Compressed-air generator with adjustable pressure output and/or adjustable air throughput

A compressed-air generator with adjustable pressure output and/or adjustable air throughput has a housing (11) and a fan motor arranged in the housing (11) below the top side (27) thereof. Further provided is an adjustment member which may be adjusted by way of a rotary knob (45) and which is provided for adjustment of the pressure output and/or the air throughput. In the compressed-air generator (8), a protective apparatus (47) at least partially covering the rotary knob (45) is provided, with the rotary knob (45) preferably being arranged on the top side (27) of the housing (11) (FIG. 1).

The invention relates to a compressed-air generator with adjustable 
pressure output and/or adjustable air throughput, having a housing, a fan 
motor arranged in the housing below the top side thereof and an adjustment 
member which may be adjusted by way of a rotary knob and which is provided 
for adjustment of the pressure output and/or the air throughput. 
A compressed-air generator of the type mentioned above is known as a 
product of the Applicant. 
In the known compressed-air generator, there is provided as the adjustment 
member a potentiometer which is part of an electronic circuit serving to 
regulate the speed of the fan motor. The rotary knob is pushed onto the 
actuating shaft of the potentiometer from the outside, this actuating 
shaft projecting laterally out of the housing of the compressed-air 
generator. The speed of the fan motor and thus the power output and/or the 
air throughput of the known compressed-air generator can be adjusted by 
way of the rotary knob. 
It is known to provide a handle on the top side of the housing in order to 
facilitate transport. For cooling of the electronic circuit, some of the 
intake air is fed to the circuit via a bypass and is then guided out of 
the housing through a blow-out opening in the direction of the handle. 
During transport or when using the known compressed-air generator, it 
happens repeatedly that the rotary knob is subjected to stress from 
impact, whether because the housing, together with the rotary knob, is 
knocked unintentionally, for example against a ladder, or because when 
transporting awkward objects on a building lot for example a bucket or a 
plank is knocked against the rotary knob. The rotary knob, which is held 
solely by the shaft of the potentiometer, transmits the impact stress on 
to the potentiometer. In the case of stress in the radial direction this 
results in the potentiometer shaft being bent askew or even broken off. In 
the case of an axial stress of the rotary knob, the force is even passed 
into the potentiometer, which may result in the boards in the interior of 
the potentiometer being bent. 
In all these cases, the potentiometer is irreparably destroyed and the 
known compressed-air generator is no longer operational. The potentiometer 
must be replaced, for which purpose a specialist workshop is generally 
sought. 
Furthermore, a disadvantage in the known compressed-air generator is the 
fact that the air used for cooling the electronic circuit leaves the 
housing in the direction of the handle. The air used for cooling can in 
fact be heated when it passes over the electronic circuit to such an 
extent that the air emerging from the blow-out opening is at a temperature 
unpleasant for people. Since the known compressed-air generator is 
regularly transported while it is also operating, the result is that the 
user burns his hand and drops the housing. In this case too, the laterally 
projecting rotary knob can be subjected to forces great enough to result 
in destruction of the potentiometer. 
The invention is thus based on the object of further developing a 
compressed-air generator of the type mentioned at the outset such that the 
danger of damaging the adjustment member is reduced. 
This object is achieved, in accordance with the invention, in that a 
protective apparatus at least partially covering the rotary knob is 
provided, with the rotary knob preferably being arranged on the top side 
of the housing. 
The object on which the invention is based is completely achieved in this 
manner. Because, in the case of the novel compressed-air generator, the 
rotary knob is arranged on the top side of the housing, the danger of 
knocking for example against a wall or a ladder laterally with the rotary 
knob is eliminated. Because of the protective apparatus at least partially 
covering the rotary knob, the danger of knocking against the rotary knob 
by means of an object carried past the compressed-air generator is also 
considerably reduced. As a rule, the impact will be against the protective 
apparatus. On the other hand, since the protective apparatus only covers 
the rotary knob partially, the latter is always accessible to the user. 
In a preferred embodiment of the inventive compressed-air generator, the 
protective apparatus includes a protective sleeve which largely covers the 
rotary knob in the region of its peripheral surface and which is connected 
to the housing with form fit. 
This measure has the advantage that the stress from impact or being knocked 
taken up by the protective sleeve is passed into the housing without 
stressing the rotary knob and thus the adjustment member. Since the 
protective sleeve largely covers the peripheral surface of the rotary 
knob, it is not possible for relatively large objects such as a bucket or 
a lath to knock against the rotary knob. 
In the case of the novel compressed-air generator, it is also preferable 
for the protective sleeve to be open towards the top and to project 
upwards above the rotary knob in the direction of the longitudinal axis 
thereof such that the protective sleeve extends to above the top side of 
the rotary knob. 
This measure has the advantage that even if the housing or the protective 
sleeve is knocked from above, the rotary knob cannot be hit since the 
protective sleeve projects above it. 
Moreover, it is preferable if the protective apparatus has a holding means, 
frictionally engaged therewith, for the 
This measure has the advantage that even forceful knocks which displace the 
protective apparatus with respect to the housing do not result in stress 
on the adjustment member since the latter moves with the holding means and 
thus with the protective apparatus. 
In a preferred embodiment of the novel compressed-air generator, the 
protective sleeve is formed as a hollow cylinder and has a continuous wall 
in which there is provided an upwardly widening V-shaped cutout through 
which a section of the peripheral surface of the rotary knob is accessible 
from the outside. 
As a result of this measure, the rotary knob is protected over the majority 
of its peripheral surface even against impacts with pointed objects such 
as a screwdriver. The peripheral surface of the rotary knob can be grasped 
through the cutout provided in the wall of the protective sleeve and the 
rotary knob can thus be adjusted. 
In this example embodiment, it is preferable if the peripheral surface of 
the rotary knob is fluted and if the V-shaped cutout extends at its upper 
section over an angular region of less than 130.degree., related to the 
longitudinal axis, and at its lower section over a correspondingly 
dimensioned angular region of less than 100.degree.. 
This measure provides the advantage that, as a result of the fluting, only 
a small region of the peripheral surface has to be accessible in order to 
be able to turn the rotary knob. Thus, the cutout can be provided in a 
small angular region, which considerably increases the protective action 
of the protective sleeve against knocks from all sides. 
In a further embodiment of the novel compressed-air generator, a handle is 
provided on the top side of the housing between the front side thereof and 
the rear side thereof, with the protective sleeve being arranged in the 
region of the front side and the cutout being aligned in the longitudinal 
direction of the housing and pointing towards the handle. 
This measure has the advantage that when transporting the novel 
compressed-air generator the region of the rotary knob exposed behind the 
cutout is covered by the hand of the carrier and thus protected. This 
means that it is no longer possible to exert a force on the rotary knob 
from one side only. What might be called an "all-around" protection is 
achieved. 
Furthermore, it is preferable if the adjustment member is cooled by way of 
an air stream for which at least one blow-out opening pointing laterally 
away from the handle is provided on the housing. 
This measure advantageously prevents the carrier from burning his hand when 
transporting the operating compressed-air generator and thus dropping the 
compressed-air generator. This means that the housing can no longer fall 
and thus by unhappy chance hit a projecting edge such that the rotary knob 
is subjected to stress despite the protective apparatus. 
Furthermore, it is preferable if the protective sleeve and the holding 
means for the adjustment member are made in one piece from a 
shock-resistant material. 
This measure has the advantage that even in the case of forceful knocks 
against the protective sleeve the latter is not destroyed. On the other 
hand, this stress results in the protective sleeve and the holding means 
moving together with respect to the housing so that no force is exerted on 
the adjustment member itself. 
A further embodiment is distinguished by the fact that the rotary knob is 
provided with a circular cross section and that the protective sleeve has 
an internal diameter only slightly larger than the rotary knob as regards 
its external diameter. 
These measures advantageously have the effect that when pressure is exerted 
on the region of the peripheral surface of the rotary knob accessible 
through the cutout in the protective sleeve the rotary knob bears against 
the inner wall of the protective sleeve. Since the internal diameter of 
the protective sleeve is only slightly larger than the external diameter 
of the rotary knob, it is not possible to subject the rotary knob to such 
a stress that forces are passed into the adjustment member. The rotary 
knob is closely surrounded by the protective sleeve around its peripheral 
surface to such a degree that there is hardly any play in the radial 
direction. In this manner, the rotary knob and thus the adjustment member 
are completely protected against lateral knocks. 
Further advantages emerge from the description and the accompanying 
drawing. 
It will be appreciated that the features mentioned above and those still to 
be described below are not merely usable in the respectively indicated 
combinations but also in other combinations or in isolation without 
departing from the scope of the present invention.

In FIG. 1, a compressed-air generator is designated 8 and in the example 
shown is a motor fan 10. The motor fan 10 has a two-part housing 11, a 
handle 12 and an electrical connecting cable 13. The housing 11, which may 
for example be of plastics material, includes a housing shell 14, on the 
right in FIG. 1, and a housing shell 15, on the left in FIG. 1. The 
housing shells 14 and 15 are placed one on the other by means of their 
open sides and receive between them, in their cylindrical housing cavity 
16 which is thus formed, a fan motor which is not shown in more detail. 
The fan motor is provided with electrical energy via the connecting cable 
13. 
Provided on the housing 11 is an L-shaped bracket 17 whereof the upper arm 
18 extends above the housing cavity 16, while the lower arm 19 thereof is 
arranged against the housing cavity 16 such that it lies against the end 
side 20 thereof. The upper arm 18 is narrowed approximately in the middle 
to form a web 22, with a free space 21 being provided between the web 22 
and the housing cavity 16. In this manner, a hand is to grasp completely 
around the web 22, which forms the handle 12. 
At its lower end remote from the upper arm 18 the front arm 19 merges with 
feet 23/1. The housing cavity 16 carries at its rear end remote from its 
end side 20 further feet 23/2 which are at the same height as the feet 
23/1. 
The two housing shells 14 and 15 are connected to one another by a snap-on 
mechanism (not shown), two screws 24 and four further screws (also not 
shown). For insertion of a carrying strap (also not illustrated), there 
serve two pins 25 which are respectively arranged in an elongate recess 26 
and provided on the two housing shells 14 and 15 in the region of their 
top side 27. The screws 24 hold the housing shells 14 and 15 together at 
their lower side 28. The top side 27 and the lower side 28 of the housing 
shells 14 and 15, needless to say, correspond to the top side and the 
lower side respectively of the motor fan 10 and are accordingly provided 
with the same reference numerals. 
Of the two elongate recesses 26, one is respectively provided on the 
right-hand housing shell 14 and one on the left-hand housing shell 15. 
Seen in the longitudinal direction 29 of the motor fan 10, the recesses 
26, which run transversely to the longitudinal direction 29, are remote 
from one another in such a way that the recess 26/1 provided on the 
left-hand housing shell 15 is arranged in the region of the end side 20 
while the recess 26/2 provided on the right-hand housing shell 14 is 
arranged on the motor fan 10 such that it extends in the region of its 
rear side 30. As can be seen from FIG. 1, the web 22 runs between the 
recesses 26/1 and 26/2, although somewhat more towards the rear recess 
26/2. 
A cover 31, which can be seen more clearly in FIG. 2, and in which an 
annular air inlet slot 32 is provided, is placed on the housing cavity 16 
at the rear side 30. Returning to FIG. 1, it can further be seen that the 
motor fan 10 has on its front side 33 remote from the rear side 30 a 
compressed-air outlet 34 located in the front arm 19, pointing away from 
the end side 20 and in the form of a projecting annular attachment, in the 
opening 35 of which there is an internal thread 36. A compressed-air hose, 
not shown for reasons of clarity, is screwed into the opening 35 in known 
manner. 
As can be seen in particular in the side view of FIG. 5, the connecting 
cable 13 emerges below the web 22 from a rear transverse web 37 of the 
upper arm 18 and points forward. For winding up the connecting cable 13 
projecting into the free space 21, longitudinal grooves 38 are provided on 
the upper arm 18 running around the latter in the longitudinal direction, 
these longitudinal grooves 38 being matched to the diameter of the 
connecting cable 13. In order to keep the connecting cable 13 in the 
wound-up position, a holding clip 39 pointing backwards is provided on the 
transverse web 37 above the longitudinal grooves 38. The wound-up 
connecting cable 13 is clamped into this holding clip 39 so that it is 
held as shown in FIG. 1. 
Two blow-out openings 41 are provided in the upper arm 18 in the region of 
its front section 40, and air which has been fed, for cooling of an 
electronic control circuit (not shown in more detail), via a bypass to 
this control circuit is blown out of the two blow-out openings 41. The 
control circuit serves to regulate the speed of the fan motor in a manner 
known per se. 
In the region of the front section 40, a press switch 42 is provided on the 
top side 27 of the motor fan 10 and serves to switch the motor fan 10 on 
and off. As a protection against sprayed water or the like, a protective 
cap 43 of plastics material is drawn over the press switch 42. A rotary 
knob 45 which is partially surrounded by a protective sleeve 46 which will 
be described in more detail below is arranged behind the press switch 42, 
as seen in the longitudinal direction 29. The protective sleeve 46 serves 
as a protective apparatus 47 for an adjustment member to be actuated via 
the rotary knob 46 and associated with the control circuit. 
As can be seen more clearly from FIG. 2, the press switch 42, the 
protective sleeve 46 and the rotary knob 45 are arranged on a base plate 
48. The base plate 48 is set in a depression 49 which is provided in the 
top side 27 of the right-hand housing shell 14. 
Because the housing 11 comprises two housing shells 14 and 15, each made in 
one piece from plastics material, the upper arm 18, for example in the 
same manner as the housing cavity 16, is composed of two halves. The 
left-hand half arm 18/1 is associated with the left-hand housing shell 15 
and the right-hand half arm 18/2 of the upper arm 18 is associated with 
the right-hand housing shell 14. As can be seen from FIG. 2, the 
depression 49 is provided in the right-hand half arm 18/2. Before assembly 
of the housing 11, the base plate 48 is inserted in the depression 49, 
where it is held on joining of the housing 11 by the front section 40 of 
the left-hand half arm 18/1. After the housing 11 has been screwed 
together, the base plate 48 is thus connected to the housing 11 with form 
fit. 
FIG. 3 illustrates, as seen in the direction of the arrow III in FIG. 1, 
the protective sleeve 46, which is made in one piece with the base plate 
48 from a shock-resistant plastics material. For reasons of clarity, the 
rotary knob 45 has been omitted and the base plate 48 truncated. 
The protective sleeve 46, in the shape of a hollow cylinder, has a wall 51 
extending symmetrically with respect to its longitudinal axis 50 and 
pointing away from the base plate 48 at its end side 52. Provided in the 
wall 51 is a V-shaped cutout 53 which is limited by two oblique end 
surfaces 54 of the wall 51. The V-shaped cutout 53 extends, at its upper 
section 55 remote from the base plate 48, over an angular region 56 of 
approximately 110.degree. with reference to the longitudinal axis 50. At 
its lower section 57 against the base plate 48, the cutout 53 extends over 
a correspondingly dimensioned angular region 58 of approximately 
90.degree.. 
Provided in the base plate 48 is a central bore 59 which passes through the 
bottom 60 thereof in the longitudinal direction 50. A shaft 63 of an 
adjustment member 64 (not shown in further detail) is pushed through the 
opening 59 from below and is screwed to the bottom 60 by a swivel nut 
(also not shown). The opening 59 and the bottom 60 thus serve as a holding 
means 65 for the adjustment member 64. 
The rotary knob 45 is pushed onto the shaft 63 in known manner and secured 
thereto. FIG. 4 shows the rotary knob 45 placed in the protective sleeve 
46. 
It can be seen that the top side 68 of the rotary knob 45 lies below the 
end side 52 of the protective sleeve 46. The rotary knob 45, which is 
knurled on its outer peripheral surface 69, may on the one hand be turned 
from the outside through the V-shaped cutout 53, but on the other hand it 
can only be removed from the protective sleeve 46 in the longitudinal 
direction 50. In the radial direction, the protective sleeve 46 surrounds 
the rotary knob 45 by means of its inner surface 70 to such an extent that 
the rotary knob 45 cannot be moved out of the protective sleeve 45 
laterally. On the other hand, the inner wall 70 bears against the outer 
peripheral surface 69 so closely that it is not possible to tilt the 
rotary knob 45 in the protective sleeve 46. 
As can best be seen from FIG. 5, the rotary knob 45 projects out of the 
protective sleeve 46 slightly in the direction of the handle 12 or of the 
web 22, so that it can be turned by gripping its peripheral surface 69. 
Here, the user's finger bears against the peripheral surface 69 and 
against the oblique end surfaces 54. 
Since the protective sleeve 46 is open to the top, a mark designated 71 in 
FIG. 4 makes it possible to perform a visual check of the adjustment of 
the rotary knob 45 and thus of the adjustment member 64. The adjustment 
member 64 is part of the electronic control circuit mentioned above. By 
turning the rotary knob 45 and thus the shaft 63, the adjustment member 64 
is affected such that the electronic control circuit establishes a desired 
speed of the fan motor. The speed of the fan motor sets the air throughput 
taken in through the air inlet slot 32 and/or the pressure output given 
out at the compressed-air outlet 34.