Steam cleaning apparatus

Abstract

A steam cleaning apparatus comprising: a main body having a boiler and a pump; a main power switch; a cleaning head coupled to a main body through a joint; a yoke in the main body or the cleaning head, the yoke having an arm contacting a position sensitive switch so that when the main body is in a non-use position, the position sensitive switch prevents the main switch from supplying power, and when the main body is in an in-use position, the position sensitive switch allows the main switch to provide power.

Claims

1. A steam cleaning apparatus comprising: a main body having a boiler and a pump; a main power switch; a cleaning head coupled to the main body through a joint; a yoke in the main body or the cleaning head, the yoke having an arm contacting a position sensitive switch so that when the main body is in a non-use position, the position sensitive switch prevents the main switch from supplying power, and when the main body is in an in-use position, the position sensitive switch allows the main switch to provide power.

2. The steam cleaning apparatus of claim 1 wherein: the yoke has a second arm, the second arm contacting a pressure release valve so that when the main body is in a non-use position, the pressure release valve is open to release pressure from a water tank, and when the main body is in an in-use position, the pressure release valve is closed.

3. The steam cleaning apparatus of claim 1 further comprising an indicator light for indicating whether the steam cleaning apparatus is ready to use.

4. The steam cleaning apparatus of claim 3, further comprising a thermostat that sends a signal to the indicator light to turn on.

5. The steam cleaning apparatus of claim 3 wherein the indicator light is on a time delay so that it turns on after a predetermined period of time after the main switch is powered.

6. A method for actuating a steam cleaning apparatus comprising: providing a main body having a boiler and a pump; providing a main switch to power the boiler and the pump; providing a steam cleaning head coupled to the main body through a joint; providing a yoke in the main body or the cleaning head, the yoke having a first arm contacting a position sensitive switch so that when the main body is in a vertical non-use position, the position sensitive switch prevents the main switch from supplying power, and when the main body is in a tilted in-use position, the position sensitive switch allows the main switch to provide power actuating the main switch to an on-position; and moving the steam apparatus from a vertical position to a tilted position to allow power to be supplied to one of the boiler or the pump.

7. The method of claim 6 wherein the joint is a universal joint and the universal joint joins the steam cleaning head and the main body.

8. The method claim 7 wherein the universal joint includes a protruding member that contacts the yoke, the yoke engaging the position sensitive switch.

9. The method of claim 8, wherein the yoke includes a second arm engaging a pressure release valve.

10. The method of claim 6 wherein the position sensitive switch comprises a microswitch.

11. The method of claim 6, where the steam cleaning apparatus comprises an indicator light for indicating when the steam cleaning apparatus is ready to use.

12. The method of claim 11, wherein the steam cleaning apparatus comprises a thermostat that detects the water temperature in the boiler; and wherein the thermostat sends a signal to the indicator light when the water reaches a pre-programmed temperature.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is a general view of a steam cleaning apparatus according to an embodiment of the invention;

(2) FIG. 2 is an exposed view of a main body portion of the steam cleaning apparatus shown in FIG. 1;

(3) FIG. 3 is a schematic diagram of the functional components of the steam cleaning apparatus shown in FIGS. 1 and 2;

(4) FIG. 4 is a close-up, exposed view of where the main body portion of the steam cleaning apparatus shown in FIGS. 1 and 2 connects with a steam cleaning head thereof; and

(5) FIG. 5 shows the steam cleaning apparatus of FIGS. 1 and 2 in a tilted, cleaning position.

DETAILED DESCRIPTION OF THE DRAWINGS

(6) Referring firstly to FIG. 1, there is shown a general view of a steam cleaning apparatus 100 having a main body portion 120, the lower end of which is mounted to a floor cleaning head 60. On the front of the main body portion 120, there can be seen an electrical power on-off switch 70, an adjustor dial 28, whereby a user can adjust the pressure and amount of steam emerging from steam cleaning head 60, and a water tank 10. The water tank can be filled through a water inlet 12 (shown in FIGS. 3 and 5) mounted on the back of main body portion 120. An upper end of main body portion 120 is connected to a handle portion 130, which includes upper 132 and lower 134 hooks for a user to be able to coil an electrical cable around. At the top end of handle portion 130 is a loop handle 136 for a user to be able to pick up the steam cleaning apparatus 100.

(7) The height of handle portion 130 may be adjusted by a user by depressing a resilient height adjustment button 138 and by sliding handle portion 130 into and out of main body portion 120 as desired until a catch on the interior of height adjustment button 138 engages with a corresponding detent in handle portion 130. A universal joint 140 joins the lower end of main body portion 120 to the steam cleaning head 60 and allows the steam cleaning apparatus to be pivoted by the user as desired.

(8) FIG. 2 shows main body portion 120 of the steam cleaning apparatus 100 with a front cover removed in order to expose its interior. As can be seen in FIG. 2, main body portion 120 houses water tank 10, an air pump 30, a valve 20 in fluid communication between the water tank 10 and the air pump 30, and a boiler 40, as the main components thereof, as well as a water filter 110 located in fluid communication between the water tank 10 and the boiler 40.

(9) FIG. 3 schematically shows the layout of the functional components of the steam cleaning apparatus shown in FIGS. 1 and 2, the operation of which will now be described.

(10) Electrically powered air pump 30 receives atmospheric air via inlet 32 thereof, compresses it, and expels the compressed air via outlet 34. Air pump 30 is of a conventional type which compresses the incoming atmospheric air via the action of alternating pistons.

(11) The compressed air is then passed to inlet 22 of first valve 20. First valve 20 has two outlets 24 and 26. The first outlet 24 is connected to an inlet 14 of water tank 10. The second outlet 26 is a vent which exhausts to atmosphere. Valve 20 acts a regulator valve and is provided with a pressure adjustor 28, the condition of which can be adjusted by a user in order to vary the amount of air supplied by the air pump 30 to the water tank 10. This is accomplished by diverting air from the inlet 22 to the vent 26 in preference to the outlet 24, in a ratio dependent on the condition of the adjustor 28. The pressure adjuster 28 includes an adjusting rod within valve 20 that acts on a resilient rubber seal of vent 26. According to the amount of pressure which is applied to the resilient rubber seal by the adjusting rod, the resilient rubber seal is opened, in order to allow air to bleed through the seal to atmosphere. The position of the adjusting rod is in turn determined by the condition of pressure adjustor 28 selected by the user.

(12) Water tank 10, which has previously been filled by the user with water via inlet 12 is therefore pressurized with air to the same degree. Water tank 10 is provided with an outlet 18 which is connected to an inlet 82 of a pressure release valve 80, which itself has an outlet 84 in fluid communication with atmospheric air. The pressure release valve 80 is arranged to allow water and/or air above a certain predetermined pressure to escape via outlet 84 to atmospheric air. The predetermined pressure is set at a value greater than the value which normally allows water to pass via outlet 16 of water tank 10 to boiler 40. Thus, if pressure in the water tank 10 builds up to a dangerous degree, for example because of a blockage downstream of water tank 10, rather than the pressure being increased further by the pumping action of air pump 30 until the apparatus risks exploding, the pressure is instead released via outlet 84. This is provided as a safety feature of the apparatus.

(13) Assuming there is no such blockage, water is accordingly pumped from outlet 16 of water tank 10 by the air pressure bearing down on it to the inlet 112 of water filter 110. Here, the water is filtered in order to remove low solubility salts, such as calcium carbonate, via an ion exchange resin, before the water is next passed via outlet 114 of the water filter 110 towards second valve 50 and boiler 40. Apart from the ion exchange resin, the water filter 110 may also contain a sponge to filter out any foreign bodies, thereby protecting the boiler 40 still further.

(14) Outlet 114 of filter 110 is in fluid communication with inlet 52 of a second valve 50, an outlet 54 of which is in turn in fluid communication with an inlet 42 of boiler 40.

(15) The second valve 50 has a predetermined pressure, above which it will allow water to flow into boiler 40, but below which it blocks the passage of water into the boiler. This predetermined pressure is set at a value lower than that set for pressure release valve 80, so that a normal range of operating pressures of boiler 40 lies between the predetermined pressure value of second valve 50 and the predetermined pressure value of pressure release valve 80. Exactly where within this range of normal operating pressures the boiler operates at is determined by the setting of regulator valve 20 which has been chosen by the user via pressure adjustor 28. This in turn determines how fast water passes through the boiler 40 and is turned into steam, and therefore how much steam, in terms of volume of steam per unit time, exits outlet 44 of boiler 40. The steam thus generated then passes via connector 46 to pivot connector 48 and to nozzle connector 142 of steam cleaning head 60.

(16) In the illustrated embodiment of FIG. 2, the electrical power supplied to air pump 30 includes a time-delay circuit 160, so that air pump 30 only starts to pump air through the system after a five second delay, because boiler 40 takes five seconds to heat up from ambient temperature to a temperature of 110 degrees Celsius. A thermostat 162 connected to the boiler 40 then ensures that the temperature of boiler 40 is held within a range of from 110 to 145 degrees Celsius once boiler 40 has heated up. Thus water entering boiler 40 is converted into steam almost instantaneously upon its entry into the boiler via inlet 42 and the possibility that water can pass through the boiler and exit the floor cleaning head 60 without being converted into steam is thereby avoided.

(17) FIG. 4 shows in close-up an exposed view of where the main body portion 120 of the steam cleaning apparatus 100 connects with the steam cleaning head 60. As may be seen in FIG. 4, the universal joint 140 includes a member 150 which acts upon a spring-loaded yoke 152. One arm 152a of yoke 152 engages with pressure release valve 80 and another arm 152b of yoke 152 engages with a position-sensitive microswitch 90. Microswitch 90 is connected in electrical series with main on-off switch 70 of steam cleaning apparatus 100. At the other end of yoke 152 are two prongs 154a, 154b, on each of which is mounted a respective coiled spring (not shown), each such spring also being mounted to an interior surface of the main body 120 of the steam cleaning apparatus 100. Thus, when the steam cleaning apparatus 100 is put in a substantially vertical, storage position, member 150 of universal joint 140 pushes on spring-loaded yoke 152, one arm 152a of which in turn presses on pressure release valve 80 and the other arm 152b of which in turn presses on the position-sensitive microswitch 90. This has the effect of first, opening the pressure release valve 80 thereby releasing air pressure from the water tank 10 until it returns to atmospheric pressure, and secondly of interrupting the flow of electrical current from the main on-off switch 70 to air pump 30 and boiler 40. At the same time, the two coiled springs are placed in tension.

(18) On the other hand, when the steam cleaning apparatus 100 is put in a tilted, cleaning position, as shown in FIG. 5, member 150 withdraws from spring-loaded yoke 152 and the two arms 152a, 152b disengage from the pressure release valve 80 and the position-sensitive microswitch 90 by the action of the two springs. Thus, pressure can now build up in the water tank 10 and electrical power can also be supplied to both the pump 30 and the boiler 40. Although in the presently described embodiment, both the main on-off switch 70 and the pressure release valve 80 are affected by whether the steam cleaning apparatus is put in a substantially vertical, storage position or in a tilted, cleaning position, alternative embodiments in which only one or neither of these features are present are also possible. However, both are preferred as safety features, as well as providing increased convenience for the user.

(19) An additional feature of the described invention is an indicator light 164 connected in series with the main on-off switch 70 of the apparatus. For greater aesthetic appeal, this indicator light 164 is mounted within the interior of main body portion 120 of the apparatus, but water tank 10 is made of a translucent plastics material, so that light from the indicator light 164 is able to shine through the water tank 10 and thus be visible by a user from the exterior of the apparatus as an apparent illumination of water tank 10.

(20) The indicator light 164 has a first colour for indicating when the steam cleaning apparatus 100 is powered on but is not ready to use and a second colour for indicating when the steam cleaning apparatus 100 is powered on and is ready to use. In order to achieve this, the indicator light 164 has a first condition associated with the first colour, a second condition associated with the second colour and a third condition not associated with either the first or the second colour.

(21) These first, second and third conditions of the indicator light 164 are achieved by electrical wiring of the indicator light 164 in the appropriate fashion, as follows:

(22) The first condition of the indicator light 164 is induced by the on-off switch 70 being put in the “on” state by a user and either the air pump 30 being prevented from receiving a supply of electrical power by the time delay circuit or the thermostat detecting that the temperature of steam generated by the boiler 30 is outside the operating temperature range. The second condition is induced by the on-off switch 70 being in the “on” state and the air pump 30 receiving a supply of electrical power unhindered by the time delay circuit and the thermostat detecting that the temperature of steam generated by the boiler 30 is within the desired operating temperature range. The third condition is induced by the on-off switch 70 being in the “off” state thereof. When on-off switch 70 is in an “off” state, the indicator light remains off and no colour is displayed due to the absence of any electrical current flowing therethrough. However, when the on-off switch 70 is put in an “on” state by the user, the indicator light illuminates the water tank 10 with colours as shown in the following Table 1:

(23) TABLE-US-00001 TABLE 1 Temperature of Temperature of steam detected by steam detected by thermostat thermostat Colour of within operating outside operating indicator light temperature range temperature range Air pump on Blue Red Air pump off Red Red

(24) Thus, in the described embodiment, red is the first colour of the indicator light and blue is the second colour. However, it may be understood that any other colours could be chosen instead as the first and second colours, for example yellow and green respectively. It should also be understood that in an alternative embodiment in which the boiler of the steam cleaning apparatus is not provided with a thermostat, the first condition of the indicator light is induced by the on-off switch 70 being put in the “on” state by a user and the air pump 30 being prevented from receiving a supply of electrical power by the time delay circuit, and the second condition is induced by the on-off switch 70 being in the “on” state and the air pump 30 receiving a supply of electrical power unhindered by the time delay circuit. In still yet a further embodiment in which the boiler does include a thermostat and the steam cleaning apparatus is not provided with a time delay circuit, the first condition of the indicator light is instead induced by the on-off switch 70 being put in the “on” state by a user and the thermostat 162 detecting that the temperature of steam generated by the boiler 40 is outside the operating temperature range, whereas the second condition is induced by the on-off switch 70 being in the “on” state and the thermostat 162 detecting that the temperature of steam generated by the boiler 40 is within the desired operating temperature range. In all cases, however, the third condition of the indicator light 164 is always induced by the on-off switch 70 being put in the “off” state by the user.