FIELD OF THE INVENTION
The present invention is concerned with a floor cleaning apparatus and a liquid delivery assembly suitable for, but not limited to, use in a floor cleaning apparatus. The present invention is also concerned with different applications of liquid delivery assemblies.
BACKGROUND OF THE INVENTION
There are a variety of conventional floor cleaning apparatus. In older generations of such apparatus, the apparatus would typically provide a cleaning head with a stick handle connected to the cleaning head. The cleaning head is configured to be installed with a disposable cleaning fabric sheet for engaging a floor surface during cleaning. If a user would like to make use of a liquid detergent to assist the cleaning, s/he would need to use a separate detergent bottle and spray liquid detergent on the floor surface before cleaning the floor with the apparatus. This can be cumbersome.
Subsequent floor cleaning apparatus have been developed in that there is provided with a cleaning fluid container as part of the apparatus. This type of apparatus is provided with, for example, a switch or actuator on the handle such that on pressing of the switch or the actuator, cleaning fluid from the container can be deployed and sprayed onto a floor surface in front of the apparatus. With such an apparatus, a separate detergent bottle would not be needed. While the provision of a built-in fluid detergent supply unit is desirable, problems of detergent leakage tend to arise at the same time. Other problems include unreliable flow of liquid detergent when desired, complications and/or bulkiness of construction, high manufacture cost, etc.
The present invention seeks to address these problems, and/or at least to provide a useful alternative to the public. The present invention also provides liquid delivery assemblies in general suitable for use in different applications.
SUMMARY OF THE INVENTION
According to a first aspect of the present invention, there is provided a floor cleaning apparatus comprising a cleaning head portion for engaging a floor surface during cleaning, an upstanding portion for maneuvering movement of the cleaning head portion, a liquid delivery assembly, a handle portion extending from the upstanding portion and a sealed liquid storage container, wherein the cleaning head portion includes at least a first nozzle for discharging of cleaning detergent therefrom, wherein:
- the liquid delivery assembly defines at least a first passageway,
- the liquid delivery assembly includes a first chamber, the first passageway allowing fluid communication between the sealed liquid storage container and the first chamber,
- a second chamber situated adjacent the first chamber,
- the liquid delivery assembly includes a first conduit allowing liquid to exit from the second chamber to the first nozzle for discharge, and
- at least the second chamber includes a damper for storing pressure when liquid is being pumped from the second chamber to the first nozzle and releasing pressure when liquid is not being pumped from the second chamber to the first nozzle.
Preferably, the damper may assume the form of an elongate tubing which expands when under an elevated internal pressure, e.g. when taking on an amount of fluid when liquid is being pumped from the second chamber to the first nozzle, and which when resumes to it default configuration, when not under an elevated internal pressure, i.e. when liquid is not being pumped from the second chamber to the first nozzle, releases the amount of fluid by default. The damper may define a closed end and an open end and is in fluid communication with the second chamber, and may be hanging or otherwise extending from the second chamber.
Suitably, the damper may be made from a soft resilient plastic(s) selected from the group consisting of silicone rubber, ethylene propylene diene monomer (EPDM) or thermoplastic polyurethane (TPU).
Advantageously, the floor cleaning apparatus may further comprise:
- a second nozzle also for discharging of cleaning detergent from the sealed liquid storage container,
- a single needle defining both the first passageway and a second passageway separated from the first passageway,
- a third chamber situated adjacent the first chamber, the second passageway allowing gaseous communication between the third chamber and the sealed liquid storage container,
- an inlet allowing surrounding air or gas to enter the third chamber and then the liquid storage container,
- a fourth chamber situated adjacent the first chamber, and
- a second conduit allowing liquid to exit from the fourth chamber to the second nozzle for discharge.
In an embodiment, the first chamber may be provided with a first aperture for fluid communication with the second chamber, and the first aperture may be reciprocatingly closable by a first one-way valve; the first chamber may be provided with a second aperture for fluid communication with the fourth chamber, and the second aperture may be reciprocatingly closable by a second one-way valve; the second chamber and the fourth chamber may be provided with a first spring-loaded valve and a second spring-loaded valve, respectively, for minimizing liquid leakage from the first conduit and the second conduit, respectively; and the second chamber and the fourth chamber may be provided with a first plunger and a second plunger, respectively, operable by one motor for pumping fluid from the sealed liquid container to the first and second nozzles, respectively, for discharge.
In one embodiment, the chamber may be provided with a third plunger operable by the one motor for pumping surrounding air or gas via said inlet to the third chamber and then via said second passageway to the sealed liquid storage container for equalizing pressure in the sealed liquid container; the inlet may act as a third one-way valve for controlling entry of surrounding air or gas to the third chamber; and the third chamber may be provided with a fourth one-way value controlling passage of the air or gas from the third chamber to the sealed liquid storage container, for equalizing pressure in the sealed liquid storage container.
In a specific embodiment, the liquid delivery assembly may include a fifth chamber housing the first, second and third plungers and the one motor, and the fifth chamber may include a pivotable plate movable by the one motor and for actuating on the first, second and third plungers alternatingly, thus generating a pumping action; and the cleaning head portion may be free of any check valve for controlling leakage of liquid from the first nozzle and/or said second nozzle when the floor cleaning apparatus is not in use.
According to a second aspect of the invention, there is provided a liquid delivery assembly for controlling flow of liquid from a sealed liquid storage container to at least a first nozzle, wherein:
- the liquid delivery assembly provides a first passageway,
- the liquid delivery assembly provides a first chamber, the first passageway allowing fluid communication between the sealed liquid storage container and the first chamber,
- a second chamber situated adjacent the first chamber,
- a first conduit allowing liquid to exit from the second chamber for said first nozzle for discharge, and
- at least the second chamber includes a damper for storing pressure when liquid is being pumped from the second chamber to the first nozzle and releasing pressure when liquid is not being pumped from the second chamber to the first nozzle.
Preferably, the liquid delivery assembly may comprise a single needle defining both the first passageway and a second passageway separated from the first passageway; a third chamber situated adjacent the first chamber, the second passageway allowing gaseous communication between the third chamber and the sealed liquid storage container; and an inlet allowing surrounding air or gas to enter the chamber and then the liquid storage container.
Suitably, the first chamber may be provided with a first aperture allowing fluid communication with the second chamber, and the first aperture may be reciprocatingly closable by a first one-way valve; the second chamber may be provided with a second aperture reciprocatingly closable by a second one-way valve for controlling flow of fluid to the first nozzle; the second chamber may be provided with a first plunger operable by one motor for pumping fluid from the sealed liquid storage container to the first chamber via the first passageway, then to the second chamber via the first aperture, then via the second aperture; the third chamber may be provided with a second plunger operable by the one motor for pumping surrounding air or gas via the inlet to the third chamber and then via the second passageway to the sealed liquid storage container; the second chamber may be provided with a first sub-chamber extended therefrom; and the third chamber may be provided with a third one-way valve for controlling entry of surrounding air or gas to the third chamber, and a fourth one-way valve for controlling passage of air or gas from said third chamber to the sealed liquid storage container, for equalizing pressure in the liquid storage container.
Advantageously, the assembly may comprise a fourth chamber situated adjacent the first chamber and a second conduit allowing liquid to exit from the fourth chamber for a second nozzle, wherein the first chamber may be provided with a third aperture allowing fluid communication with the fourth chamber, and the fourth aperture is reciprocatingly closable by a fifth one-way valve; the fourth chamber may be provided with a fourth aperture reciprocatingly closable by a sixth one-way valve for controlling flow of fluid to the second nozzle; and the fourth chamber may be provided with a third plunger operable by the one motor for pumping fluid from the liquid storage container to the first chamber via the first pipeline for the second nozzle.
In an embodiment, the assembly may comprise a fifth chamber housing the first, second and third plungers and the one motor, the fifth chamber may include a pivotable plate drivenable by the one motor and for actuating on the first, second and third plungers alternatingly, for generating a pumping action. The first and fifth one-way valves may be configured to allow one-way fluid flow from the first chamber to the second chamber and the first chamber to the fourth chamber, respectively.
According to a third aspect of the invention, there is provided a floor cleaning apparatus comprising a cleaning head portion for engaging a floor surface during cleaning, an upstanding portion for maneuvering movement of said cleaning head portion, a liquid delivery assembly as described above, a handle portion extending from the upstanding portion, and the sealed liquid container, wherein the cleaning head portion includes the first nozzle and the second nozzle arranged on lateral opposite ends for forward discharging liquid therefrom.
Preferably, sequentially, the sealed liquid storage container, the first passageway of the needle, the first chamber, the second chamber, the first conduit, and the first nozzle together may define a liquid flow path; sequentially, the sealed liquid storage container, the first passageway of the needle, the first chamber, the fourth chamber, the second conduit, and the second nozzle together may define a liquid flow path; sequentially, surrounding air or gas, the inlet, the third chamber, the second passageway of the needle and the sealed liquid storage container together may define a gas flow path.
According to a fourth aspect of the present invention, there is provided a floor cleaning apparatus comprising a cleaning head portion for engaging a floor surface during cleaning, an upstanding portion for maneuvering movement of said cleaning head portion, a liquid delivery assembly, a handle portion extending from the upstanding portion and a sealed liquid storage container, wherein the cleaning head portion includes a first nozzle and a second nozzle for discharging of cleaning detergent therefrom, wherein the liquid delivery assembly includes:
- a needle defining a first passageway and a second passageway separated from the first passageway,
- a first chamber, the first passageway allowing fluid communication between the sealed liquid storage container and the first chamber,
- a second chamber situated adjacent the first chamber,
- a first conduit allowing liquid to exit from the second chamber to the first nozzle for discharge,
- a third chamber situated adjacent the first chamber, the second passageway allowing gaseous communication between the third chamber and the sealed liquid storage container,
- an inlet allowing surrounding air or gas to enter the third chamber and then the liquid storage container,
- a fourth chamber situated adjacent the first chamber, and
- a second conduit allowing liquid to exit from the fourth chamber to the second nozzle for discharge.
Preferably, the first chamber may be provided with a first aperture for fluid communication with the second chamber, and the first aperture may be reciprocatingly closable by a first one-way valve; the first chamber may be provided with a second aperture for fluid communication with the fourth chamber, and the second aperture may be reciprocatingly closable by a second one-way valve; the second chamber and the fourth chamber may be provided with a first spring-loaded valve and a second spring-loaded valve, respectively, for minimizing liquid leakage from the first conduit and the second conduit, respectively; and the second chamber and the fourth chamber may be provided with a first plunger and a second plunger, respectively, operable by one motor for pumping fluid from the sealed liquid container to the first and second nozzles, respectively, for discharge.
Suitably, the third chamber may be provided with a third plunger operable by the one motor for pumping surrounding air or gas via the inlet to the third chamber and then via the second passageway to the sealed liquid storage container for equalizing pressure in the sealed liquid container; the inlet may act as a third one-way valve for controlling entry of surrounding air or gas to said third chamber; and the third chamber may be provided with a fourth one-way value controlling passage of the air or gas from the third chamber to the sealed liquid storage container, for equalizing pressure in the liquid storage container.
Advantageously, the liquid delivery assembly may include a fifth chamber housing the first, second and third plungers and the one motor, and wherein the fifth chamber may include a pivotable plate movable by the one motor and for actuating on the first, second and third plungers alternatingly, thus generating a pumping action.
In an embodiment, the cleaning head portion may be free of any check valve for controlling leakage of liquid from the first nozzle and/or the second nozzle when said floor cleaning apparatus is not in use.
In one embodiment, at least one of the second chamber and the fourth chamber may include a damper for storing pressure when liquid is being pumped from the second chamber to the first nozzle and/or from the fourth chamber to the second nozzle for discharge.
According to a fifth aspect of the present invention, there is provided a liquid delivery assembly for controlling flow of liquid from a sealed liquid storage container to a first nozzle, comprising:
- a needle defining a first passageway and a second passageway separated from the first passageway,
- a first chamber, the first passageway allowing fluid communication between the sealed liquid storage container and the first chamber,
- a second chamber situated adjacent the first chamber,
- a first conduit allowing liquid to exit from the second chamber for the first nozzle for discharge,
- a third chamber situated adjacent the first chamber, the second passageway allowing gaseous communication between the third chamber and the sealed liquid storage container, and
- an inlet allowing surrounding air or gas to enter said third chamber and then the liquid storage container.
Preferably, the first chamber may be provided with a first aperture allowing fluid communication with said second chamber, and the first aperture is reciprocatingly closable by a first one-way valve; the second chamber may be provided with a second aperture reciprocatingly closable by a second one-way valve for controlling flow of fluid to the first nozzle; the second chamber may be provided with a first plunger operable by one motor for pumping fluid from the sealed liquid storage container to the first chamber via the first passageway, then to the second chamber via the first aperture, then via the second aperture; the third chamber may be provided with a second plunger operable by the one motor for pumping surrounding air or gas via the inlet to the third chamber and then via the second passageway to the sealed liquid storage container; and the second chamber may be provided with a first sub-chamber extended therefrom.
Suitably, the third chamber may be provided with a third one-way valve for controlling entry of surrounding air or gas to the third chamber, and a fourth one-way valve for controlling passage of air or gas from the third chamber to the sealed liquid storage container, for equalizing pressure in the liquid storage container.
Advantageously, the assembly may comprise a fourth chamber situated adjacent the first chamber, and a second conduit allowing liquid to exit from said fourth chamber for a second nozzle, wherein the first chamber may be provided with a third aperture allowing fluid communication with the fourth chamber, and the fourth aperture may be reciprocatingly closable by a fifth one-way valve; the fourth chamber may be provided with a fourth aperture reciprocatingly closable by a sixth one-way valve for controlling flow of fluid to the second nozzle; and the fourth chamber may be provided with a third plunger operable by said one motor for pumping fluid from the liquid storage container to said first chamber via said first pipeline for the second nozzle.
In an embodiment, the assembly may comprise a fifth chamber housing the first, second and third plungers and the one motor, said fifth chamber may include a pivotable plate drivenable by the one motor and for actuating on the first, second and third plungers alternatingly, for generating a pumping action.
In one embodiment, the first and fifth one-way valves may be configured to allow one-way fluid flow from the first chamber to the second chamber and the first chamber to the fourth chamber, respectively.
In a further embodiment, the second chamber may include a damper for storing pressure when liquid is being pumped from the second chamber to the first nozzle for discharge.
In another embodiment, there is provided with a floor cleaning apparatus comprising a cleaning head portion for engaging a floor surface during cleaning, an upstanding portion for maneuvering movement of said cleaning head portion, a liquid delivery assembly as described above, a handle portion extending from the upstanding portion, and the sealed liquid container, wherein the cleaning head portion may include the first nozzle and the second nozzle arranged on lateral opposite ends for forward discharging liquid therefrom.
In such an embodiment, sequentially, the sealed liquid storage container, the first passageway of the needle, the first chamber, the second chamber, the first conduit, and the first nozzle together may define a liquid flow path. Further, sequentially, the sealed liquid storage container, the first passageway of the needle, the first chamber, the fourth chamber, the second conduit, and the second nozzle together may define a liquid flow path. Yet further, sequentially, surrounding air or gas, the inlet, the third chamber, the second passageway of the needle and the sealed liquid storage container together may define a gas flow path.
The cleaning head portion may be free of any check valve for controlling leakage of liquid from the first nozzle when the floor cleaning apparatus is not in use.
According to a sixth aspect of the present invention, there is provided a floor cleaning apparatus comprising a cleaning head portion for engaging a floor surface during cleaning, an upstanding portion for maneuvering movement of the cleaning head portion, a liquid delivery assembly, a handle portion extending from the upstanding portion and a sealed liquid storage container, wherein the liquid delivery assembly includes a single needle defining a first passageway for allowing cleaning detergent from the sealed storage container to travel to the cleaning head portion therethrough and a second passageway for allowing as or air to travel from the surrounding to the sealed storage container for pressure equalization, and wherein the needle has a non-cylindrical configuration and a flattened configuration.
Preferably, the needle may have a length from 20-22 mm; the needle may have a width at its base from 6-7.5 mm and tapers towards its tip; the needle may be provided with a wall separating the first passageway and the second passageway, and the thickness of the wall in said needle is 1.5-2 mm; both the first passageway and the second passage way have a cylindrical profile, and the diameter of the first passageway and the second passageway is 1.8-2.5 mm; and the needle may be made of polyoxymethylene (POM) or nylon, or a non-metallic material.
According to a seventh aspect of the present invention, there is provided with a liquid delivery assembly for controlling flow of liquid from a sealed liquid storage container for discharge, comprising a damping device for temporality storing pressure whereby flow rate of the liquid being discharged is enhanced.
According to an eighth aspect of the present invention, there is provided a liquid processing assembly for controlling flow of a first liquid from a first liquid storage container and controlling flow of a second liquid from a second liquid storage container for discharge, and for mixing said first fluid and said second fluids for generating a formulation therefrom during discharge, comprising:
- a first chamber,
- a first pipeline allowing fluid communication between the first liquid storage container and said first chamber,
- a second chamber situated adjacent said first chamber,
- a second pipeline allowing fluid communication between the second liquid storage container said second chamber,
- a first outlet from said first chamber and a second outlet from said second chamber, and
- a converger for mixing the first fluid and the second fluid exiting from said first outlet and said second outlet, respectively,
- wherein:
- a. said first chamber is provided with a first plunger operable by one motor for pumping fluid from the first liquid storage container to said first chamber via said first pipeline, and
- b. said second chamber is provided with a second plunger operable by said one motor for pumping fluid from the second liquid storage container to said second chamber via said second pipeline.
Preferably, the first and second liquid storage containers may be sealed containers. The liquid processing assembly may be provided with a third chamber allowing gaseous or air communication between said third chamber and the first and second sealed liquid containers. In this configuration, two pipelines forking off from said third chamber to said first and second sealed liquid containers would be needed. Alternatively, the liquid processing assembly may be provided with a third chamber and a third pipeline allowing gaseous or air communication between said third chamber and the first sealed liquid storage container for pressure equalization in the first sealed liquid container, and a fourth chamber and a fourth pipeline allowing gaseous or air communication between said fourth chamber and the second sealed liquid storage container for pressure equalization in the second sealed liquid container, respectively.
BRIEF DESCRIPTION OF DRAWINGS
Some embodiments of the present invention will now be explained, with reference to the accompanied drawings, in which:
FIG. 1 is a perspective view of a conventional floor cleaning apparatus;
FIG. 2 is a schematic diagram illustrating a liquid delivery assembly comprised in the apparatus of FIG. 1;
FIG. 3 is a perspective view of an embodiment of a floor cleaning apparatus according to an aspect of the present invention;
FIG. 4 is a schematic diagram illustrating an embodiment of a liquid delivery assembly comprised in the apparatus of FIG. 3 and according to another aspect of the present invention;
FIG. 5A is a three-dimensional view of the liquid delivery assembly of FIG. 4;
FIG. 5B is an exploded view of the liquid delivery assembly of FIG. 5A;
FIG. 6 is a perspective view of the liquid delivery assembly of FIG. 5A but with top and middle caps thereof removed;
FIG. 7A is an exploded view of the liquid delivery assembly of FIG. 5A but with the top cap thereof removed;
FIG. 7B is a schematic view of the liquid delivery assembly of FIG. 7A;
FIG. 8A is a schematic diagram illustrating different chambers (or zones) defined in the liquid delivery assembly of FIG. 5A;
FIGS. 8B and 8C are schematic diagrams of the liquid delivery assembly of FIG. 5A but with a lower portion thereof removed;
FIG. 9A is a schematic diagram illustrating different chambers (or zones) defined in the liquid delivery assembly of FIG. 5A;
FIGS. 9B and 9C are schematic diagrams of the liquid delivery assembly of FIG. 5A also with the lower portion thereof removed;
FIG. 10A is a schematic diagram illustrating different chambers (or zones) defined in the liquid delivery assembly of FIG. 5A;
FIG. 10B is a schematic diagram of the liquid delivery assembly of FIG. 5A also with the lower portion thereof removed;
FIG. 11 is a schematic diagram illustrating, in operation, liquid flow path via the liquid delivery assembly of FIG. 5A;
FIG. 12 is a schematic diagram illustrating, in operation, air or gas flow path via the liquid delivery assembly of FIG. 5A;
FIGS. 13A and 13B are schematic diagrams showing two different states of the liquid delivery assembly of FIG. 5A;
FIGS. 14A, 14B and 14C are schematic diagrams showing three different states of the liquid delivery assembly of FIG. 5A;
FIGS. 15A and 15B are side-by-side representations of the conventional liquid delivery assembly of FIG. 2 and the novel liquid delivery assembly, respectively;
FIG. 16A is a schematic diagram showing a three-dimensional view of an embodiment of a liquid delivery assembly different from the embodiment of the liquid delivery assembly of FIG. 5A;
FIG. 16B is an exploded view of the liquid delivery assembly of FIG. 16A;
FIG. 17 is a perspective view of the liquid delivery assembly of FIG. 16A but with top and middle caps thereof removed;
FIG. 18A is an exploded view of the liquid delivery assembly of FIG. 16A but with the top cap thereof removed;
FIG. 18B is a schematic view of the liquid delivery assembly of FIG. 18A, and FIG. 18B1 is an enlarged view of a portion of FIG. 18B;
FIG. 19A is a schematic diagram illustrating different chambers (or zones) defined in the liquid delivery assembly of FIG. 16A;
FIG. 19B is schematic diagram of the liquid delivery assembly of FIG. 16A but with a lower portion thereof removed, and FIG. 19B1 is an enlarged view of showing a portion of FIG. 19B;
FIG. 19C is a schematic diagram of the liquid delivery assembly of FIG. 16A but illustrating the flow of fluid differently,
FIG. 20A is a schematic diagram illustrating different chambers (or zones) defined in the liquid delivery assembly of FIG. 16A;
FIG. 20B is schematic diagram of the liquid delivery assembly of FIG. 16A also with the lower portion thereof removed;
FIG. 20C is an alternative schematic view diagram of FIG. 20B, and FIG. 20C1 is an enlarged view showing a portion of FIG. 20C,
FIG. 21A is a schematic diagram of the liquid delivery assembly of FIG. 16A also with the lower portion thereof removed, and FIG. 21A1 is an enlarged view showing a portion of FIG. 21A,
FIG. 22A is a schematic diagram illustrating, in operation, liquid flow path via the liquid delivery assembly of FIG. 16A, and FIG. 22A1 is an enlarged view showing a portion FIG. 22A,
FIG. 23A is a schematic diagram illustrating, in operation, air or gas flow path via the liquid delivery assembly of FIG. 16A, and FIG. 23A1 is an enlarged view showing a portion of FIG. 23;
FIGS. 24A and 24B are schematic diagrams showing two different states of the liquid delivery assembly of FIG. 16A; and
FIGS. 25A and 25B are schematic diagrams showing two different states of the liquid delivery assembly of FIG. 5A.
DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS OF THE INVENTION
FIG. 1 shows a perspective view of a conventional floor cleaning apparatus 2. The apparatus comprises a cleaning head portion 4 provided with two nozzles 6, 8 arranged at opposite lateral sides thereof for forward-discharging of liquid detergent, an upstanding portion 10 and a handle portion 12. The upstanding portion 10 is fitted with a container 14 in the form of a liquid detergent reservoir and means or assembly 16 (represented in FIG. 2) for controlling delivery of liquid detergent from the reservoir to the nozzles 6, 8 for forward-discharging. The delivery means 16 includes a number of cylinders or independent devices provided in separate locations in the apparatus 2 but are otherwise connected together by parts such as conduits, tubings, pipelines, etc.
FIG. 2 is a schematic diagram summarizing the operation of the delivery means 16 of the apparatus 2 of FIG. 1. The delivery means 16 includes a container A (14) for storing liquid detergent, a pump B, a diverger C for forking off or channeling passing liquid detergent to conduits D, E for the respective nozzles D1, E1 for discharge, and a valve means F for allowing air to enter the container A for pressure equalization. The pump B is located at the upstanding portion 10 of the apparatus 2. The diverger C is located in the cleaning head portion 4 of the apparatus 2 and is provided with a check-valve therein for minimizing leakage of liquid detergent from the pump B to the nozzles D1, E1 when the apparatus 2 is not in use and/or when the cleaning head portion is in a tilted orientation. While both the pump B and the valve means F may be located in the upstanding portion 10, it to be noted that the pump B and the diverger C are located in different portions in the apparatus 2 and are connected by the conduits D, E and a conduit G. The pump B is caused to operate, e.g. by the user during use, while the valve means is separately and passively operated when there is a drop in pressure in the container A. A number of problems tend to arise with the apparatus 2 or the delivery means 16. First, with the pump B, the diverger C and the valve means F located and/or operated separately, the construction and assembly of the delivery means 16 and the apparatus 2 is technically complicated in terms of manufacturing of the apparatus 2. Second, since the valve means F is passively operated and is connected to the container 14 filled with liquid detergent which is typically sticky, an air inlet or one-way valve of the valve means F leading to the container 14 tends to experience the problem of “sticking”, meaning the air inlet or the one-way valve tends to be clogged up or malfunction over time when the liquid detergent thereat is dried up. Third, the delivery of liquid detergent to the two nozzles 6, 8 are not independent and this also reduces reliability. These are just some of the problems.
FIG. 3 shows a perspective view of an embodiment of a floor cleaning apparatus 102 according to an aspect of the present invention. The apparatus 102 comprises a cleaning head portion 104 provided with two nozzles 106, 108 arranged at opposite lateral sides thereof for forward-discharging of liquid detergent, an upstanding portion 110 and a handle portion 112. The upstanding portion 110 is fitted with a container 114 in the form of a sealed reservoir for liquid detergent storage and a first embodiment of a liquid delivery assembly 116 according to another aspect of the present invention. The assembly 116 functions to control delivery of the liquid detergent from the reservoir to the nozzles 106, 108 for forward-discharging.
FIG. 4 is schematic diagram illustrating the assembly 116 according to another aspect of the present invention. The assembly 116 includes a container A′ (or the sealed liquid container 146) for liquid detergent, a pump unit B′, conduits D′, E′ for the respective nozzles D1′ (106), E1′ (108), means for diverging flow of fluid to the conduits D′ E′, and a valve means F′ for allowing air to enter the container A′ (146) for pressure equalization. Further details of the apparatus 102 and the assembly 116 are explained below.
FIG. 5A is a schematic diagram which illustrates the construction of the liquid delivery assembly 116 or at least most of the construction of the assembly 116. The assembly 116 is in the form of an integral operating system having a first pipeline 118 allowing fluid communication from the container 114 to the assembly 116, a second pipeline 120 allowing surrounding air or gaseous communication to travel via the assembly 116 to the container 114 for pressure equalization in the container 114, fluid outlets 122, 124, a battery (not shown) and a motor 126 powered by the battery for operating both fluid flow and air or gaseous flow in the assembly 116. In this embodiment, the sealed liquid container A′ (146) has a cap made of a self-sealable silicone membrane material. Both the first and second pipelines are in the form of rigid metallic pipes (e.g. steel pipes) with a sharp end. With this configuration, the pipelines 118, 120 can be inserted into the container A′ (140) via the cap and a liquid tight seal is then automatically formed around the pipelines 118, 120.
FIG. 5B is an exploded view of the assembly of FIG. 5A. As shown, the assembly 116 includes a housing 128 for accommodating the motor 126 and a three-cylinder arrangement. The three cylinders in the arrangement are operable by three plungers, 130, 132, 134, respectively. The plungers 130, 132, 134 resemble three pumps drivenable by the motor 126. The housing 128 is provided with a circumferential upper flange 129. The assembly 116 is provided with a lower cap 137 in which the plungers 130, 132, 134 sit and to which the housing 128 engages.
FIG. 6 is a perspective view of a lower portion the assembly 116 of FIG. 5A but with the housing 128 removed. In this figure, the three plungers 130, 132, 134, are more clearly shown. There is provided a wall 136 defining a lower surface to which the top of the three plungers 130, 132, 134 engage and connect. The plungers 130, 132, 134 are operable by a wobbleable plate 146 which is movable by an axle of the motor 126.
FIG. 7A is a perspective and exploded view of the lower portion of the assembly 116 of FIG. 6 but with a middle cap 138. The bottom view of the middle cap 138 is shown. FIG. 7B generally corresponds to FIG. 7A, but also shows the top view of the middle cap 138. (It is to be noted that reference to “top”, “bottom”, etc. in this specification refers to the relative position thereof, and is not intended to be limiting in terms of absolute orientation.) The bottom surface of the middle cap 138 is provided with three recesses 130a, 132a, 134a, respectively. It can thus be understood that cavities are provided or defined at the recesses 130a, 132a, 134a between the middle cap 138 and the wall 136. In this embodiment, three chambers are generally defined between the middle cap 138 and the three plungers 130, 132, 134. The three cylinders mentioned above correspond to these three regions. The three cylinders include two cylinders for fluid transfer and one cylinder for air or gaseous transfer. The three regions are region 140, region 142 and region 144.
The middle cap 138 at the region 140 is provided with a one-way valve 140a for allowing single direction fluid flow via an opening 140b from above to below across the middle cap 138. The middle cap 138 at region 140 is also provided with a one-way valve 140c for allowing single direction fluid flow via the opening 140d from below to above across the middle cap 138. FIG. 7B illustrates the working of the plunger 130. Please see the plunger 130 in hashed lines. The arrows illustrate that, when the plunger 130 is operated by the motor 126 via a wobbleable plate 146, fluid is caused to travel via the opening 140b from above to below across the middle cap 138, and then via the opening 140d from below to above the middle cap 138.
Region 142 of the middle cap 138 is similar to the region 140 in that the region 142 likewise is provided with the one-way valve 142a for allowing single direction fluid flow via the opening 142b from above to below across the middle cap 138. The middle cap 128 at the region 142 is provided with one-way valve 142c for allowing single direction fluid flow via the opening 142d from below to above across the middle cap 138. Flow of fluid in the region 142 is caused by the plunger 132 operated by the same motor 126.
Region 144 of the middle cap 138 is somewhat dissimilar to the regions 140, 142. Structurally, there is provided a one-way valve 144c (see FIG. 7B). Functionally, the one-way valve 144c is configured to allow single direction gas or air flow via an opening 144d from below to above across the middle cap 138. Although not shown in FIGS. 7A and 7B, the region 144 is provided with an air inlet 164 at the wall 136 for allowing air or gas to enter the chamber defined by or between the middle cap 138 and the plunger 134.
It can thus be understood that, due to the presence of two chambers corresponding to the regions 140, 142, two fluid flow paths are defined by the assembly 116. It can also be understood that, due to the presence of one chamber corresponding to region 144, one air or gaseous flow path is defined by the assembly 116. The two fluid chambers and the one air/gas chamber and the respective plungers 130, 132, 134 can thus be understood as the three-cylinder arrangement.
FIG. 8A are two schematic diagrams, namely left and right, illustrating two states of the region 140 of the middle cap 138 shown in FIG. 7A, when the assembly 116 is in operation. Specifically, FIG. 8A right shows the top view of the middle cap 138 while FIG. 8A left the bottom view of the middle cap 138 in operation.
FIG. 8B and FIG. 8C are two schematic diagrams corresponding to FIG. 8A right. It is to be noted that FIG. 8B and FIG. 8C show not only the assembly 116 of FIG. 7A and FIG. 7B but also the assembly 116 with a top cap 148. As such, FIGS. 8B and 8C further illustrate chambers defined between the top cap 148 and the middle cap 138, and fluid communication from the container 114 via the first pipeline 118 then to successive chambers. From FIG. 8B, it can be understood that the middle cap 138 and the top cap 148 together defines a chamber 150 therebetween. As fluid is drawn from the container 114 via the first pipeline 118 to the assembly the 116, the fluid firstly arrives the chamber 150. The grey area in FIG. 8A right illustrates the upper surface of the middle cap 138 and the zone between the top cap 148 and the middle cap 138 when the chamber 150 is filled with the fluid. The assembly 116 is also provided with a chamber 152 and a chamber 154 between the middle cap 138 and the wall 136. The chamber 152, 154 are the zones between the middle cap 138 and the wall 136. The assembly 116 is constructed such that the fluid in the chamber 150 can then travel and fork off via the opening 140b and 142b to the chamber 152 and the chamber 154, respectively. The arrows in FIGS. 8B and 8C illustrate the fluid flow pattern when the assembly 116 is in operation. The grey area in FIG. 8A left illustrates the chambers 152, 154 filled with the fluid travelled from the chamber 150.
FIG. 9A are two schematic diagrams, namely left and right, illustrating two states of the middle cap 138 shown in FIG. 7A when the assembly 116 is in operation.
FIG. 9B and FIG. 9C are two schematic diagrams corresponding to FIG. 9A left, illustrating fluid communication from the chambers 152, 154 to the nozzles 122, 124, respectively. From FIGS. 8A-8C, after the fluid has reached chambers 152, 154, continuous working of the plungers 130, 132 will drive the fluid away chamber 152, 154 via the openings 140d, 142d and then the valves 140c, 142c, respectively. The fluid will then exit the nozzles 122, 124, respectively. The nozzles 122, 124 are arranged on or extended from opposite lateral sides of the upper cap 148. The arrows in FIG. 9C illustrate the subsequent fluid flow pattern when the assembly 116 is in use.
FIG. 10A is a schematic diagram illustrating a state of the middle cap 138 shown in FIG. 7A. FIG. 10B is a schematic diagram corresponding to FIG. 10A illustrating air or gaseous communication path from the surrounding to the second pipeline 120. A chamber 160 is provided at the region 144 between the top cap 148 and the middle cap 138, as represented by the zone in the grey in FIG. 10A. FIG. 10B shows an air inlet 164 at the wall 136 for allowing entry of surrounding gas or air, a one-way valve 144c for controlling the state of an aperture 144d at the middle cap 138 thus to control entry of surrounding gas to the chamber 160, and a one way-valve 162 for controlling the air or gas to travel from the chamber 160 to the container 114 via the pipeline 120. The arrow in FIG. 10B illustrates the air flow path.
FIG. 11 and FIG. 12, corresponding to FIG. 9C and FIG. 10B, respectively, are schematic diagrams illustrating simultaneous fluid flow and gas/air flow when the assembly 116 is in operation.
In order to further explain the structure and working of the assembly 116, FIGS. 13A-13B and 14A-14B illustrate the schematics of the assembly. FIGS. 13A-13B and 14A-14B should be reviewed together with at least FIG. 7A for ease of understanding.
Generally, FIGS. 13A-13B illustrate two configurations of a fluid transfer mechanism in the assembly 16 when fluid transfer in the assembly is taking place.
FIG. 13A illustrates the assembly 116 including the chamber 150 and the pipeline 118 for supplying fluid to the chamber 150 and then separately to the chamber 152 and the chamber 154. The chamber 150 is provided with the one-valve 140a for controlling the state of the aperture 140b and the one-valve 142a for controlling the state of the aperture 142b.
The chamber 152 is provided with a sub-chamber 152a extended therefrom and the one-valve 140c for controlling the state of the aperture 140d. The sub-chamber 152a is further provided with a spring-loaded valve 156 for controlling an aperture 156a before fluid exits for the nozzle 122.
Similar to the chamber 152, the chamber 154 likewise has a sub-chamber 154a extended therefrom and the one-valve 142c for controlling the state of the aperture 142d. The sub-chamber 154a is further provided with a spring-loaded valve 158 for controlling an aperture 158a before fluid exits for the nozzle 124.
FIG. 13A shows the assembly 116 in a first configuration. In this configuration, when the plunger 130 for the chamber 152 is caused by a first end of the wobbleable plate 146 to assume a low position, a suction effect (i.e. a drop in pressure) is generated, causing the one-way valve 140b to open so as to allow fluid to travel from the chamber 150 to the chamber 152 via the aperture 140b. At the same time, the suction closes the one-way valve 140c.
While the plunger 130 for the chamber 152 is caused by the one end of the wobbleable plate 146 to be in the low portion, the plunger 132 for the chamber 154 is caused by a second end of the wobbleable plate 146 to assume a high position. As a result, a blowing effect (i.e. an increase in pressure) is generated, causing the one-way valve 142a to close, and the one-way valve 142c and the spring loaded valve 158 to open, so as to allow fluid to travel from the chamber 154 to the sub-chamber 154a then to the nozzle 122 via the aperture 142c and then the aperture 158a.
FIG. 13B shows the assembly 116 in a second configuration. In this configuration, when the plunger 130 is now caused by a third end of the wobbleable plate 146 to assume a high position, a blow effect is generated, causing the one-way valve 140a to close and the one-way valve 140c and the spring-loaded valve 156 to open, so as to allow fluid to travel from the chamber 152 to the sub-chamber 152a then to the nozzle 122 via the aperture 140d and the aperture 156a. It can be envisaged that the wobbleable plate 146 has a three-prong profile, with the three prongs engaged with the plungers 130, 132, 134, respectively.
When the plunger 130 is caused by the first end of the wobbleable plate 146 to assume a high position, the plunger 132 is now caused by the second end of the wobbleable plate to assume a low portion. As a result, a suction is generated causing the one-way valve 142d to open so as to allow fluid to travel from the chamber 155 to the sub-chamber 154 via the aperture 142b. At the same time, the suction closes the one-way valve 142c.
As the wobbleable plate 146 connected to the plungers 130, 132 reciprocatingly and alternatingly pushes and pull, the plungers 130, 132 assume alternating positions thus pumping fluid through the pipeline 118, then to chamber 150, then forking off to the chambers 152, 154, then to the sub-chambers 142a and 154a, and eventually reaching the nozzles 122, 124, respectively.
FIGS. 14A-14C show three configurations of an air or gas delivery mechanism in the assembly 116 for equalizing pressure in the container 114 when the assembly 116 is in operation. Specifically, FIGS. 14A-14C show that the assembly 116 includes the chamber 160 defined between the top cap 148 and the middle cap 138, the plunger 134 for operating the chamber 160, the inlet 164 leading to the chamber 160, the one-way valve 144c for controlling surrounding air or gas to enter the chamber 160, the one-way valve 162 for controlling the air to travel from the chamber 160 to the container 114 via the pipeline 120.
FIG. 14A illustrates a first configuration of the pressure equalizing mechanism in which the plunger 134 is in its low position. This low or initial position of the plunger 134 generates a suction and causes the both the one-way valves 144c, 162 to close while the inlet 164 is open.
FIG. 14B illustrates that as the plunger 134 is upwardly moved by the first end (or prong) of the wobbleable plate 146, an initial pumping effect is generated and as a result the inlet 164 is closed while both the one-way valves 144c, 162 are open.
FIG. 14C illustrates that once both the one-way valves 144c, 162 are open, lower or negative pressure in the chamber 160 causes the inlet 164 to also open, allowing air to travel from the surrounding into the container 114 such that pressure lost in the sealed liquid container is replenished. As the plunger 134 is reciprocatingly operated by the wobbleable plate 146, pressure in the container 114 is continuously replenished and maintained. It is to be understood that the displacement volume of the gas cylinder made from the chamber 160 does not need to match the displacement volume of the liquid cylinders made from the chambers 150, 152, 154 because due to the negative pressure a respective amount of air will be automatically drawn into the sealed liquid detergent container 114 until the pressure is equalized.
It is to be noted that all three plungers 130, 132, 134 are alternatively operated by these distal ends (or prongs) of the wobbleable plate 146. Thus, when the assembly 116 is discharging liquid from the sealed liquid container 116 via the conduits 122, 124, pressure drop in the sealed liquid is being replenished and fluid flow from the container 114 to the chamber 150 would not be hindered.
FIG. 15A and FIG. 15B correspond to FIG. 2 and FIG. 4, respectively, but are presented side for side for ease of comparison. FIG. 15A represents the liquid delivery means 16. In this means 16, three discrete units, i.e. the pump B, the diverger C, and the valve means F, are separately provided. With this configuration, while the pump B is actively operated, the diverger C and the valve means F are passively operated.
FIG. 15B represents the liquid delivery assembly 116. In this assembly 116, the pump B′, the means for diverging fluid to the conduits D′, E′ and the valve means F′ are integrally formed. In other words, they are parts of a discrete unit. For example, the assembly 116 provides a number of cylinders and chambers separated by partitions and operation of the cylinders and fluid flow and air flow in the integral assembly 116 is effected by one motor. Further, the floor cleaning portion 104 does not have any diverger for channeling fluid to the two nozzles 106, 108. The diverging function is already provided by the integral assembly 116 installed in the upstanding portion 110 of the apparatus 102. Leakage of fluid is prevented by way of the independent valves 140d, 156, 142c, 158 in the assembly 116 in the upstanding portion 110 despite no additional check valve is provided in the floor cleaning portion 104 is needed. With this configuration, the assembly 116 can thus be made to be more compact and installation of the assembly 116 to the rest of the apparatus 102 from an industrial engineering point of view is technically more efficient.
In the above embodiment, the assembly 116 generally assumes the three-cylinder arrangement with partitions (e.g. the top cap 148, the middle cap 138, etc.) and the chambers (e.g. the chambers 150, 152, 154, 160, etc.) arranged adjacent each other. The three-cylinder arrangement is formed into a larger cylindrical configuration. However, the present invention encompasses alternative embodiments. For example, the three chambers 152, 154, 160 can be arranged in a radial configuration. As a further example, the three chambers 152, 154, 160 can be arranged linearly or in a V-shaped manner. Further, other alternative embodiments are possible when only two liquid cylinders (operable by one motor) are needed, when only one liquid cylinder and one air/gas cylinder (operable by one motor) are needed, and/or when three liquid cylinders are needed.
In the above embodiment, the wobbleable plate 146 acts as a pivotably movable actuator on the plungers 130, 132, 134. In alternative embodiments, other forms of actuator for providing reciprocating or vibratable motion to the plungers 130, 132 driven by the motor 126 will also work.
In the above embodiments, the plungers 130, 132, 134 act as diagram pumps to effect the fluid and air/gas flow. It is envisaged that other types of diagram pumps or pumps would equally work.
FIGS. 13A-13B show that the chamber 150 is situated above the chambers 152, 154. However, in other embodiments, the chamber 150, for example, may be situated at an adjacent side of the chambers 152, 154.
While the above has illustrated one embodiment of a floor cleaning apparatus comprising the first embodiment of the liquid delivery assembly 116, FIGS. 16A to 25B illustrate a second embodiment of a liquid delivery assembly 316 according to the present invention. The following seeks to depict the configuration of this alternative assembly 316. For sake of brevity and ease of understanding, the following focuses on comparing the assembly 316 with the first embodiment 116 and thus the differences. As such, the construction of the assembly 316 should be understood in light of the construction of the assembly 116.
FIG. 16A illustrates the overall construction of the second embodiment of the liquid delivery assembly 316, while FIG. 16B is an exploded view of the assembly 316. One main difference is that unlike the assembly 116 having the two separate pipelines, namely the pipeline 118 and the pipeline 120 defining two respective channels, the assembly 316 has only one single needle 319 with an elongate body having or defining two passageways, namely passageway 318 and passageway 320 adjacent but separated from the passageway 318. Nevertheless, the passageway 318 is similar to the pipeline 118 of the assembly 116 in that the passageway 318 likewise acts as a route for transporting liquid from the liquid container through the assembly 316, and the passageway 320 acts as another route for transporting gas or surrounding air through the assembly 316. It is to be noted that while both the passageways 318 and 320 share the same body of the needle 319, they are separated by a wall 319a and they similarly lead to different chambers of the assembly 316, as in the assembly 116.
As illustrated in at least FIGS. 16A-16B and 19C, in this embodiment the needle 319 has a certain configuration. First, the needle 319 is not a conventional needle having a cylindrical body. Instead, it has a flattened configuration with a width wider than its thickness. The flattened configuration is more apparent when the transverse cross section of the needle 319 is envisaged. This structure is understandable because both the passageways 318 and 320 which are substantially cylindrical run or otherwise are arranged in parallel side by side. Second, as more clearly shown in FIGS. 16A and 19C, the needle 319 extended from a top end of the remaining portion of the assembly 316 and has a wider base. The needle 319 tapers towards its upper end. Towards the upper end of the needle 319, the passageways 318, 320 end with two openings 318a, 320a, respectively. The needle 319 at the two openings 318a, 320a is further provided with a cut-out region, thus defining a pointed-tip. The following table summarises some physical parameters of the needle 316 of this embodiment.
TABLE 1
|
|
Physical parameter of the needle of assembly 319
|
Characteristics
Parameters
|
|
Length of the needle at its base
20-22 mm
|
Width of the needle at its base
6.0-7.5 mm
|
Thickness of the needle at its base
3.0-4.5 mm
|
Width of the needle at where openings begin
5.0-6.0 mm
|
Thickness of the needle at where openings begin
1.5-2.0 mm
|
Diameter of the passageways 318, 320
1.8-2.5 mm
|
Thickness of wall in the needle between
0.9-1.6 mm
|
the passageways 318, 320
|
Width of the needle at its pointed-tip
1.5-1.5 mm
|
Material of needle
POM, nylon, or non-metal
|
|
It is to be noted that although both passageways 318, 320 reside in the needle 319 and in use the openings 318a, 320a are in fluid communication with a liquid storage container, the other ends of the passageways 318, 320 extend and lead to separate and liquid and gas/air chambers, respectively.
Similar to FIG. 6, FIG. 17 is a perspective view of a lower portion the assembly 316 of FIG. 16A but with its housing removed. In this figure, three plungers 330, 332, 334 are more clearly shown. There is provided a wall 336 defining a lower surface to which the top of the three plungers 330, 332, 334 engage and connect. The plungers 330, 332, 334 are operable by a wobbleable plate 346 which is movable by an axle of the motor 326. In this embodiment, the motor 326 has a power output of 1.5-4W.
FIGS. 18A, 18B & 1861, 19A & 20A, 19B & 1961, 19C, 20B, 20C & 20C1, 21A & 21A1, 22A & 22A1, 23A & 23A1, 24A, 24B, 25A and 25B of the assembly 316 generally correspond to, and should be understood in view of, FIGS. 7A, 7B, 8A & 9A & 10A, 8B, 8C, 9B, 9C, 10B, 11, 12, 13A, 13B, 14A and 25B of the assembly 116, respectively.
FIGS. 18B & 18B1 illustrate one route of flow of liquid within the assembly 316 and especially at the plunger 330. FIGS. 19B, 19B1 & 19C illustrate more elaborately two routes of flow of liquid within the assembly 316. FIGS. 20C and 20C1 illustrate, more elaborately the two routes of flow of liquid within the assembly 316. FIGS. 20C & 20C1 and 22A & 22A1 illustrate, even more elaborately the two routes of the flow of liquid within the assembly 316.
FIGS. 19A & 20A are cross section views illustrating, during operation, filling of liquid in cavities of the assembly 316.
FIG. 20B is a cross section view taken across plate a middle cap 338. Please see FIG. 19B.
FIGS. 21A & 21A1 illustrates a path of air flow from the surrounding via the assembly 316 to the liquid container for pressure equalization.
FIGS. 23A & 23A1 illustrate route of flow of gas or surrounding air within the assembly 316 and especially at the plunger 334.
Another difference between the assembly 316 and the assembly 116 is that each of chamber 352 and chamber 354 of the assembly 316 is additionally provided with a damping device (or damper) (402/404). Referring to FIGS. 16A-16B, 18A-18B, 19B-19C, 20C, 21A, 22A and 23A. The damping device (402/404) is in the form of an elongate tubing which has an expandable wall with one closed end and an open end and is in fluid communication with the chamber (352/354), and is hanging from the chamber 352/354. In this embodiment, the damping device is made from a soft resilient plastic(s), suitable material candidates of which include silicone rubber, ethylene propylene diene monomer (EPDM) or thermoplastic polyurethane (TPU). With this configuration, the volume (and its capacity) of the damping device (402/404) is slightly increased when subjected to an elevated internal liquid pressure. In a specific embodiment, the internal diameter, external diameter and length of the elongate tube is 3.6-4.4 mm, 5.4-6.6 mm and 27.45-33.55 mm, respectively. In a more specific embodiment, the internal diameter, external diameter and length of the elongate tube is 4 mm, 6 mm and 30.5 mm, respectively. However, as long as a damper can expand slightly when subject to elevated internal fluid pressure and resume to an unexpanded configuration after the elevated pressures, such a damper is suitable. When the elevated internal liquid pressure is reduced in between pumping cycles, the damping device (402/404) will return to its default or non-expanded state and prolongs pumping of fluid to the nozzles. In other words, the damping device (402/404) acts as a pressure capacitor and enhances pumping efficiency and effectiveness. It can be understood that on conventional systems, when liquid is being pumped for discharges during successive pumping cycles, liquid discharged often behaves in a successive squeaking pattern. This is undesirable because the discharged liquid is not in the form of a continuous stream. To the contrary, the provision of the damper (402/404) prolongs the discharge of liquid from each pumping motion, thus effectively connecting successive discharge of liquid effecting forming a continuous liquid stream.
FIGS. 24A & 24B of the assembly 316 correspond to FIGS. 13A & 13B of the assembly 116. While the assembly 316 similarly provides one-way valves 340a, 342a for controlling apertures 340b and 342b, these one-way valves 340a and 342a are flip valves and not disc valves. Further, the assembly 316 provides spring-loaded valves 356 and 358 for controlling exit liquid to first and second nozzles, respectively, and not both disc valves and spring-loaded valves as in the assembly 116. Yet, further, as illustrated above, the chambers 352 and 354 are provided with the damping devices.
FIGS. 25A & 25B of the assembly 316 correspond to FIGS. 14A & 14B of the assembly 116. While the assembly 316 similar provides mechanism for controlling one-way flow of gas or surrounding air to the liquid container, the mechanism includes one inlet 364 and one disc-valve 362, and not one inlet, one disc-valve and one nozzle valve.
While the alternative embodiment of the assembly 316 is functionally equivalent to the assembly 116 in many ways, it has its own structural and functional characteristics. First, with the use of one single needle 319 and not separate two pipelines, the assembly 316 when engaging with the liquid container only requires puncture by the single needle 319 at one location and not two locations. This can reduce risk and/or extent of leakage from or surrounding the puncture region. From a manufacturing point of view, the use of one single needle can increase sturdiness of the one needle and/or decrease production cost.
Further, as discussed above, the damping device (402/404) can store energy or pressure when fluid is being pumped from the chamber (352/354). Then even when fluid is stopped being pumped in between fluid pumping cycles, the device (402/404) can release pressure by prolonging the pumping of remaining fluid. This can increase and/or prolong the flow rate for discharge at the nozzles. Experiments leading to the present invention have demonstrated that the flow rate of liquid discharging from the assembly 316 can reach as high as 550 ml (per minute?) or at least a workable range of 350-550 ml/minute.
It should be understood that certain features of the invention, which are, for clarity, described in the content of separate embodiments, may be provided in combination in a single embodiment. Conversely, various features of the invention which are, for brevity, described in the content of a single embodiment, may be provided separately or in any appropriate sub-combinations. It is to be noted that certain features of the embodiments are illustrated by way of non-limiting examples. For example, the first embodiment of the liquid delivery assembly 116 of a floor cleaning apparatus may be replaced by a second embodiment of the liquid delivery assembly. Further, an arrangement with two sealed liquid containers and two fluid cylinders, respectively, both operable by one motor may be provided such that two streams of different fluids can be delivered and then combined to form a formulation therefrom for discharge.
Patent Application
20230389770
