The present invention relates to an elevator as de-
fined in the preamble of claim 1 and to a method as
defined in the preamble of claim 9 for detecting a de-
viation of a compensating device from a preselected
compensating range in an elevator.
One of the objectives in elevator development work is
to achieve an efficient and economical utilization of
building space. In recent years, this development work
has produced various elevator solutions without ma-
chine room, among other things. Good examples of ele-
vators without machine room are disclosed in specifi-
cations EP 0 631 967 (Al) and EP 0 631 968. The eleva-
tors according to these specifications are fairly ef-
ficient in respect of space utilization as they have
made it possible to eliminate the space needed for the
machine room in the building without a need to enlarge
the elevator shaft. The machine used in the elevators
according to these specifications is compact in at
least one direction, but in other directions it may be
much larger than conventional elevator machines.
In these basically good elevator solutions, the space
and placement of the hoisting machine limits the free-
dom of choice in elevator lay-out solutions. The ar-
rangements for the passage of the hoisting ropes re-
quire space. The space required by the elevator car
itself on its track, and likewise the space needed for
the counterweight, can not be easily reduced, at least
at a reasonable cost and without compromising on the
performance and quality of operation of the elevator.
In a traction sheave elevator without machine room,
installing the hoisting machine in the elevator shaft,
especially in the case of solutions with machine
above, is often difficult because the hoisting machine
is a fairly heavy and large object. Especially in ele-

vators for larger loads, speeds and/or hoisting
heights, the size and, weight of the machine are a
problem in respect of installation, even so much so
that the required machine size and weight have in
practice limited the scope of application of the con-
cept of elevator without machine room, or at least re-
tarded the introduction of said concept in larger ele-
vators. The space available in the elevator shaft in
elevator modernization projects has often limited the
scope of application of the concept of elevator with-
out machine room. Often, especially in cases of mod-
ernization or replacement of hydraulic elevators, it
has not been practical to apply a roped elevator solu-
tion without machine room, due to insufficient space
in the elevator shaft especially in a situation where
no counterweight has been used in the hydraulic eleva-
tor solution to be modernized/replaced. The drawbacks
of elevators provided with a counterweight include the
cost of the counterweight and the space required for
the counterweight in the elevator shaft. Drum-driven
elevators, which at present are quite rare, have the
disadvantages of heavy and complicated hoisting ma-
chines and their high power and/or torque require-
ments . Prior-art elevator solutions without counter-
weight are exotic and no appropriate solutions are
known. So far, it has not been technically or economi-
cally reasonable to make elevators without counter-
weight. One solution like this is disclosed in speci-
fication WO9806655. A recent international patent ap-
plication discloses a feasible solution. In prior-art
elevator solutions without counterweight, the tension-
ing of the hoisting rope is implemented using a weight
or spring, and that is not an. attractive approach to
implementing the tensioning of the hoisting rope. An-
other problem with elevators without counterweight,
when long ropes are used e.g. due to a large hoisting
height or large suspension ratios used, the compensa-

tion of rope elongations and at the same time, due to
rope elongations, the friction between the traction
sheave and the hoisting ropes is insufficient for the
operation of the elevator. A further problem is how to
ensure the compensation of rope elongations and the
operating reliability of the compensating device.
The general aim of the invention is to achieve at
least one the following objectives. On the one hand,
it is an objective of the invention to develop the
elevator without machine room so as to achieve more
efficient space utilization in the building and in the
elevator shaft than before. This means that the eleva-
tor should permit of being installed in a relatively
narrow elevator shaft if necessary. On the other hand,
it is an objective of the invention to control danger-
ously large rope elongation of the hoisting ropes and
to eliminate danger situations caused thereby. Another
objective is to ensure a safe adjustment range and
compensation range for the rope elongation compensat-
ing system and a simple implementation of monitoring
of the condition of the hoisting ropes.
The elevator of the invention is characterized by what
is disclosed in the characterization part of claim 1.
The method of the invention is characterized by what
is disclosed in the characterization part of claim 9.
Other embodiments of the invention are characterized
by what is disclosed in the other claims. Inventive
embodiments are also presented in the description part
of the present application. The inventive content dis-
closed in the application can also be defined in other
ways than is done in the claims below. The inventive
content may also consist of several separate inven-
tions, especially if the invention is considered in the
light of explicit or implicit sub-tasks or in respect
of advantages or sets of advantages achieved. In this

case, some of the attributes contained in the claims
below may be superfluous from the point of view of
separate inventive concepts.
By applying the invention, one or more of the follow-
ing advantages, among others, can be achieved:
- monitoring of the hoisting ropes and compensation
range needed in the compensating device can be eas-
ily implemented because the compensation range of
the compensating device is limited due to its struc-
ture
- by monitoring the compensation range in the compen-
sating device, information regarding deviation from
the preselected compensation range is obtained
quickly and at the same time the danger situation
resulting from the deviation can be detected in time
- safety of the elevator of the invention is better
ensured, especially in the case of an elevator with-
out counterweight
- the elevator can be stopped and its use can be pre-
vented in time due. to a factor which has been caused
by a disturbance or some other corresponding danger
situation detected by the compensating device and
which activates the switching elements of the com-
pensating device,
- monitoring of the condition of the hoisting ropes of
the elevator is easy and simple to implement by ap-
plying the invention

- the elevator control system can be supplied with in-
formation and/or about some other danger situation
that causes activation of the switching elements of
the hoisting rope compensating device
- using the method and elevator of the invention, it
is possible to transmit information regarding devia-
tion from the preselected compensation range even to
a remote elevator monitoring system, and thus to

transmit information regarding the need of mainte-
nance of the elevator
- information regarding the need of maintenance of the
elevator of the invention is obtained quickly, at
least as far as the hoisting ropes and/or compensat-
ing device are concerned
- the invention enables easy and fast detection of
various disturbance situations and danger situations
in the elevator, such as e.g. damaged and blocked
diverting pulleys, disturbances of rope passage in
the elevator, changes in rope lengths, situations
where the elevator car is driven onto the buffer or
the safety gear of the elevator grips and/or other
corresponding disturbance situations
- in addition, by applying the invention, the opera-
tion of the compensating device in the desired man-
ner can be easily ensured.
The primary area of application of the invention is
elevators designed for transporting people and/or
freight. A normal area of application of the invention
is in elevators whose speed range is about or below
1.0 m/s but may also be higher. For example, an eleva-
tor traveling at a speed of 0.6 m/s is easy to imple-
ment according to the invention.
In the elevator of the invention, normal elevator
ropes, such as generally used steel wire ropes, are
applicable. The elevator may use ropes of synthetic
material and rope structures with a synthetic-fiber
load-bearing part, such as e.g. so-called "aramid"
ropes, which have recently been proposed for use in
elevators. Applicable solutions are also steel-
reinforced flat belts, especially because of the small
deflection radius they permit. Particularly advanta-
geously applicable for use in the elevator of the in-
vention are elevator hoisting ropes twisted from e.g.

round and strong wires. Using round wires, the rope
can be twisted in many ways using wires of the same or
different thicknesses. In ropes well applicable with
the invention, the wire thickness is below 0.4 mm on
an average. Well-suited ropes made from strong wires
are those in which the average wire thickness is under
0.3 mm or even under 0.2 mm. For example, thin-wired
and strong 4-mm ropes can be twisted relatively advan-
tageously from wires such that the average wire thick-
ness in the finished ropes is between 0.15 .... 0.25 mm,
in which the thinnest wires may even have a thickness
of only about 0.1 mm. Thin rope wires can be easily
made quite strong. In the invention, rope wires having
a strength greater than about 2000 N/mm2. Appropriate
rope wire strengths are 2300-2700 N/mm2. In principle,
it is possible to use rope wires having a strength of
about 3000 N/mm2 or even more.
In the elevator applying the invention, the elevator
car is suspended on a set of hoisting ropes comprising
one rope or a number of parallel ropes, and the eleva-
tor has a traction sheave which moves the elevator car
by means of the hoisting ropes. The elevator of the
invention comprises rope portions of hoisting ropes
going upwards and downwards from the elevator car. The
elevator also has a compensating device acting on the
hoisting ropes to equalize and/or compensate rope ten-
sion and/or rope elongation. The compensating device
acting on the hoisting ropes of the elevator comprises
at least a first range, which is a structural operat-
ing range, and at least a second range, which is a
preselected compensation range of the compensating de-
vice. In addition, the elevator comprises at least one
switching element for monitoring whether the compen-
sating device remains within the preselected compensa-
tion range.

In the method of the invention for detecting a devia-
tion of a compensating device from a preselected com-
pensating range in an elevator, in which elevator the
elevator car is at least partially suspended on a set
of hoisting ropes comprising one rope or a number of
parallel ropes. The elevator has a traction sheave
which moves the elevator car by means of the hoisting
ropes, and the elevator comprises rope portions of
hoisting ropes going upwards and downwards from the
elevator car. In addition, the elevator has a compen-
sating device acting on the hoisting ropes to equalize
and/or compensate rope tension and/or rope elongation.
In the method, at least one switching element is used
in the compensating device to monitor whether the com-
pensating device of the elevator remains within the
preselected compensation range.
By increasing the contact angle using a rope pulley
functioning as a diverting pulley, the grip between
the traction sheave and the hoisting ropes can be im-
proved. Therefore, a car of lighter weight as well as
smaller size can be used, thus increasing the space-
saving potential of the elevator. A contact angle of
over 180° between the traction sheave and the hoisting
rope is achieved by utilizing a diverting pulley or
diverting pulleys. The need to compensate rope elonga-
tion follows from the friction requirements, in order
to ensure a grip between the hoisting rope and the
traction sheave that is sufficient in respect of op-
eration and safety of the elevator. On the other hand,
in respect of operation and safety of the elevator, it
is essential that the rope below the elevator car of
an elevator without counterweight is held under suffi-
cient tension. This can not necessarily be achieved by
using a spring or a simple lever.

In the following, the invention will be described in
detail with reference to embodiment examples and the
accompanying drawings, wherein
Fig. 1 is a diagram representing a traction sheave
elevator without counterweight according to
the invention,
Fig. 2 is a diagram representing a second traction
sheave elevator without counterweight accord-
ing to the invention and a compensating de-
vice according to the invention, and
Fig. 3 is a diagram representing a third traction
sheave elevator without counterweight accord-
ing to the invention and a compensating de-
vice according to the invention.
Fig. 1 presents a general view of a traction sheave
elevator without counterweight according to the inven-
tion without a switching element in the compensating
system for monitoring rope elongation, in which eleva-
tor the elevator guide rails are arranged on one side
of the elevator car. The elevator is preferably an
elevator without machine room and with a drive machine
4 placed in the elevator shaft. The elevator presented
in the figure is a traction sheave elevator without
counterweight and with machine above, in which the
elevator car 1 moves along guide rails 2. The elevator
presented in Fig. 1 is a side rucksack-type elevator
in which the elevator guide rails 2, hoisting machine
4, diverting pulleys, rope compensating device 15 and
hoisting ropes 3 are arranged on one side of the ele-
vator car l, which in this case is located to the
right of the elevator car 1 as seen from the door
opening towards the elevator shaft. This arrangement
can also be implemented on any side of the elevator
car 1, such as e.g. in the case of a rucksack solution
in the space between the back wall of the elevator car

and the elevator shaft. The elevator can also be im-
plemented by placing the guide rails of the elevator
car and some of the diverting pulleys on different
sides of the elevator car. In Fig. 1, the hoisting
rope compensating device 15, which in the case of Fig.
1 can also be referred to as a tensioning sheave as-
sembly, comprises two wheel-like bodies fitted to each
other, which preferably are sheaves and which in the
situation illustrated in Fig. 1 are secured to the
elevator car 1. Of the wheel-like bodies, the diameter
of the sheave connected to the hoisting rope portion
below the elevator car is larger than the diameter of
the sheave connected to the hoisting rope portion
above the elevator car. The diameter ratio between the
diameters of the sheaves determines the magnitude of
the tensioning force acting on the hoisting rope and
therefore the compensation force needed to compensate
the hoisting rope elongations as well as the length of
the rope elongation compensated by the compensating
device. In this solution, the use of sheaves provides
the advantage that the structure can compensate even
very large rope elongations. By varying the diametric
size of the tensioning sheaves, it is possible to in-
fluence the magnitude of the rope elongation to be
compensated and the ratio between the rope forces act-
ing over the traction sheave, which ratio can be main-
tained at a constant value by the arrangement in ques-
tion. Due to a large suspension ratio or a large
hoisting height, the length of the rope used in the
elevator is large. It is therefore essential for the
operation and safety of the elevator that the hoisting
rope portion below the elevator car be held under a
sufficient tension, and often the amount of rope elon-
gation to be compensated is large. In the case of odd
suspension ratios above and below the elevator car,
the compensating device 15 is fitted in conjunction
with the elevator car, and in the case of even suspen-

sion ratios the compensating device 15 is fitted in
the elevator shaft or in some other appropriate place
not in conjunction with the elevator car. In the solu-
tion it is possible to use two sheaves as illustrated
in Fig. 1 in the compensating device 15, but the num-
ber of wheel-like bodies used may vary; for example,
it is possible to use only one sheave with positions
for hoisting rope fastening points of different diame-
ters fitted on it. It is also possible to use more
than two tensioning sheaves if it is desirable e.g. to
vary the diameter ratio between the sheaves by only
changing the diameter of the tensioning sheaves. In
addition, the compensating device 15 used may also
consist of a different type of compensating device,
such as e.g. a lever, a different compensating sheave
assembly application or some other compensating device
application suited to the purpose.
In Fig. 1, the hoisting ropes run as follows: One end
of the hoisting ropes is secured to the sheave of
smaller diameter in the compensating device 15, which
sheave is immovably fitted fast to the sheave of lar-
ger diameter, to which larger sheave the other end of
the hoisting ropes 3 is secured. This compensating de-
vice 15 has been fitted in place on the elevator car.
From the compensating device 15, the hoisting ropes 3
go upwards and meet a diverting pulley 14 placed above
the elevator car in the elevator shaft, preferably in
the upper part of the elevator shaft, passing around
it along rope grooves provided on the diverting pulley
14. These rope grooves may be coated or uncoated, the
coating used is e.g. a friction-increasing material,
such as polyurethane or some other appropriate mate-
rial. From diverting pulley 14, the ropes go further
downwards to a diverting pulley 13 fitted in place on
the elevator car, and having passed around this pulley
the ropes go further upwards to a diverting pulley 12

fitted in place in the upper part of the elevator
shaft. Having passed around diverting pulley 12, the
ropes come again downwards to a diverting pulley 11
fitted in place on the elevator car, pass around it
and go further upwards to a diverting pulley 10 fitted
in place in the upper part of the elevator shaft, and
having passed around this pulley the hoisting ropes 3
go further downwards to a diverting pulley 9 fitted in
place on the elevator car. Having passed around this
pulley 9, the ropes 3 go further upwards in tangential
contact with diverting pulley 7 to the traction sheave
5. Diverting pulley 7 is preferably fitted near and/or
in conjunction with the hoisting machine 4. Between
diverting pulley 7 and the traction sheave 5, the fig-
ure shows Double Wrap (DW) roping, in which roping the
hoisting ropes 3 go in tangential contact with divert-
ing pulley 7 upwards to diverting pulley 5 and, having
passed around the traction sheave 5, the hoisting
ropes return to diverting pulley 7, pass around it and
go back to the traction sheave 5. In Double Wrap rop-
ing, when diverting pulley 7 is substantially the same
size with the traction sheave 5, diverting pulley 7
may also function as a damping pulley. In this case,
the ropes going from the traction sheave 5 to the ele-
vator car 1 pass via the rope grooves of the diverting
pulley 7 and the deflection of the rope caused by the
diverting pulley is very small. It could be stated
that the ropes going from the traction sheave to the
elevator car and the ropes coming to it only run in
"tangential contact" with the diverting pulley. Such
"tangential contact" functions as a solution damping
vibrations of the outgoing ropes and it can also, be
applied in other roping solutions. An example of other
roping solutions is Single Wrap (SW) roping, wherein
the diverting pulley is substantially of the same size
with the traction sheave and the diverting pulley is
used as a "tangential contact sheave" as described

above. In the SW roping according to the example, the
ropes are passed only once around the traction sheave,
so the contact angle of the rope on the traction
sheave is about 18 0° and the diverting pulley is only
used as an auxiliary sheave for "tangential contact"
of the rope as described above and wherein the divert-
ing pulley functions as a rope guide and a damping
pulley suppressing vibrations. Diverting pulleys
14,13,12,11,10,9,7 together with the traction sheave 5
of the hoisting machine and the compensating device 15
form the suspension above the elevator car, which has
the same suspension ratio as the suspension below the
elevator car, which suspension ratio in Fig. 1 is 7:1.
From the traction sheave 5, the ropes go further in
tangential contact with diverting pulley 7 to a di-
verting pulley 8, which is preferably fitted in place
in the lower part of the elevator shaft. Having passed
around diverting pulley 8, the ropes 3 go further up-
wards to a diverting pulley 16 fitted in place on the
elevator car, and having passed around this pulley the
ropes go further downwards to a diverting pulley 17 in
the lower part of the elevator shaft, pass around it
and return to a diverting pulley 18 fitted in place on
the elevator car. Having passed around diverting pul-
ley 18, the ropes go further downwards to a diverting
pulley 19 in the lower part of the elevator shaft and,
having passed around this pulley, the ropes go further
upwards to a diverting pulley 20 on the elevator car.
Having passed around diverting pulley 20, the hoisting
ropes 3 go further downwards to a diverting pulley 21
fitted in place in the lower part of the elevator
shaft, pass around it and go further upwards to the
compensating device 15 fitted in place on the elevator
car, the second end of the hoisting ropes being se-
cured to the sheave of larger diameter in the compen-
sating device. Diverting pulleys 8,16,17,18,19,20,21
and the compensating device 15 form the hoisting rope

suspension below the elevator car. The hoisting ma-
chine 4 and traction sheave 5 of the elevator and/or
the diverting pulleys 7,10,12,14 in the upper part of
the elevator shaft may be mounted in place on a frame
structure formed by the guide rails 2 or on a beam
structure at the upper end of the elevator shaft or
separately in the elevator shaft or on some other ap-
propriate mounting arrangement. The diverting pulleys
in the lower part of the elevator shaft may be mounted
in place on a frame structure formed by the guide
rails 2 or to a beam structure placed at the lower end
of the elevator shaft or separately in the lower part
of the elevator shaft or on some other appropriate
mounting arrangement. The diverting pulleys on the
elevator car may be mounted in place on the frame
structure of the elevator car 1 or to a beam structure
or beam structures in the elevator car or separately
on the elevator car or some other appropriate mounting
arrangement. The tensioning sheave assembly 15 used as
a rope elongation compensating device as illustrated
in Fig. 1 can also be advantageously placed to replace
diverting pulley 21 on the bottom of the shaft, which
pulley is preferably secured in place to the floor of
the shaft, or diverting pulley 14 in the upper part of
the shaft, which pulley is preferably secured in place
to the ceiling of the shaft if an even suspension ra-
tio is used, in which case the compensating device is
not mounted in conjunction with the elevator car. In
this case, the number of diverting pulleys needed is
smaller by one. In advantageous cases, this also al-
lows easier and faster installation of the elevator.
Fig. 2 presents a diagram illustrating the structure of
an elevator according to the invention. The elevator is
preferably a traction sheave elevator without machine
room and with a drive machine 204 placed in the eleva-
tor shaft. The elevator presented in the figure is a

traction sheave elevator without counterweight and
with machine above, in which the elevator car 201
moves along guide rails 202. In elevators designed for
a large hoisting height, elongation of the hoisting
rope involves a need to compensate the rope elonga-
tion, and this has to be done reliably within certain
allowed limit values. In the rope force equalizing
sheave assembly 224 of the invention presented in Fig.
2, a very long movement for the compensation of rope
elongation is achieved. This allows compensation of
even very large elongations, which is often not possi-
ble if simple lever or spring solutions are used. The
compensating device is also used to ensure safe opera-
tion of the elevator in other situations where the
safety of the elevator is impaired. The operation of
the compensating device is to be monitored to ensure
that it will not be used in an operating range where
the reliability and safety of the elevator would be
impaired. As a compensating device according to the
invention, Fig. 2 presents an arrangement of compen-
sating sheaves that maintains a substantially constant
ratio Ti/T2 between the rope forces Tx and T2 acting
over the traction sheave. The compensating device has
a limited compensating distance due to its structure,
e.g. the fact that the compensating device is guided
by guide rails and the compensating range between
their ends is a range that forms the theoretic limited
operating range of the compensating device, within
which range the compensating device maintains a dif-
ference of tension between T1 and T2 and between dif-
ferent parts of the hoisting ropes. Within this range,
the compensating device works in the desired manner,
but when the extremities of the compensating device
are reached, such as e.g. the fixing point 226 of the
hoisting ropes, the compensating device will not nec-
essarily function in the desired manner and the opera-
tion of the elevator is impaired. Thus, the compensat-

ing device generally has a first range, which is a
structural operating range, and/or a theoretical com-
pensation range, within which the compensating device
functions in a known and desired manner but beyond
which it will not necessarily function in the desired
manner. For this reason, it is desirable to select in
the compensating device a second range which is to be
monitored by means of switching elements and which is
a preselected compensation range of the compensating
device, within which range the compensating device
works in the desired manner. This arrangement is de-
signed to ensure that the compensating device is oper-
ated in a certain range within which the compensating
device works in the desired manner. If necessary, the
preselected compensation range can also be defined as
a range equal to the structural operating range. It is
also possible to have more than one such compensation
range monitored by means of switching elements in the
compensating device. For example, in a situation where
information is to be transmitted to an elevator main-
tenance or remote monitoring system to indicate that
the preselected limit has been exceeded and the eleva-
tor needs maintenance but its operation is not yet im-
paired and the elevator remains in normal use. In ad-
dition to this, the above-mentioned system comprises
at least a second predefined compensation range, which
is larger than the compensation range selected by
means of the switching elements transmitting informa-
tion to the maintenance system, upon activation of the
switching elements of which range the operation of the
elevator is stopped and/or prevented. Fig. 2 also
shows switching elements r1 and r2 comprised in the
compensating device, which elements are used to moni-
tor the position of a compensating sheave 225 or Tp1
in the compensating sheave assembly. By means of the
switching elements, a preselected compensation range
is defined for the compensating device 224. This range

is generally smaller than the theoretical limited op-
erating range, which e.g. in the situation illustrated
in Fig. 2 is limited at its upper end by the upper
ends of the guide rails guiding the compensating de-
vice and at its lower end by a buffer placed at the
fixing point 226 or some other suitable point. The
structural operating range and the preselected compen-
sation range may also be equal if necessary. Fitted in
place on the diverting pulley 225 (Tp1) is a connecting
element 227 designed to engage the switching elements
r1 and r2 to activate them so that they will receive
limit information regarding the position of the com-
pensating sheave Tp1. The switching elements can also
be activated by some other technique applicable to the
purpose. The switching elements are used to indicate
that the compensating device is working outside the
preselected compensation range. In an elevator without
counterweight according to the invention, the condi-
tion of the parallel ropes in the set of hoisting
ropes 203 can be monitored e.g. by means of a compen-
sating device. In the arrangement accordingto the in-
vention as illustrated in Fig. 2, the compensating
sheave assembly 224 used as a rope force compensating
device is provided with switching elements ri,r2, such
as limit switches, fitted to monitor the position of
the diverting pulley 225 (Tp1) . When for some reason
the length of the hoisting ropes 203 has been in-
creased too much, the above-mentioned switching ele-
ments will transmit information to the elevator con-
trol system, which again can e.g. inform the elevator
remote monitoring system that the elevator needs main-
tenance, or the switching element may send information
regarding its activation directly to the remote moni-
toring system. If the elongation of the hoisting rope
increases to a dangerous length, the limit data ob-
tained from the switching elements can stop the eleva-
tor and/or prevent the use of the elevator if desired.

In the elevator and compensating device according to
the invention, it is also possible to use more switch-
ing elements than in the examples in the present ap-
plication; for instance, in the situation illustrated
in Fig. 2, it is possible to use several switching
elements to indicate different preselected compensa-
tion ranges of the compensating device and occurrences
of the device exceeding the range. For example,
switching elements used to indicate a need for mainte-
nance may be fitted to work from a smaller compensa-
tion range than switching elements stopping the eleva-
tor. Situations that cause the compensating device to
move outside the preselected compensation range and/or
to the end of the maximum operating range may include
e.g. various disturbance and danger situations in the
elevator, such as diverting pulleys being damaged or
getting stuck, disturbances of rope passage in the
elevator, changes in rope lengths e.g. due to an ex-
cessive rope elongation, situations where the elevator
is driven onto the buffer or the safety gear grips
and/or other corresponding disturbance situations in
which the compensating device moves outside the prede-
fined compensation range.
In Fig. 2 the hoisting ropes run as follows: One end
of the hoisting ropes 203 is secured to a diverting
pulley 225 fitted to hang on a rope portion coming
downwards from diverting pulley 214. Diverting pulleys
214 and 225 together constitute a rope force equaliz-
ing system 224, which in the case illustrated in Fig.
2 is a compensating sheave assembly. From diverting
pulley 214, the hoisting ropes run further as de-
scribed in connection with the previous figures be-
tween the diverting pulleys 212,210,207 fitted in
place in the upper part of the elevator shaft and the
diverting pulleys 213,211,209 fitted in place on the
elevator car, forming the suspension above the eleva-

tor car. Between the traction sheave 205 of the hoist-
ing machine 204 and diverting pulley 207, X Wrap (XW)
roping is used, in which roping the rope portion of
the hoisting ropes going upwards from the diverting
pulley 207 to the traction sheave 205 and the rope
portion returning from the traction sheave 205 to the
diverting pulley 207 run across each other. Diverting
pulleys 214,213,212,211,210,209,207 together with the
traction sheave 205 of the hoisting machine 204 form
the suspension above the elevator car, which has the
same suspension ratio as the suspension below the ele-
vator car, which suspension ratio in Fig. 2 is 6:1.
Between diverting pulley 207 and the traction sheave
it is also possible to use other types of roping ap-
propriate for the purpose, such as e.g. the known SW,
DW tai ESW roping solutions or some other appropriate
roping solution. From the traction sheave, the hoist-
ing ropes go further via diverting pulley 2 07 to a di-
verting pulley 2 08 placed in the lower part of the
shaft. Having passed around diverting pulley 208, the
hoisting ropes run between the diverting pulleys
218,220,222 fitted in place on the elevator car 201
and the diverting pulleys 219,221,223 fitted in place
in the lower part of the elevator shaft, as described
in connection with the previous figures. From divert-
ing pulley 223, the hoisting ropes 203 go further to
diverting pulley 225, which is comprised in the rope
force equalizing sheave assembly 224 and is fastened
to the second end of the hoisting rope. Having passed
around diverting pulley 225 along its rope grooves,
the rope goes further to the fixing point 226 of the
second end of the hoisting rope, this fixing point be-
ing located in the elevator shaft or in some other
place appropriate for the purpose. Diverting pulleys
208,218,219,220,221,222,223 form the suspension below
the elevator car, in which the suspension ratio is the
same as the suspension ratio of the suspension above

the elevator car, i.e. 6:1 in the situation of Fig. 2.
Diverting pulley 225 may be guided by guide rails to
keep it on its track, especially in situations where
the compensating sheave assembly 224 is subjected to a
hard impact, such as e.g. when the safety gear of the
elevator grips. By means of the guide rails of the
compensating sheave 225, a desired clearance between
the elevator car and the compensating device can be
maintained and the motion of the compensating device
controlled. The guide rails used with the compensating
device may be almost any type of guide rails applica-
ble for the purpose, such as e.g. guide rails made of
metal or some other appropriate material or e.g. guide
ropes.
In the elevator presented in Fig. 2, the compensating
sheave assembly 224 compensates rope elongations by
means of a diverting pulley 225 (Tp1) . The diverting
pulley 225 moves through distance 1, compensating elon-
gations of the hoisting ropes 203. The compensation
distance 1 is half the elongation of the hoisting
ropes. In addition, this arrangement keeps the rope
tension over the traction sheave 2 05 at a constant
level, so that the Tl/T2 ratio between the rope forces
is 2/1. By means of the switching elements r1 and r2, a
compensation range has been preselected for the com-
pensating device, which will work in the desired man-
ner as long as it remains within this range. The
structural operating range of the compensating device
is the maximal distance through which the compensating
sheave assembly 224 can move while maintaining a ten-
sion difference between the rope portions above and
below the elevator car, when the upper end is reached
the compensating device will not compensate the rope
elongation upwards. In the situation illustrated in
Fig. 2, the compensating device moves upwards normally
when the elevator car moves downwards. When the com-

pensating device is in a situation where it no longer
moves upwards compensating the rope elongation, a
situation arises where the rope force T1 of the rope
portion above the elevator car increases while the
rope elongation in the hoisting rope simultaneously
increases. The compensating device can no longer per-
form the compensation function and at the same time
the rope portion below the elevator car becomes slack
and its tension T2 decreases. The compensating device
is not working properly, so the T1/T2 ration does not
remain constant, and consequently the rope portion be-
low the elevator car becomes slack and the tension
acting over the traction sheave changes, which leads
to a loss of friction between the hoisting ropes and
the traction sheave. This situation is dangerous for
the operation of the elevator as the elevator hoisting
rope starts slipping and the elevator car can move
downwards in an uncontrolled manner. After the compen-
sating device has moved to the limit of the second end
of the maximal operating range, in the situation in
Fig. 2 to the fixing point 226 of the hoisting rope, a
situation arises where T2 is increasing and the rope
elongation in the portion below the elevator car is
increasing. As a consequence of this, the rope portion
above the elevator car becomes slack and the rope
force T1 decreases as the compensating device is not
compensating the rope elongations and equalizing the
rope forces. In this situation the elevator hoisting
machine only tries to feed more rope to the rope por-
tion above the elevator car while the tension of the
rope portion below the elevator car is further in-
creased. The compensating sheave assembly 224 used as
a compensating device can also be implemented in other
ways besides that presented in the example, such as by
using more complex suspension arrangements in the rope
force compensating sheave assembly, e.g. different
suspension ratios between the diverting pulleys in the

compensating sheave assembly. Examples of such differ-
ent suspension ratios in the compensating sheave as-
sembly are 3:1, 3:2 or some other appropriate suspen-
sion ratio.
Fig. 3 illustrates the structure of an elevator accord-
ing to the invention. The elevator is preferably an
elevator without machine room and with a drive machine
3 04 placed in the elevator shaft. The elevator pre-
sented in the figure is a traction sheave elevator
without counterweight and with machine above, in which
the elevator car 301 moves along guide rails 302. In
Fig. 3, a compensating sheave assembly 315 as de-
scribed in connection with Fig. 1 is used a compensat-
ing device, which comprises two wheel-like bodies,
preferably sheaves, fixed to each other, which sheave
assembly in the case of Fig. 3 has been fitted in
place on the elevator car 301. In the tensioning
sheave assembly 315 used as a compensating device, the
sheave connected to the hoisting rope portion below
the elevator car has a larger diameter than the sheave
connected to the hoisting rope portion above the ele-
vator car. The diameter ratio between the diameters of
the sheaves in the tensioning sheave assembly deter-
mines the magnitude of the tensioning force acting on
the hoisting rope and the compensation distance needed
to compensate the hoisting rope elongations, as well
as the ratio between T1 and T2. In this solution, the
use of tensioning sheaves provides the advantage that
the structure can compensate even large rope elonga-
tions. By varying the diametric size of the tensioning
sheaves, it is possible to influence the magnitude of
the compensation range and distance and the ratio be-
tween the rope forces T1 and T2 acting over the trac-
tion sheave, which ratio can be maintained at a con-
stant value by the arrangement in question. Due to a
large suspension ratio or a large hoisting height, the

length of the rope used in the elevator is large. It
is therefore essential for the operation and safety of
the elevator that the hoisting rope portion below the
elevator car be held under a sufficient tension and
the amount of rope elongation to be compensated is
sufficiently large. Often this can not be implemented
using a spring or a simple lever. In the case of odd
suspension ratios above and below the elevator car,
the tensioning sheaves are fitted in conjunction with
the elevator car, and in the case of even suspension
ratios the tensioning sheaves are fitted in the eleva-
tor shaft or in some other appropriate place not in
conjunction with the elevator car. In the solution it
is possible to use two sheaves, but the number of
wheel-like bodies used may vary; for example, it is
possible to use only one sheave with positions for
hoisting rope fastening points of different diameters
fitted on it. It is also possible to use more than two
tensioning sheaves if it is desirable e.g. to vary the
diameter ratio between the sheaves by only changing
the diameter of the tensioning sheaves. In addition,
when a tensioning sheave assembly 315 is used as a
compensating device in the elevator of the invention,
it is necessary to monitor the compensating device to
ensure that it remains within the selected compensa-
tion range. The monitoring can be advantageously im-
plemented e.g. as in Fig. 3, where the tensioning
sheave assembly is provided with a switching element
320, which is activated e.g. by means of a bracket 314
provided on the compensating device 315. By shaping
the bracket 314 in a suitable way, it is possible to
monitor both ends of the preselected compensation
range by means of a single switching element in a man-
ner corresponding to that applied in connection with
the compensating device presented in Fig. 2. The safe
compensation range in the tensioning sheave assembly
is normally somewhat less than a full revolution. The

structural operating range depending on the structure
of the tensioning sheave assembly is larger than the
preselected compensation range, which is monitored by
means of at least one switching element to ensure that
the compensating device is functioning in the desired
manner. The bracket 314 can be designed to a size of
e.g. 2 0% to ensure reliable activation of the switch-
ing element 320, and disposed at a suitable point on
the tensioning sheave assembly 315.
In Fig. 3, the hoisting ropes run as follows: One end
of the hoisting ropes is secured to the sheave of
smaller diameter in the tensioning sheave assembly
315. This tensioning sheave assembly 315 has been fit-
ted fast to the elevator car. From the sheave of
smaller diameter, the hoisting ropes 303 go upwards
and meet a diverting pulley 312 placed above the ele-
vator car in the elevator shaft, preferably in the up-
per part of the elevator shaft, passing around it
along rope grooves provided on the diverting pulley
312. These rope grooves may be coated or uncoated, the
coating used may be e.g. a friction-increasing mate-
rial, such as polyurethane or some other appropriate
material. From pulley 312, the ropes go further down-
wards to a diverting pulley 311 on the elevator car,
and having passed around this pulley the ropes go fur-
ther upwards to a diverting pulley 310 fitted in the
upper part of the shaft. Having passed around divert-
ing pulley 310, the ropes come again downwards to a
diverting pulley 3 09 mounted on the elevator car, pass
around it and go further upwards to the traction
sheave 305 of the hoisting machine 304. The roping
presented in Fig. 3 is Single Wrap (SW) roping, in
which no auxiliary diverting pulleys are used. Divert-
ing pulleys 312,311,310,309 together with the traction
sheave of the hoisting machine and the tensioning
sheave assembly 315 constitute the suspension above

the elevator car, wherein the suspension ratio is the
same as in the suspension below the elevator car, this
suspension ratio in Fig. 3 being 5:1. From the trac-
tion sheave 305, the ropes go further to a diverting
pulley 308 preferably fitted in place in the lower
part of the elevator shaft, e.g. on an elevator guide
rail 3 02 or on the shaft floor or in some other appro-
priate place. Having passed around diverting pulley
308, the ropes 303 go further upwards to a diverting
pulley 316 fitted in place on the elevator car, pass
around it and run further downwards to a diverting
pulley 317 in the lower part of the elevator shaft.
Having passed around this pulley, the ropes return to
a diverting pulley 318 fitted in place on the elevator
car. Having passed around diverting pulley 318, the
hoisting ropes 3 03 go further downwards to a diverting
pulley 319 fitted in place in the lower part of the
elevator shaft, and having passed around this divert-
ing pulley the ropes go further upwards to the ten-
sioning sheave assembly 315 fitted in place on the
elevator car, the second end of the hoisting ropes 3 03
being secured to the sheave of larger diameter in the
tensioning sheave assembly.
A preferred embodiment of the elevator of the inven-
tion is an elevator without machine room and with ma-
chine above, in which the drive machine has a coated
traction sheave and which elevator has thin and hard
hoisting ropes of a substantially round cross-section.
In the elevator, the contact angle of the hoisting
ropes on the traction sheave is greater than 180° and
preferably implemented using DW roping in the hoisting
machine. The hoisting machine has a traction sheave
and a diverting pulley, in which hoisting machine the
traction sheave and the diverting pulley are ready
fitted in a correct angle relative to each other. The
hoisting machine is secured to the elevator guide

rails. The elevator is implemented without counter-
weight with a suspension ratio of 8:1 in such a way
that both the suspension ratio in the roping above the
elevator car and the suspension ratio in the roping
below the elevator car is 8:1, and that the ropes of
the elevator run in a space between one wall of the
elevator car and the wall of the elevator shaft. The
elevator has a compensating device, which maintains a
constant ratio between forces T1 / T2 as 2:1. With the
compensating device used, the required compensation
distance equals half the magnitude of the rope elonga-
tion. In addition, the compensating device is provided
with at least one switching element to monitor whether
the device remains within the preselected compensation
range.
Another preferred embodiment of the elevator of the
invention is an elevator without counterweight in
which the suspension ratio above and below the eleva-
tor car is 10:1. This embodiment uses conventional
elevator ropes, which preferably are ropes of a diame-
ter of 8 mm, and a traction sheave made of cast iron
at least in the area of the rope grooves. The traction
sheave has undercut rope grooves and the contact angle
on the traction sheave has been fitted by means of a
diverting pulley to be 180° or greater. When conven-
tional 8-mm ropes are used, the traction sheave pref-
erably has a diameter of 340 mm. The diverting pulleys
used are large rope sheaves which, when conventional
8-mm hoisting ropes are used, have a diameter of 320,
33 0 340 mm or even more.
It is obvious to the person skilled in the art that
different embodiments of the invention are not limited
to the examples described above, but that they may be
varied within the scope of the claims presented below.
For example, the number of times the hoisting ropes

are passed between the upper part of the elevator
shaft and the elevator car and between the diverting
pulleys in the lower part of the elevator shaft and
the elevator car is not a very decisive question as
regards the basic advantages of the invention, al-
though it is possible to achieve some additional ad-
vantages by using multiple rope portions. Embodiments
are generally so implemented that the ropes are passed
to the elevator car as many times from above as from
below, so that the suspension ratios in the suspension
above and below the elevator car are the same. It is
likewise obvious that the hoisting ropes need not nec-
essarily be passed under the car, but that they can as
well be passed e.g. over the car. In accordance with
the examples described above, the skilled person can
vary the embodiment of the invention as the traction
sheaves and rope pulleys, instead of being coated
metal pulleys, may also be uncoated metal pulleys or
uncoated pulleys made of some other material suited to
the purpose.
It is further obvious to the person skilled in the art
that the traction sheaves and rope pulleys made of
metal or some other material appropriate for the pur-
pose which are used as diverting pulleys in the inven-
tion and which are coated with a non-metallic material
at least in the area of their grooves may be imple-
mented using a coating material consisting of e.g.
rubber, polyurethane or some other material suited to
the purpose.
It is obvious to the skilled person that the elevator
of the invention can be implemented using as hoisting
ropes almost any flexible hoisting means, e.g. a
flexible rope of one or more strands, a flat belt, a
cogged belt, a trapezoidal belt or some other type of
belt suited to the purpose. It is obvious to the

skilled person that, instead of using ropes with a
filler, the invention can be implemented using ropes
without a filler, which are either lubricated or unlu-
bricated. In addition, it is also obvious to the
skilled person that the ropes may be twisted in many-
different ways.
It is also obvious to the person skilled in the art
that the elevator of the invention can be implemented
using other types of roping between the traction
sheave and the diverting pulley/diverting pulleys to
increase the contact angle a than the roping arrange-
ments described above as examples. For example, it is
possible to arrange the diverting pulley/diverting
pulleys, traction sheave and hoisting ropes in other
ways than in the roping examples presented. It is fur-
ther obvious to the skilled person that the elevator
of the invention may also be provided with a counter-
weight, in which elevator, for example, the counter-
weight preferably has a weight below that of the car
and is suspended on separate ropes.
Due to the bearing resistance of the rope sheaves used
as diverting pulleys and the friction between the
ropes and the rope sheaves and also to possible losses
occurring in the compensating device, the ratio of the
rope tensions may deviate somewhat from the nominal
ratio of the compensating device. Even a 5-% deviation
is not a significant detriment because the elevator
must in any case have a certain in-built robustness.

WE CLAIM :
1. Counterweight-less elevator, which has an elevator car(1) suspended by
means of a set of hoisting ropes(3) comprising one rope or a plurality of parallel
ropes and which elevator has a traction sheave(4) that moves the elevator car(1) by
means of the hoisting ropes, and which elevator comprises rope portions of hoisting
ropes going upwards and downwards from the elevator car, and which elevator has
a compensating device(15) acting on the hoisting ropes(3) to equalize and/or
compensate rope tension and/or rope elongation, characterized in that the
compensating device(15) acting on the hoisting ropes of the elevator, said
compensating device having at least a first range which is a structural operating
range of the compensating device and at least a second range(r1 - r2) which is a
preselected compensation range of the compensating device, is provided with at
least one switching element(r1, r2) for monitoring whether the compensating device
(15) remains within the preselected compensation range.
2. The elevator as claimed in claim 1, wherein the compensating device is a
lever, a tensioning sheave assembly or a compensating sheave assembly.
3. The elevator as claimed in claim 1, wherein the compensating device is a
tensioning sheave assembly and the switching element is an element detecting
whether the preselected compensation range has been exceeded.
4. The elevator as claimed in claim 1, wherein the compensating device
comprises a compensating sheave(Tp1) and at least a first switching element (r1)
and the second switching element (r2) for monitoring the position of the
compensation sheave (TP1) in the compensating device and detecting a deviation
from the preselected compensation range.

5. The elevator as claimed in claim 4, wherein the compensating device
comprises one and/or more diverting pulleys.
6. The elevator as claimed in any one of the preceding claims, wherein the
compensating device comprises a system that sends information regarding
deviation from the preselected compensation range to a remote monitoring system
and/or prevents the use of the elevator.
7. The elevator as claimed in any one of the preceding claims, wherein the
elevator car is provided with diverting pulleys from which the hoisting ropes go
upwards and diverting pulleys from which the hoisting ropes go downwards, the
number of each type of pulleys being 1, 2, 3, 4, 5, or even more.
8. The elevator as claimed in any one of the preceding claims, wherein the
roping used between the traction sheave and the diverting pulley is double
wrap(DW) roping or x wrap(XW) roping or single wrap(SW) roping that forms a
continuous contact angle of at least 180° between the traction sheave and the
hoisting ropes.
9. A method for detecting a deviation of a compensating device(15) from a
preselected compensation range in a counterweight-less elevator, in which elevator
the elevator car(1) is at least partially suspended by means of a set of hoisting
ropes(3) comprising at least one rope or a plurality of parallel ropes, and which
elevator has a traction sheave(4) that moves the elevator car by means of the
hoisting ropes, and which elevator comprises rope portions of hoisting ropes going
upwards and downwards from the elevator car, and which elevator has a
compensating device(15) acting on the hoisting ropes to equalize and/or
compensate rope tension, characterized in that monitoring is performed in the
compensating device by means of at least one switching element(r1, r2) to detect
whether the compensating device of the elevator remains within the preselected
compensation range(r1 - r2).

10. The method as claimed in any claim 9, wherein, after the switching element
in the compensating device has detected a deviation from the preselected
compensation range, corresponding information is sent to a remote elevator
monitoring system and/or the use of the elevator is prevented in such a situation.

ABSTRACT

COUNTERWEIGHT-LESS ELEVATOR
A counterweight-less elevator and method for detecting a deviation of a
compensating device from a preselected compensation range in a counterweight-
less elevator are disclosed. The counterweight-less elevator, which has an elevator
car(1) suspended by means of a set of hoisting ropes(3) comprising one rope or a
plurality of parallel ropes and which elevator has a traction sheave(4) that moves
the elevator car (1) by means of the hoisting ropes, and which elevator comprises
rope portions of hoisting ropes going upwards and downwards from the elevator
car, and which elevator has a compensating device(4) acting on the hoisting ropes
to equalize and/or compensate rope tension and/or rope elongation, characterized
in that the compensating device(15) acting on the hoisting ropes of the elevator,
said compensating device(15) having at least a first range which is a structural
operating range of the compensating device(15) and at least a second range(r1 - r2)
which is a preselected compensation range of the compensating device(15), is
provided with at least one switching element(r1, r2) for monitoring whether the
compensating device(15) remains within the preselected compensation range.