[0001] This invention relates to electronic anafogue displays of the kind having an arcuate
row of electricaJly-energisable elements and a setting member for addressing different
ones of the elements.
[0002] Electronic time switches, clocks and watches may be provided with a digital display
in which time is represented by a number, or with an analogue display in which time
is represented by sefectively energising radial elements arranged around a circular
scale.
[0003] One problem with such displays arises with the setting or changing of the display.
This is especially the case with time switches which have to be programmed with several
different times when switching operations are to occur. With time switches it is often
necessary frequently to change the time settings of the switching operations, such
as, for example, when controlling domestic heating at weekends.
[0004] Several different means are know by which the display can be changed. The display
may, for example, have a keyboard in which each key is associated with a different
number. By appropriately actuating a combination of keys, a time setting may be entered.
Although this may be satisfactory for digital displays where actuation of a key causes
display of the number associated with that key, it is less suitable for analogue displays
where the time is represented by the position of an element and is therefore less
directly associated with the keys on the keyboard. The keyboard also requires a large
amount of space.
[0005] An alternative arrangement involves the use of only one or two keys. While a key
is depressed, the time displayed is advanced in steps, the user releasing the key
when the desired time setting is reached. The second key may be used to change the
display. in the opposite sense. Although such arrangements take up less space, they
can be difficult or time consuming to use, since, if accurate setting is to be achieved
the display must be advanced relatively slowly.
[0006] It is an object of the present invention to provide an electronic analogue display
with improved setting means.
[0007] According to one aspect of the present invention there is provided an electronic
analogue display of the above- specified kind, characterised in that the setting member
is displaceable in opposite senses, that the display includes a sensor responsive
to the displacement of the setting member, and an addressing unit that addresses the
elements in accordance with the amount of displacement of the setting member and the
sense in which the setting member is displaced.
[0008] The setting member is preferably rotatable in either direction, the sensor being
responsive to rotation and direction of rotation of the setting member, the addressing
unit addressing different ones of the elements as the setting member is rotated, each
element in turn in one direction along the row being addressed as the member is rotated
in one direction and each element in turn in the other direction along the row being
addressed as the member is rotated in the other direction, and the rate at which different
elements are addressed being dependant- on the rate of rotation of the setting member.
[0009] The setting member may be continuously rotable and the elements may be arranged in
a circle. The setting member may be a rotatable wheel, an edge of the wheel projecting
from the casing of the display towards one side of the row of elements.
[0010] The elements may extend radially and the addressing unit may address the elements
to represent time. Each element may be divided into separate sub elements along its
radial length, the addressing unit addressing different ones of the sub elements to
vary the length of element that is energised in accordance with a temperature value.
[0011] The setting member may have a knurled surface and the sensor may engage the knurled
surface. The sensor preferably includes a spring in engagement with the knurled surface,
and a piezoelectric device in contact with the spring, the piezoelectric device producing
a first output in response to flexing of the spring in one sense, caused by displacement
of the setting member in one sense, and a second output, different from the first
output in response to flexing of the spring in the opposite sense, caused by displacement
of the setting member in the opposite sense.
[0012] For a predetermined displacement of the setting member, a greater number of elements
may be addressed when the setting member is displaced rapidly than when the setting
member is displaced slowly.
[0013] Time switches including displays according to the present invention, will now be
described, by way of example, with reference to the accompanying drawings, in which:
Figure 1 is a perspective view of a time switch;
Figure 2 is a schematic diagram of the time switch;
Figure 3 shows the time switch display in greater detail;
Figure 4 is a perspective view of an alternative time switch; and
Figure 5 shows an alternative display.
[0014] The time switch has a generally rectangular casing 1 from the rear face of which
project three metal pins 3 that are arranged for insertion into a mains electricity
socket The front of the housing is divided into a vertical lower face
4 and an inclined upper face 5. The lower face 4 is provided with a socket 6 for receiving
the mains plug (not shown) of the appliance that is to be controlled by the time switch.
The upper, inclined face 5 carries a circular, electronic analogue display 7 on which
is indicated the present time and the switching period or periods, as explained in
more detail below. From the right edge 9 of the inclined face 5 there projects a segment
of a setting member or wheel 10 by which the switching periods and time setting can
be altered. The top 11 of the casing 1 supports slider 12 which can be slid between
three positions: OFF, RUN and PROGRAMME and which can also been pushed down to control
programming of the time switch.
[0015] With reference now to Figure 2, it will be seen that the earth (E) and neutral (N)
sockets are connected directly to the earth and neutral pins 3. The live (L) socket
6 is connected to the live pin 3 via a relay 20 that is controlled by signals on line
21 from a processing unit 22. The processing unit 22 opens and closes the relay 20
according to the programmed switching periods in a store 23. The processing unit 22
also receives signals from a clock 24, from a sensing unit 25 responsive to rotation
of the setting wheel 10, and from the slider 12. Power for the processing unit is
derived from the mains connection via the pins 3, when the time switch is plugged
into a mains socket, or from a lithium battery 26 when the time switch is disconnected,
such as, during the programming operation. In addition to controlling the relay 20,
the processing unit 22 supplies output signals along line 30 to a display drive/addressing
unit 31 which controls energisation of the display 7.
[0016] With reference also to Figure 3, the display 7 comprises ninety-six elements 70 which
are arranged side-by- side in a circle, and which take the form of radially-extending
bars. The elements 70 are equally spaced around the circle and are located inwardly
of a circular scale 71 which carries numbers 0 to 23 corresponding to a twenty-four
hour clock. Each element 70 is thereby equivalent to a fifteen minute period. The
elements 70 are preferably liquid- crystal display elements although other electrically-energisable
elements could be used.
[0017] The wheel 10 is mounted so that it can be continuously rotated, that is, through
more than 360 degrees, having a knurled edge 26 so that it can be readily rotated
by hand. The wheel sensing unit 25 may take several different forms which are responsive
to rotation, and the direction of rotation of the wheel 10. The wheel 10 is engaged
by a click mechanism, such as a leaf spring 28 which engages the knurled edge 26 or
another toothed or serrated region of the wheel. In one form, a bi-morph piezo- electric
element 29 is mounted on the leaf spring. As the leaf spring 28 flexes, it distorts
the piezo-eiectric element 29 producing an output pulse. Rotation of the wheel 10
in one direction causes flexure of the spring 28 in one sense, giving rise to a positive
voltage peak followed by a negative peak from the piezo-electric element 29. Rotation
of the wheel 10 in the other direction causes flexure of the spring 28 in the opposite
sense, giving rise to a negative voltage peak followed by a positive peak. In other
arrangements for example, a a microswitch may be actuated periodically by a click
mechanism as the wheel is rotated, and a separate direction sensing switch may be
used to direct the direction of the rotation of the wheel 10.
[0018] The time switch is programmed in the way outlined below.
[0019] The slider 22 is first moved to the right, to the PROGRAMME position which causes
the display 7 to energise the element 70 against the 0' hours setting on the scale
71. The wheel 10 is then rotated clockwise, causing a train of pulses to be supplied
by the sensing unit 25 to the processing unit 22 representative of the direction and
the extent of rotation of the wheel. This causes the processing unit 22 and the display
drive unit 31 to energise successive adjacent elements 70 around the display 7, only
one element being energised at a time to give the appearance of a rotating dark bar.
[0020] When the dark bar reaches the desired time at which the first switching-on period
is to start, the user presses down the slider 22 into its ON position. The user holds
the slider 22 while rotating the wheel 10 further until the end of the first switching-on
period is reached, as depicted by further rotation of the dark bar against the scale
71. While the slider 22 is held down, intermediate elements 70 around the display
are darkened, producing an arc of dark elements corresponding to the first period
in which the appliance is to be switched on. The slider 22 is then released and the
wheel 10 rotated further to cause the dark bar to be rotated, without permanently
darkening intermediate elements, until the start of the next period. The slider 22
is then pressed down again while the wheel 10 is rotated to cause rotation of the
dark bar through the next period when the appliance is to be switched on, thereby
darkening intermediate elements and producing a second arc of dark elements. When
the end of the second switching-on period is reached, the slider 22 is released again.
This procedure is repeated until all the switching times are programmed. Large intervals
of time can be passed by rotating the wheel 10 quickly. Accurate setting is achieved
by rotating the wheel 10 slowly, and by rotating the wheel 10 backwards if the time
setting is accidentally overshot.
[0021] When all the switching periods have been programmed, the slider 22 is set to the
RUN position which causes the element 70 addressed at the time to be intermittently
energised, giving a flashing appearance. The wheel 10 is then rotated clockwise or
anticlockwise until the flashing bar is set to the present time, following which it
will be rotated around the scale with time, under control of the clock unit 24. The
programming of the time switch can be carried out when the unit is not plugged into
the mains socket, power for this being derived from the battery 26. This enables the
time switch to be set in the user's hand rather than in an inconvenient position in
a wall socket. As soon as the unit is plugged back into the mains socket, power to
drive the processing unit 22, display 7, and relay 20 etc. is derived from the mains
source, although, in other embodiments, the battery could provide the power permanently.
[0022] The arrangement of the present invention has several advantages. The setting arrangement
takes up very little space on the exterior of the unit, thereby enabling the overall
size of the unit to be kept to a minimum. Because rotation of the bar around the display
is achieved by rotating a wheel it is easy to use even by inexperienced users, since
movement of the setting wheel produces an equivalent displacement on the display.
Accurate and rapid setting can be achieved because the display can be advanced or
reversed at the desired rate, slowly or quickly, as necessary. One complete revolution
of the wheel may be arranged to produce one revolution around the display, or it may
be scaled to produce more or less than one revolution.
[0023] The processing unit could be arranged to be responsive to the speed of rotation of
the wheel 10, in such a way that the display is advanced at a faster rate, for a predetermined
rotation of the wheel, when the wheel is rotated quickly. For example, at a slow speed
the display 7 could be advanced by one element 70 for every click of the wheel 10,
whereas, when the wheel is rotated quickly, the display could be advanced by more
than one element for every click of the wheel. This may be particularly useful where
the time switch can be programmed with different time periods for different days,
since programming might require the setting wheel 10 to be spun through a complete
rotation for each day.
[0024] The setting wheel need not be edge mounted but could be mounted at other locations,
such as shown in Figure 4. In the arrangement of Figure 4, the setting wheel 10' is
mounted on the inclined upper face 5' of the time switch whilst the display 7' is
provided on the lower front face 4' and the socket 6' is provided on a side face 9'.
A separate button 13' is used for programming the time switch. Alternatively, the
setting wheel could be a knob located in the centre of the display itself.
[0025] - A display according to the present invention could, for example, be incorporated
in a heating programmer or a programmable thermostat. Such devices may include means
for setting temperature so that a heater controlled by the device produces different
temperatures at different times of the day. The display of such devices may be arranged
to represent the temperature programmed at different times of the day, as shown in
Figure 5. In this arrangement, each of the radially-extending elements 570 is formed
from a row of smaller sub-elements
580. All of the elements 570 are energised, their apparent length being varied by energising
selected ones of these sub-elements 580. Low temperatures are represented by making
the element 570 short, high temperatures being represented by energising more of the
sub-elements so that the element is longer. The display 57 may be marked with a scale
formed of several concentric rings 18 labelled with temperature so that the length
of the elements 570 in terms of temperature can be determined.
[0026] Liquid crystal display matrices having large numbers of pixels are now commonly available
and these can also be employed to produce a display of radial bars of varying length
resembling the display shown in Figure 5. Various other ways of representing temperature
could be employed.
1. An electronic analogue display having an arcuate row of etecfically-energisable
elements and a setting member for addressing different ones of the elements, charcterised
in that the setting member (10) is displaceable in opposite senses, that the display
includes a sensor (25) responsive to the displacement of the setting member, and an
addressing unit (31) that addresses the elements (70) in accordance with the amount
of displacement of the setting member and the sense in which the setting member is
displaced.
2. A display according to Claim 1, characterised in that the setting member (10) is
rotatable in either direction, that the sensor (25) is responsive to rotation and
direction of rotation of the setting member, that the addressing unit (31) addresses
different ones of the elements (70) as the setting member is rotated, that each element
in turn in one direction along the row is addressed as the member is rotated in one
direction and each element in turn in the other direction along the row is addressed
as the member is rotated in the other direction, and that the rate at which different
elements (70) are addressed is dependant on the rate of rotation of the setting member.
3. A display according to Claim 2, characterised in that the setting member is continuously
rotatable.
4. A display according to any one of the preceding claims, characterised in that the
elements (70) are arranged in a circle-
5. A display according to any one of the preceding claims, characterised in that the
setting member (10) is a rotatable wheel, and that an edge of the wheel projects from
a casing (1) of the display towards one side of the row of elements - (70).
6. A display according to any one of the preceding claims, characterised in that the
elements (70) extend radially, and that the addressing unit (31) addresses the elements
to represent time.
7. A display according to Claim 6, characterised in that each element (570) is divided
into separate sub elements - (580) along its radial length and that the addressing
unit addresses different ones of the sub elements to vary the length of element that
is energised in accordance with a temperature value.
8. A display according to any one of the preceding claims, characterised in that the
setting member (10) has a knurled surface (26) and that the sensor (25) engages the
knurled surface.
9. A display acording to Claim 8, characterised in that the sensor (25) includes a
spring (28) in engagement with the knurled surface (26), and a piezoelectric device
(29) in contact with the spring, and that the piezoelectric device - (29) produces
a first output in response to flexing of the spring in one sense, caused by displacement
of the setting member (10) in one sense, and a second output, different from the first output in response
to flexing of the spring in the opposite sense, caused by displacement of the setting
member in the opposite sense.
10. A display according to any one of the preceding claims, characterised in that,
for a predetermined displacement of the setting member (10), a greater number of the elements (70) are addressed when the setting member is
displaced rapidly than when the setting member is displaced slowly.