walls of the suction chamber may be formed by the intermediate part and / or the lower housing part.

The suction connection is, as has already been pointed out, suitably designed as an intake. It is advantageous if the upper housing part forms the suction nozzle.

The following description of an advantageous embodiment of the invention is used in conjunction with the drawings for further explanation. Show it :

Figure 1: A perspective view of an advantageous embodiment of a suction head according to the invention;

Figure 2 is a front view of the suction head of Figure 1;

Figure 3 is a sectional view of the suction head along the figure 3-3 in Figure 2;

FIG. 4 shows a sectional view of the suction head according to FIG. 3 during use of the suction head for extracting drilling dirt;

Figure 5 is an enlarged view of detail A of Figure 3;

FIG. 6: an enlarged view of detail B from FIG. 3;

Figure 7 is a sectional view taken along line 7-7 in Figure 3; Figure 8: a perspective view of the suction head in the manner of an exploded view.

In the drawing, an advantageous embodiment of a suction head according to the invention is shown schematically, which is generally occupied by the reference numeral 10. The suction head has a housing 12 which has an upper housing part 14 and a lower housing part 16 and an intermediate part 18 arranged between the upper housing part 14 and the lower housing part 16. The housing 12 has two straight, obliquely aligned longitudinal sides 20, 22, which are connected to one another via an end face 24 and a rear side 26. As can be seen in particular from FIG. 7, the rear side 26 is aligned parallel to the front side 24, although the front side 24 has a shorter extent than the rear side 26.

Adjacent to the front side 24, the housing 12 has a drill receptacle 28, which is formed by the upper housing part 14 and the lower housing part 16 and in the illustrated embodiment forms a circular passage in plan view. During use of the suction head 10, a drill 30 shown in FIG. 4 can be inserted into the drill receptacle 28 for introducing a bore into a substrate 32 shown in FIG.

To the drill receptacle 28 is followed by a lateral opening 34 of the drill receptacle 28 within the housing 12 to a suction 36, which extends from the Bohrerdaufnahme 28 through the housing 12 through to a suction port 38, which configured in the illustrated embodiment as a suction nozzle 40 is. The suction nozzle 40 is formed by the upper housing part 14.

Within the housing 12, the intermediate part 18 connects to the suction nozzle 40, which is designed as a hollow body and a longitudinal portion 41 of the suction channel 36 is formed. This becomes clear in particular from FIG. At a distance from the suction nozzle 40, the intermediate part 18 forms a first Channel arm 42 and a second channel arm 44, which extend in the direction of the drill bit holder 28. Between the two channel arms 42, 44 a ventilation chamber 46 is disposed within the housing 12. To the two channel arms 42, 44, an end portion 48 of the suction channel 36 connects. The end portion 48 extends to the opening 34 of the drill bit holder 28 and is formed jointly by the upper housing part 14 and the lower housing part 16.

With the exception of a region surrounding the drill receiver 28, the housing lower part 16 is substantially plate-shaped and forms a bottom wall 50, from which an inner edge 52 and an outer edge 54 arranged at a distance from the inner edge 52 protrude downward in the direction away from the upper housing part 14. The inner edge 52 and the outer edge 54 form between them a receptacle 55, in which a sealing element in the form of a sealing ring 56 is arranged, which projects beyond the inner edge 52 and the outer edge 54 to the outside. In the unloaded state, as shown in Figure 3, the sealing ring 56 has a projection 58 of at least 3 mm, preferably 5 to 6 mm. The sealing ring 56 is elastically compressible.

The bottom wall 50 forms in combination with the inner edge 52 of a suction hood 60, which can be applied with the interposition of the sealing ring 56 to the substrate 32. This becomes clear from FIG.

The bottom wall 50 has a suction opening 62, via which the suction hood 60 is in fluid communication with a suction chamber 64. The suction chamber 64 is formed by the bottom wall 50 of the lower housing part 16 and by the intermediate part 18. The intermediate part 18 has for this purpose a perpendicular to the bottom wall 50 aligned chamber wall 66, which forms a side wall of the suction chamber 64. A ceiling wall 68 of the suction chamber 64 is also formed by the intermediate part 18. In the ceiling wall 68 opens a connecting channel 70 which extends within the suction chamber 64 and through which the suction chamber 64 is in fluid communication with the suction channel 36. The suction opening 62 can be closed by means of a check valve which, in the illustrated embodiment, is designed as a diaphragm valve 72 and is arranged within the suction chamber 64 on the bottom wall 50. This becomes clear in particular from FIG. The diaphragm valve 72 opens in the direction of the suction channel 36, so that the suction hood 60, after it has been applied to the substrate 32, can be acted upon by the suction opening 62, the suction chamber 64, the connecting channel 70 and the suction channel 36 with negative pressure. In this case, the diaphragm valve 72 automatically assumes its open position. If there is a brief weakening of the negative pressure in the suction channel 36, the diaphragm valve 72 automatically moves into its closed position, in which it interrupts the flow connection between the suction chamber 64 and the suction hood 60.

As already mentioned, the ventilation chamber 46 is arranged between the two channel arms 42, 44 of the intermediate part 18. The ventilation chamber 46 is bounded in the circumferential direction by an essentially triangular annular wall 74 in plan view. This becomes clear from FIG. The annular wall 74 projects upwards from the bottom wall 50 of the housing lower part 16 in the direction of the housing upper part 14. The bottom wall 50 has a ventilation opening 76, which allows a flow connection from the ventilation chamber 46 to the suction hood 60 and which can be closed by a ventilation valve 78.

The ventilation valve 78 has a valve tappet 80, which passes through the ventilation chamber 46 and dips into the suction hood 60 with a lower end section 82. At the lower end portion 82 of the valve stem 80 carries a valve plate 84, by means of which the vent opening 76 is selectively releasable and closable.

At its end facing away from the valve plate 84, the valve tappet 80 carries an actuating element in the form of a pressure plate 86 which, in the closed position of the aeration valve 78 shown in FIGS. passage opening 88 of the housing upper part 14 dips, so that it is accessible to the user from the outside.

The valve stem 80 is surrounded within the ventilation chamber 46 by a return spring 90, which is supported on the one hand on the integrally connected to the valve stem 80 pressure plate 86 and on the other hand on the bottom wall 50. Under the action of the return spring 90, the valve tappet 80 is pushed so far upwards that the valve disk 84 bears against the ventilation opening 76 and closes it. Contrary to the action of the return spring 90, the user can press the valve tappet together with the pressure plate 86 downwards in the direction of the bottom wall 50, so that the valve plate 84 occupies a distance from the ventilation opening 76 and thereby releases it. This becomes clear from FIG.

Laterally adjacent to the passage opening 88, the upper housing part 14 has a plurality of inlet openings 92, via which the ventilation chamber 46 is permanently in fluid communication with the surroundings of the housing 12. Thus, foreign air can flow into the ventilation chamber 46 via the inlet openings 92. If the user actuates the ventilation valve 78, the external air can reach the suction hood 60 via the ventilation opening 76, so that it is ventilated.

For suction of Bohrschmutz can be connected to the suction nozzle 40, a suction line, such as a suction hose 94, as illustrated in Figure 4. The suction hose 94 is in flow communication with a suction unit of a suction device known per se, so that a suction flow can be formed by the suction unit, which extends from the drill receptacle 28 via the suction channel 36 to the suction nozzle 40 and then via the suction hose 94 to the suction unit. The suction hose 94 exerts a tilting moment on the suction head 10. To counteract this tilting moment, a parallel to the back 26 of the housing 12 extending sealing ring portion 96 is configured rectilinear and perpendicular to a longitudinal axis 98 of the suction nozzle 40 aligned. This becomes clear in particular from FIGS. 4 and 8.

To introduce a hole in the substrate 32, the suction head 10 can be positioned on the ground 32. By connecting the suction head 10 to a suction device, a suction flow can be formed in the suction channel 36, as explained above. Since the suction channel 36 is in fluid communication with the suction hood 60 via the suction chamber 64 and the suction opening 62, a negative pressure is formed in the suction hood 60. This has the consequence that the suction head 10 is pressed against the substrate 32, wherein the sealing ring 56 is compressed and the interior of the suction hood 60 is sealed. The suction head 10 is under the action of the negative pressure prevailing in the suction hood 60, automatically held on the ground 32, so that the user has both hands free for introducing a hole in the ground. If it comes within the suction channel 36, for example, due to a filter cleaning in the suction device, a brief reduction in the negative pressure, this has the consequence that the diaphragm valve 72 automatically passes from its open position to its closed position and thereby the flow connection between the suction duct 36 and the suction hood 60 interrupts. This ensures that a short-term reduction of the negative pressure in the suction channel 36 does not result in a corresponding reduction of the negative pressure within the suction hood 60, so that the suction head 10 reliably adheres to the substrate 32 even with brief interruptions of the suction flow. The provision of the diaphragm valve 72 also ensures that no drilling debris can pass from the suction channel 36 into the suction hood 60 when the suction flow is interrupted. The entry of drilling debris into the suction hood 60 is also avoided by the provision of the connecting channel 70 and the suction chamber 64, which form a flow labyrinth in combination of the suction opening 62 and reduce the risk that Bohrschmutz can get into the suction hood 60.

If the user wants to release the suction head from the substrate 32 after a successful drilling operation, he actuates the ventilation valve 78. External air can then flow via the inlet openings 92, the ventilation chamber 46 and the vent opening 76 in the suction hood 60, so that a pressure equalization takes place.

Claims

PATENT APPLICATIONS

Suction head for sucking when drilling a bore into a substrate (32) resulting Bohrschmutz, comprising a housing (12) having a drill receptacle (28) for inserting a drill (30), one of the drill receptacle (28) to a suction port (38) for a suction device leading suction channel (36) and in the circumferential direction of a sealing element (56) surrounded and with the interposition of the sealing element (56) to the substrate (32) can be applied suction hood (60) which with the suction channel (36) is in flow communication, characterized in that in the flow path between the suction hood (60) and the suction channel (36) in the direction of the suction channel (36) opening check valve (72) is arranged.

2. Suction head according to claim 1, characterized in that the check valve is designed as a diaphragm valve (72).

3. Suction head according to claim 1 or 2, characterized in that the suction channel (36) via a suction chamber (64) with the suction hood (60) is in flow communication, by means of the check valve (72) a suction opening (62) is releasable and closable , via which the suction hood (60) is connected to the suction chamber (64).

4. Suction head according to claim 3, characterized in that the check valve (72) in the suction chamber (64) is arranged.

5. Suction head according to claim 3 or 4, characterized in that the

 Suction chamber (64) via a connecting channel (70) with the suction channel (36) is connected.

6. Suction head according to claim 5, characterized in that the connecting channel (70) projects into the suction chamber (64).

7. Suction head according to one of the preceding claims, characterized in that the sealing element (56) is elastically compressible and in the unloaded state by at least 3 mm beyond an edge (52) of the suction hood (60) protrudes.

8. Suction head according to one of the preceding claims, characterized in that the suction hood (60) has a ventilation opening (76) which is selectively releasable and closable by means of a ventilation valve (78).

9. suction head according to claim 8, characterized in that the housing (12) has a ventilation chamber (46) via at least one inlet opening (92) with the environment of the housing (12) and via the ventilation opening (76) with the suction hood ( 60) is in fluid communication.

10. Suction head according to claim 9, characterized in that the suction channel (36) has two channel arms (42, 44), between which the ventilation chamber (46) is arranged.

11. Suction head according to one of the preceding claims, characterized in that the suction port (38) is designed as a suction nozzle (40), at the free end of a suction line (94) can be connected.

12. Suction head according to claim 11, characterized in that the sealing element (56) below the suction nozzle (40) has a rectilinear, transversely to a longitudinal axis (98) of the suction nozzle (40) aligned sealing element portion (96).

13. Suction head according to one of the preceding claims, characterized in that the housing (12) has an upper housing part (14) and a lower housing part (16), which together form the Bohreraufnahme (28).

14. Suction head according to claim 13, characterized in that the upper housing part (14) and the lower housing part (16) together form a to the drill receptacle (28) immediately adjoining end portion (48) of the suction channel (36).

15. Suction head according to claim 13 or 14, characterized in that the lower housing part (16) forms the suction hood (60).

16. Suction head according to claim 13, 14 or 15, characterized in that the housing lower part (16) forms a receptacle (55) for the sealing element (56).

17. Suction head according to one of claims 13 to 16, characterized in that the lower housing part (16) and the upper housing part (14) together form the ventilation chamber (46).

18. Suction head according to one of claims 13 to 17, characterized in that the suction head (10) between the upper housing part (14) and the lower housing part (16) arranged intermediate part (18), which forms at least a longitudinal portion of the suction channel (36) ,

19. Suction head according to claim 18, characterized in that the intermediate part (18) and the lower housing part (16) define the suction chamber (64).

20. Suction head according to one of claims 13 to 19, characterized in that the housing upper part (14) forms the suction nozzle (40).