Title of Invention

PRINTER WITH A MEDIA UNIT WHICH CAN BE REMOVED THEREFROM AND WHICH IS LOCKABLE

Abstract A printer (1), in particular a printer (1) of a tachograph for a motor vehicle, having a housing (2), a printing unit (4), having a media unit (26) to hold the medium that can be printed, which media unit (26) can be moved relative to the printing unit (4) along an insertion curve describing an insertion direction (11) into an operating position and, counter to the insertion direction (11), out of an operating position, which media unit (26) can be at least partly removed from the housing (2), which media unit (26) can be locked in an operating position in the housing (2) by means of a locking unit (17), which locking unit (17) has at least one movable locking element (50) which can be moved into a locked position and into an unlocked position, the locking element (50) in the locked position engaging with at least one retaining element which is fixed to the housing (2), characterized in that the locking element (50) can be moved translationally transversely with respect to the insertion direction (11) into a locked position and into an unlocked position.
Full Text Description
PRINTER WITH A MEDIA UNIT WHICH CAN BE REMOVED THEREFROM AND
WHICH IS LOCKABLE
The invention relates to a printer, in particular the printer
of a tachograph for a motor vehicle, having a housing, a
printing unit, having a media unit to hold a medium that can be
printed, which media unit can be moved relative to the printing
unit along an insertion curve describing an insertion direction
into an operating position and, counter to the insertion
direction, out of an operating position, which media unit can
be at least partly removed from the housing, which media unit
can be locked in an operating position in the housing by means
of a locking unit, which locking unit has at least one movable
locking element which can be moved into a locked position and
into an unlocked position, the locking element in the locked
position engaging with at least one retaining element which is
fixed to the housing.
The focus of the application of the device according to the
invention is in the area of tachographs or devices for
registering the working times and rest times of commercial
vehicle drivers. However, other applications are likewise
conceivable, for example in the area of banking and finance.
Because of the legal verification function of the working time
data registered by means of the tachograph, this data must be
documented in an unchanging way in a forgery-proof format. The
statutory standard provides for the data to be printed out by
means of a printer on specific, forgery-proof paper, in order
to develop a legal evidential character. Therefore, the quality
and the functional reliability

of the printer of a tachograph will have strict measures
applied to them. In order to meet these high requirements, in
view of the operating conditions of these devices, which are to
some extent extreme, the development faces a very great
challenge. The rough operating conditions are distinguished by
extreme temperature fluctuations between -40°C and 80°C and, at
the same time, high atmospheric humidity, as well as high
vibration and shock stresses. In addition, generic devices are
mounted in different installation positions, so that, with
regard to the dynamic mechanical stresses, they must be able to
withstand the loadings in virtually all spatial directions
without the availability of the device being impaired. The
rough operating conditions are additionally intensified by
regularly less careful operation of the device. At the same
time, the usual standards with regard to operating convenience
have to be taken into account, for example changing the media
under the rather adverse conditions in the driver's cab of a
motor vehicle must not degenerate into fiddly manual work. In
addition, the only little overall space available makes it more
difficult to implement a secure function and convenient
operation with ruggedness at the same time.
DP 102 15 122.9 has already disclosed a tachograph having a
box-shaped housing and a generic printing device, in which the
media unit can be removed from the housing for the purpose of
reloading and can be fixed and locked in the housing by means
of lock elements which interact with latching links. It is
proposed to mount the lock element such that it can be rotated
and to provide it with a latching hook which is assigned to a
fixed-location latching link. Under the dynamic mechanical
stresses already outlined, however, it has been shown

that such a latching hook unlocks automatically in an unplanned
manner, so that the media unit, which is formed in the manner
of a drawer, unintentionally moves out of the housing of the
tachograph. In this solution, the implementation is carried
out in practice with two latching hooks, in each case arranged
on one side of the media unit, the consequence of which is that
from time to time only one latching hook is in engagement with
the corresponding latching link, so that although the media
unit is moved out of the operating position it is displaced, so
that the printed image is impaired in an improper manner. In
addition, the printing quality is subjected to high
fluctuations.
Starting from the disadvantages and problems of the prior art,
the object of the invention is to provide a printer of the type
mentioned at the beginning which, despite the rough operating
conditions, exhibits a low failure rate with a high level of
operating convenience and produces a good printed image.
The achievement of the object according to the invention
provides for the locking element to be capable of movement
translationally transversely with respect to the insertion
direction into a locked position and into an unlocked position.
It has been shown that a translationally movable locking
element provides higher security against shocks than a
rotatably mounted one. According to the invention, by means of
the locking unit, it is not only possible to keep the media
unit, which can be displaced in the manner of a drawer, in the
locked position in the housing but also to stabilize it. With

the effect of.this double function, the locking unit aligns the
media unit more accurately in the operating position. By
contrast, a rotatably mounted latching hook additionally has
the disadvantage

that either particularly large overtravel during locking and
unlocking processes must be provided or extremely high
prestressing forces have to be applied to the latching hook in
the direction of a locked position in order to ensure the
necessary security against shocks. These bracing forces
increase when the printing unit and/or the media unit are
prestressed counter to the insertion direction by means of a
second resilient element and the locking unit must absorb these
forces. Only the translational movement according to the
invention transversely with respect to the insertion direction
of the locking element ensures the necessary security against
shocks.
An advantageous development of the invention provides for the
printer to have two retaining elements arranged with a spacing
from each other which, in the locked position, engage with at
least one locking element. The use of two retaining elements
with a spacing is distinguished by incomparably precise
retention of the media unit in the housing of the printer. In
this way, torques can also be transmitted to the locking unit
and the stabilization of the media unit according to the
invention becomes possible.
Expediently, the direction of the spacing between the two
retaining elements extends at right angles to the direction in
which the locking element or the locking elements can move. In
this way, it is possible for forces occurring on the locking
unit in the insertion direction not to move the locking
element, for example out of the locked position. An
orientation of the direction of the spacing between the
retaining elements or of the force introduction regions

of the forces from the locking elements is particularly
expedient into the retaining elements

arranged in a fixed manner in the housing, and perpendicular to
the insertion direction and, in the case of two guides for the
media unit extending in the insertion direction, a vertical
orientation in relation to the plane described by these two
guides. By means of such an arrangement of the locking unit,
the media unit gains additional positional stability in the
housing, since torques occurring in the housing transversely
with respect to the insertion direction in the plane of the
guides of the media unit can advantageously be absorbed by the
locking unit and transmitted to the housing.
The critical advantage of the translational direction of
movement transversely with respect to the insertion direction
of the locking element of the locking unit resides in the
extremely far-reaching decoupling of the movement of the
locking element from forces acting in the insertion direction.
Here, in addition to the shock loadings occurring during proper
operation, the forces from an ejection spring or another
resilient element forcing the media unit counter to the
insertion direction are primarily of importance. In addition
to the necessary force for the ejection, such a second
resilient element also ensures a secured position of the media
unit in the housing, despite the play of the media unit
required for mobility. In particular in the case of an
operating unit arranged on the front panel of the media unit in
an expedient and space-saving manner and actuating the locking
unit, a high ejection force counter to the insertion direction
is required, since the magnitude of this force must exceed the
finger pressure of the user when actuating the operating
element initiating the ejection.

The locking unit advantageously has a first resilient element,
which prestresses the locking element

into the locked position. This arrangement, which is needed for
shock resistance, can be improved still further according to
the invention in terms of security against shocks since, on
account of the decoupling of the forces of the movement of the
locking unit from forces occurring in the insertion direction,
the restoring force of the first resilient element, even in the
case of operating elements arranged in a space-saving manner on
the front panel of the media unit and initiating the ejection
of the media unit, the operating force can be compensated for
by means of a particularly powerful ejection spring. In
addition, the restoring force from the ejection spring and the
force from the first resilient element of the locking unit are
linearly independent, which opens up new degrees of freedom for
dimensioning.
Additional ruggedness is imparted to the locking unit according
to the invention if the locking unit has a slide-mounted
carriage, which carries at least one locking element and can be
moved into a locked position and into an unlocked position. The
locking element expediently extends substantially perpendicular
to the direction of movement of the carriage.
For an extremely high level of stability, the carriage is
designed to be elongated in the direction of movement, so that
torques can also be transmitted to the sliding surface. In
particular in the case of an elongated design, the carriage
according to the invention is suitable as a carrier for at
least one elongated locking element which extends with its
longitudinal axis perpendicular to the direction of movement of
the carriage. Given an elongated design of the carriage,
torques oriented perpendicular to the longitudinal axis of the

locking element and perpendicular to the direction of movement
of the carriage can be transmitted

from the media unit into the housing by means of the locking
unit.
The transmission of torques oriented in the insertion direction
from the media unit into the housing by means of the locking
unit imparts the optimal stability to the arrangement primarily
when two retaining elements arranged with a spacing from each
other are provided and locking elements corresponding to these
are fitted to the carriage, the direction of the spacing
between the retaining elements expediently being oriented
perpendicular to the direction of movement of the carriage and
perpendicular to the insertion direction.
The transmission of higher supporting moments from the media
unit to the locking unit in the insertion direction and
transversely thereto is possible if the locking elements fixed
to the carriage have at least two contact regions, with which
they bear on the retaining elements in the locked position and
the direction of the spacing between the two contact regions
describes a straight line running substantially perpendicular
to the direction of movement of the carriage.
Further stability in the location of the media unit is achieved
if the carriage of the locking unit is slide-mounted on at
least one sliding plane and the sliding plane extends between
the two contact regions, so that at least one locking element
is arranged on both sides of the sliding mounting of the
carriage.
In relation to the ability to transfer the force components
oriented in any direction from the media unit to the housing,

it is advantageous if the two contact regions are located
substantially

on a single straight line described by a normal to the sliding
plane of the carriage.
Optimal interaction between the locking unit and guides of the
media unit, which can be displaced in the manner of a drawer,
results if the media unit is mounted such that it can be
displaced along the insertion curve in guides, the direction of
the spacing between the two contact regions of the locking unit
extending substantially in the direction of the normal to a
tangential plane described there by the guides.
In order to ensure friction-free latching of the locking
element in the associated retaining element, it is expedient if
the locking element has a cylindrical shape, is elongated and
the cylinder longitudinal axis runs perpendicular to the
direction of movement. In the case of expediently hook-shaped
retaining elements, a locking element designed in this way
slides along the hook profile into the locked position
virtually without friction.
For space-saving reasons, it is expedient if the movable
locking elements on the media unit are constituents fixed to
the media unit. Under the limited overall space conditions, it
has proven to be expedient to provide the operating element
actuating the locking element on the front panel of the media
unit, which necessitates arranging the movable locking elements
on the media unit. In the same way, it is expedient if the
stationary retaining elements are permanently connected to the
housing and interact in a locking manner with the locking
elements on the media unit.

In order to avoid misprints, it is expedient if the movable
parts of the locking unit interact with a sensor which
registers a locked position, in which the media unit or the
carrier and the printing unit are fixed in relation to each
other in the direction of the spacing or, in a corresponding
manner, an unlocked position.
Because of the arrangement according to the invention of
locking elements on a common carriage, one sensor is
advantageously sufficient for registering the state of the
locking unit. As compared with the use of a plurality of
sensors for a plurality of locking elements, this firstly has
the advantage that component costs are saved and secondly the
functional advantage that contradictory status messages cannot
come from the locking unit.
The locking according to the invention gains special
significance in interaction with a printing unit which can be
moved in the housing within a movement play. A design of this
type is able to increase the printing quality if means for
aligning the printing unit in relation to the media unit are
provided, so that the printing unit and the media unit are
aligned with each other when the media unit is inserted in the
insertion direction. The positional inaccuracy in relation to
the printing unit resulting from the movement play of the media
unit is in this way compensated for when it is inserted into
the housing. The movement play of the printing unit in the
housing extends primarily horizontally in the insertion
direction, preferably with an order of magnitude of about 1 mm.
In addition, a horizontal movement play transversely with
respect to the insertion direction and of the same order of
magnitude can be provided. A vertical movement play of about

0.5 mm transversely with respect to the insertion direction is
expedient on account of the special importance for the

printing quality. In interaction with a second resilient
element, which pushes or pulls the printing unit counter to the
insertion direction with a force, so that the force urges the
printing unit against the media unit when the latter is
inserted, so that the printing unit is aligned with the
inserted media unit, the preferred spatial movement play
reliably ensures a reproducible relative position of the media
unit in relation to the printing unit. In a design of the
locking unit having at least two retaining elements, special
security against shocks and positional stability of the media
unit are ensured if the retaining elements are arranged
symmetrically in relation to the second resilient element. A
design of the second resilient element in such a way that it
prestresses the printing unit in the housing against stops
limiting the movement play when the media unit is not in the
operating position reliably prevents uncontrolled, possibly
destructive, movements of the printing unit in the housing in
the absence of the media unit.
In the following text, in order to illustrate the invention, a
specific exemplary embodiment is described in more detail with
reference to/drawings, in which:
fig. 1 shows a printer according to the invention as a
constituent part of a tachograph arranged in a
housing, in a perspective illustration in a view
obliquely from above,
fig. 2 shows the opened housing of the tachograph
illustrated in fig. 1 with the arrangement of the
carrier of the media unit, lateral guidance of the
media unit,

and of the locking unit in a view obliquely from
below,
fig. 3 shows a perspective illustration of a mounting of the
printing unit in a view obliquely from above,
fig. 4 shows a perspective illustration of the media unit
with the holder for a coiled strip, a part of the
locking unit and of the resilient element for
ejecting the media unit from the housing, in a view
obliquely from above,
fig. 5 shows an isolated perspective illustration of the
operating element of the locking unit, of a
transmission slide of the locking unit, of the
carriage of the locking unit, of the locking element
and of a first resilient element, in a view obliquely
from above,
fig. 6 shows a perspective illustration of the carriage of
the locking unit and of a locking element,
fig. 7 shows a perspective illustration of the carriage of
the locking unit with a locking element according to
fig. 6 in an assembly with a printed circuit board,
on which a sensor is arranged,
fig. 8 shows a perspective illustration of a part of the
locking unit fixed to the housing,

fig. 9 shows a perspective illustration of the locking unit
together with the front panel of the media unit,
fig. 10 shows a perspective illustration of the locking unit
on the housing side and the media unit side in an
assembly with the carrier of the media unit and of
the front panel in a view obliquely from below.
In relation to some illustrations, the installed position is
pointed out by means of an arrow O which points upward. The
substantially box-shaped housing 2 illustrated in figure 1 is
used to hold a tachograph 3 comprising a printer 1. The
tachograph is provided with various operating elements 7 and an
LCD display unit 9. Beside the LCD display unit 9 there is the
front panel 12 of the printer 1. Under the front panel 12 and
the LCD display unit 9 there are respectively holding openings
15 for holding a card, not illustrated, comprising a data
storage means. The front panel 12 of the printer 1 is a
constituent part of a media unit 2 6 of the printer 1 and
carries a first operating element 27 for actuating a locking
unit 17 and a second operating element 25 for controlling the
function of the printer 1.
In figure 2, the housing 2 of figure 1 is illustrated in open
form perspectively in a view from below, in the interior of the
housing 2 only a carrier 10 of the media unit 26, having first
guide elements 19a, 19b arranged at the sides, and the media
unit 11 being illustrated. For the purpose of improved
understanding, the electronics of the tachograph 3,

the holding openings 15 for a chip card, second guide elements
20 for guiding the first guide elements 19a, 19b, a transport
unit 8 of the media unit 26, as important components, are not
illustrated. The media unit 2 6 can be moved along the
insertion curve 17 described by the first guide elements 19a,
19b out of the housing 2 and into an operating position along
an insertion direction 11 and counter to this direction. When
the operating position is reached, the locking unit 17 latches
in, holding the media unit 26 in the operating position in the
housing 2.
In figure 3, the floating mounting 90 of the printing unit 4,
not illustrated in the other figures, is illustrated. The
floating mounting 90 comprises a wing-like molding 91
integrally molded on both sides of the printing unit 4, which
is in each case arranged in a recess 92 which is a constituent
part of a carrier element 93a, which also comprises the second
guide elements 20a, 20b corresponding to the first guide
elements 19a, 19b. The carrier elements 93a, 93b are firmly
connected to a retaining element carrier 94 of the locking unit
17, illustrated in figure 8, when they are mounted. In this
case, the carrier elements 93a, 93b are centered on pins 95 on
both sides of the side of the retaining element carrier 94 and
latched by means of latching hooks 96. The moldings 91 arranged
on both sides of the printing unit 4 in each case have a
vertical movement play 97 of about 0.5 mm in the recesses 92 in
the carrier element 93a, 93b, and a horizontal movement play 98
in the insertion direction 11 of about 1 mm. Between the
printing unit 4 and the carrier elements 93a, 93b, in addition
a horizontal movement play of a total of 1 mm transversely with
respect to the insertion

direction is provided. It would be to the advantage of printing
quality if the horizontal movement play in the

insertion direction 11 and transversely thereto were in each
case reduced to about 0.5 mm, but this would increase the
expenditure on fabrication as compared with the movement play
selected. In the same way, it is conceivable with a functional
advantageous to reduce the vertical movement play down to 0.35
mm. In a manner not illustrated, by means of a resilient
element not illustrated, the printing unit 4 is prestressed
counter to the insertion direction 11 in the recess 92 so as to
butt up against the molding 91 of the floating mounting 90, so
that the printing units 4 is always located in a defined
position, even in the absence of the media unit 26.
In figure 4, the media unit 26 is illustrated with its
important components, a transport unit 8, the movable parts of
the locking unit 17, the carrier 10 and a second resilient
element 99 for ejecting the media unit 26. A transport unit 8
of the media unit 26 has a transport roll 100 for the transport
of the paper of a coiled strip, not illustrated but arranged in
the holding space 101 between transport unit 8 and locking unit
17. Arranged on the front side 104 of the transport unit 8 of
the media unit 2 6 are centering elements 102 for holding the
front panel 12 illustrated in figure 1. By means of the first
operating element 27, an operating slide 103 of the locking
unit 17 can be actuated and, in a manner illustrated in figure
5, transports a carriage 106 of the locking unit 17 on the
actuating slide 103 and on the carriage 106 by means of
inclined siding planes 107a, 107b. The media unit 26 is
prestressed in the housing 2, counter to the insertion
direction 11, by means of a second resilient element 99 which
is formed as a spiral spring and which is supported

on the retaining element carrier 94 between a first retaining
element 110a illustrated in figure 8 and a second retaining
element 110b.

On both sides of the transport roll 100, on a common shaft 114
holding the transport roll 100, the transport unit 8 has
alignment guides 115, which interact with corresponding
recesses 116 of the printing unit 4 illustrated as a detail in
figure 3 during a movement of the media unit 2 6 in the
insertion direction 11, aligning the printing unit 4 in
relation to the media unit 26. In the course of this
alignment, the printing unit 4 is moved within the horizontal
(98) and vertical (98) movement play. In this way, a
compensation of the tolerance between the media unit 2 6 and the
printing unit 4 is expediently carried out, which improves the
printing quality decisively. In this case, the carriage 106 is
guided such that it can be displaced on the carrier 10 of the
media unit, slide-mounted along a sliding guide 117. The
sliding guide 117 limits the mobility of the carriage 106 to
just the translational degree of freedom of the locking
movement. In this way, the sliding guide 117 of the carriage
106 is also able to accommodate torques which are input by
means of locking elements 50, 51 fixed to the carriage 106.
From the illustration of figure 5, it is possible to gather
that there is resiliently prestressed mounting of the first
operating element 25 by means of a fourth resilient element
120. In the finally mounted state, the fourth resilient
element 120 interacts in a sealing manner with a collar 121 on
the first operating element 27 and a sealing stop on the front
panel 12, which extends in the peripheral direction of the
first operating element 27 but is not specifically illustrated.
The fourth resilient element 120 is in this case dimensioned
and also prestressed in such a way that the

arrangement comprising collar 121 and sealing stop of the front
panel 12, managing without any additional resilient seal,

meets protection class IP 54, in particular is sealed against
spray.
A first resilient element 13 of the locking unit 17 ensures a
defined position of the locking elements 50, 51 and of the
carriage 106 both in a locked position and an unlocked
position.
Figure 6 reveals the construction of the carriage 106 with
locking elements 50, 51 and a sensor actuating element 130 in a
perspective illustration. The carriage 106 is provided with a
cylindrical hole 122, through which there extends a metal pin
123, likewise cylindrical, which projects on both sides of a
sliding surface 131 of the sliding guide 117 of the carriage
106. The two projecting ends of the pin 123 embody the locking
elements 50, 51.
In the manner illustrated in figure 7, the sensor actuating
element 150 actuates a sensor switch 135, which is arranged on
a common printed circuit board 136 of the device. Within the
context of an inward movement along the insertion direction 11
of the carriage 106, the carriage 106 and, with it, the sensor
actuating area 130, completes a curved (14 0) movement in order
to actuate the sensor switch 135 along the slot-type guides of
the hook profiles of the retaining elements 110a, 110b
illustrated in figure 8, which force this curved movement (140)
on the carriage 106 by means of the guide elements 50, 51. The
actual locking movement of the carriage 106 and of the locking
elements 50, 51 of the hook-like profiles of the retaining
elements 110a, 110b runs perpendicular to

the insertion direction 11, so that the restoring force of the
second resilient element 99

for the ejection of the media unit has no component in the
direction of movement of the locking unit 17. The locking
elements 50, 51 arranged on both sides of the sliding surface
131 of the carriage 106, and therefore the contact regions 145,
146 of the locking elements 50, 51, likewise arranged on both
sides of this sliding surface 171, on the retaining elements
110a, 110b likewise advantageously permit the transmission of
torques oriented transversely with respect to the insertion
direction 11 from the carriage 106, which is mounted so as to
be stable against torques, to the retaining elements 110a, 110b
of the locking unit 17. The second resilient element 99
illustrated in figure 4 is arranged between the retaining
elements 110a, 110b illustrated in figure 8 and symmetrically
with respect to the locking elements 50, 51. This arrangement
is illustrated once more in figure 9 for the purpose of
clarification, in particular leaving out the carrier 10 with
the torque-stable guidance 132 of the carriage 106.
The perspective illustration of figure 10 shows the complete
media unit in an overall view with the retaining element
carrier 94, leaving out the printing unit 4, so that the action
of inserting the media unit 26 along the insertion curve 70 in
the insertion direction 11 is illustrated. Subsequently, not
illustrated, the locking elements 50, 51 move along the
retaining elements 110a, 110b of the locking unit, so that the
media unit 2 6 is retained on the retaining element carrier 94
under the prestress of the second resilient element 108, and
thus in a locked position in the housing.

WE CLAIM:.
1. A printer (1), in particular a printer (1) of a
tachograph for a motor vehicles comprising a housing
(2), a printig unit (4), a media unit (26) to hold the
medium that can be printed) which media unit (26) is
movable relative to the printing unit (4) along an insertion
curve describing an insertion direction (11)
into an operating position and, counter to the
insertion direction (11), out of an operating position,
the media unit (26) being at least partly removable
from the housing (2), and lockabie in an operating
position in the housing (2) by means of a locking unit
(17), the locking unit (17) has at least one movable
locking element (50) movable into a locked position and
into an unlocked position, the locking element (50)
in the lacked position engaging with at least one
retaining element which is fixed to the housing
(2) characterized in that the locking element (50) is
movable transiationally transversely with respect to the
insertion direction (11) into a locked position and into an
unlocked position.

2. The printer as claimed in claim 1, comprising two
retaining elements arranged with a spacing from each
other which, in the locked position, engage with at
least one locking element.
3. The printer as claimed in at least one of the preceding
claims, wherein the locking unit has a first resilient
element, which pushes or pulls the locking element into
the locked position and preatresses it.
4. The printer as claimed in at least one of the preceding
claims, wherein the locking unit (17) has a slide-
mounted carriage, which carries at least one locking
element and can be moved into a locked position and
into an unlocked position.
5. The printer as claimed in at least one of the preceding
claims, wherein at least one locking element is fixed
to the carriage and extends substantially perpendicular
to the direction of movement of the carriage.
6. The printer as claimed in at least one of the preceding
claims, wherein the locking elements fixed to the
carriage have at least two contact regions, with which

they bear on the retaining elements in the locked
posit ion, the direction of the spacing between the two
contact regions describes a straight line running
substantially perpendicular to the direction of movement
of the carriage.
7. The printer as claimed in claim 6, wherein the carriage
is slide-mounted on at least one sliding plane and the
sliding plane extends between the two contact regions
so that at least one locking element is arranged on
both sides of the sliding mounting of the carriage.
8. The printer as claimed in claim 7, wherein the two
contact regions are located substantially on a single
straight line a normal to the sliding plane of the
carriage.
of the carriage.
9. The printer as claimed in claim 6, 7 or 8, wherein the
media unit is so mounted to be displaceable along the
insertion curve in guides, the direction of the spacing
between the two contact regions of the locking unit
extends substantially in the direction of the normal
to the tangential plane described thereby the guides.

10. The printer as claimed in at least one of the preceding
claims, wherein the media unit has an operating front
facing the user, into which an operating element of the
locking unit is integrated, by means of which the lock-
ing unit is movable into a locking position and into
an unlocked position.
11. The printer as claimed in at least one of the preceding
claims, wherein the locking unit has a cylindrical
shape and the cylinder longitudinal axiS runs
perpendicular to the direction of movement.
12. The printer as claimed in at least one of the preceding
claims, wherein the movable locking element (17) on the
media unit (26) is a fixed component part of the media
un i t ( 26 ).
13. The printer as claimed in at least one of the preceding
claims, wherein the stationary retaining element is
permanently connected to the housing (2) and interact
in a locking manner with the locking elements (17) on
the media unit (26).

14. The printer as claimed in at least one of the preceding
claims? wherein the retaining element has at least one
hook-like slotted guide along which the locking
elements (1/) move as they move into the lacked
pasition.
15. The printer as claimed in at least one of the preceding
claims wherein the movable parts of the locking unit
interact with a sensor which registers a locked
position, in which the media unit (26) or the carrier
(lO) and the printing unit (4) are fixed in relation to
each other in the direction of the spacing and/or in the
unlocked position? in which the media unit (26) or the
carrier (10) and the printing unit (4) are not fixed in
relation to one another in the direction of the
spacing.
16. fhe printer as claimed in at least one of the preceding
claims wherein when the media unit (26) is inserted in
the insertion direction (11) the printing unit (4) is
movable in the housing (2) within a movement play?
and wherein means for aligning the printing unit (4)

with the media unit (26) are provided, so that the
printing unit (4) and the media unit (26) are aligned
in relation to each other.
17. The printer as claimed in claim 1 or 16, wherein when
the media unit (26) is inserted in the insertion
direction (11) the printing unit (4) is movable in
the housing (2) in the insertion direction (11) and/or
transversely with respect to the insertion direction
(11) to the extent of a substantilly horizontal
movement play.
18. The printer as claimed in claims 1 or 16, wherein the
the printing unit (4) is transversely movable with
respect to the insertion direction (11) in the
housing (2) to the extent of a substantially vertical
movement play.
19. The printer as claimed in at least one of the preceding
claims and/or as claimed in claim 15, wherein the
horizontal movement play of the printing unit 4 in

the insertion direction (11) and/or transversely with
respect to the insertion direction (11) is in each case
between 0.5 mm and 1.5 mm.
20. The printer as claimed in claim 17, wherein the
vertical movement play of the transport unit (4)
transversely with respect to the insertion direction
(11) is between 0.2 mm and 0.5 mm.
21. The printer as claimed in claim 1 or 16, wherein the
printing unit (4) is mounted in a floating manner in the
housing (2).
22. The printer as claimed in at least one of the preceding
claims, comprising at least one second resilient
element (13), which pushes or pulls the printing unit
(4) counter to the insertion direction (11) with a
force (14), so that the force (14) urges the printing
unit (4) against the media unit (26) when the latter is
inserted.

23. The printeras claimed in claim 22, wherein the locking
unit (17) has at least two retaining elements) which
are arranged symmetrically with respect to the second
resilient element (13).
24. The printer as claimed in claims 1 or 22 wherein the
second resilient element (13) is configured in such a way
that it prestresses the printing unit (4) in the housing
(2) against stops limiting the movement play when the
media unit (26) is not in the operating position, so
that the printing unit (40 is always located in a defined
position in the absence of the media unit (26).
25. The printer as claimed in at least one of the
preceding claims, comprising at least one guide (10)
which has at least two first guide elements (19a, 19b).
which are arranged on the media unit (26), and has two
second guide elements (20a, 20b), which correspond to
the first guide elements (19a, 19b), on the media unit
(26), so that, during a movement in or counter to the
to the insertion direction (11), the media unit (26)
is guided by means of the guide.

26. A tachograph comprising a printer (1) as claimed in
at least one of the preceding claims .

A printer (1), in particular a printer (1) of a tachograph for a motor vehicle,
having a housing (2), a printing unit (4), having a media unit (26) to hold the
medium that can be printed, which media unit (26) can be moved relative to the
printing unit (4) along an insertion curve describing an insertion direction (11)
into an operating position and, counter to the insertion direction (11), out of an
operating position, which media unit (26) can be at least partly removed from
the housing (2), which media unit (26) can be locked in an operating position in
the housing (2) by means of a locking unit (17), which locking unit (17) has at
least one movable locking element (50) which can be moved into a locked
position and into an unlocked position, the locking element (50) in the locked
position engaging with at least one retaining element which is fixed to the
housing (2), characterized in that the locking element (50) can be moved
translationally transversely with respect to the insertion direction (11) into a
locked position and into an unlocked position.

Documents:

2251-KOLNP-2005-ASSIGNMENT.pdf

2251-KOLNP-2005-CORRESPONDENCE 1.1.pdf

2251-kolnp-2005-granted-abstract.pdf

2251-kolnp-2005-granted-claims.pdf

2251-kolnp-2005-granted-correspondence.pdf

2251-kolnp-2005-granted-description (complete).pdf

2251-kolnp-2005-granted-drawings.pdf

2251-kolnp-2005-granted-examination report.pdf

2251-kolnp-2005-granted-form 1.pdf

2251-kolnp-2005-granted-form 18.pdf

2251-kolnp-2005-granted-form 2.pdf

2251-kolnp-2005-granted-form 3.pdf

2251-kolnp-2005-granted-form 5.pdf

2251-kolnp-2005-granted-gpa.pdf

2251-kolnp-2005-granted-others.pdf

2251-kolnp-2005-granted-reply to examination report.pdf

2251-kolnp-2005-granted-specification.pdf

2251-kolnp-2005-granted-translated copy of priority document.pdf


Patent Number 230346
Indian Patent Application Number 2251/KOLNP/2005
PG Journal Number 09/2009
Publication Date 27-Feb-2009
Grant Date 25-Feb-2009
Date of Filing 11-Nov-2005
Name of Patentee SIEMENS AKTIENGESELLSCHAFT
Applicant Address WITTELSBACHERPLATZ 2, 80333 MUNCHEN
Inventors:
# Inventor's Name Inventor's Address
1 THOMAS RIESTER BOZENER STR, 10. 78052 VILLINGEN-SCHWENNINGEN
2 HAUTVAST, HEINZ-JOSEF AN-DER KALBERWED 17, 78086 BRIGACHTAL
3 AXEL HUGLE ALMENDSTR. 9, 78120 FURTWANGEN
PCT International Classification Number 407 F 5/12
PCT International Application Number PCT/EP2004/003541
PCT International Filing date 2004-04-02
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 103 21 233.7 2003-05-12 Germany