The present invention relates to a ventilated work station. In the context of this invention a work station will be illustrated as a manicure or nail salon workstation. More specifically, the present invention relates to an improved nail salon workstation that includes integrated dust, debris and fume collection, VOC exhaust, and ventilation, as well as a modular design that allows multiple workstations to be installed in an adjoined manner.
In the salon industry, it is common to carry out the treatment of nails at a nail salon workstation where a technician employs a convenient table top working area that allows the customer to rest their hands while the technician carries out a procedure on the nails, such as a manicure etc. In many of the procedures carried out on the nails, there is a need to grind or file the nails or a plastic overlay applied to the nails in order to shape them into the desired configuration. The grinding process creates dust from the nails that is harmful to the health, safety and welfare and is readily inhaled by the technician and/or customer. In addition, there are normally fumes, consisting of toluene, formaldehyde and acetone, that are created in the course of a manicure such as those emitted by acrylic materials that are applied to the finger nails. Such fumes have been proven harmful if inhaled by the technician or customer.
As a result, professional manicure salons are now required to install source capture systems per the International Mechanical code and other health codes to protect both employees and customers from exposure to manicure by-products. Successful control of by-products requires that the VOC fumes be captured from the work area at the source of application and exhausted.
Exhaust and filtration systems have been used as a means to mitigate solvents, in an attempt to comply with air quality regulations. However, exhaust and filtration systems do not comply with current safety regulations because they recirculate the fume laden air back to the work space and end up mixing the fresh air with the contaminated air. They require diligence in maintenance, filtration changes and regular cleaning. Also, these small systems are not integrated with the manicure workstation and appear to interfere with or restrict the manicurist's work, they are noisy and they are cumbersome which generally leads to a reluctance to use them .
For example, some systems employ a hood over the work station. However, the presence of a hood is a significant inhibitor to the close attention that is required for good quality manicure work, and the presence of a laboratory-style hood can discourage and drive away customers. Ultimately, the currently available systems and hoods all are undesirable because of their negative impact customers and on the manicurist trade. The clearest problem is the visual impact or fear factor caused by technical equipment on display and the lack of compliance with the various health and mechanical regulations. Manicurists strive to make their shops warm and inviting, rather than cold and technical. It would be desirable for a manicure workstation to minimize or eliminate signs of technical equipment in use. While the use of air cleaning equipment is environmentally helpful, the equipment should take advantage of existing support structure in the manicure salon to operate optimally with minimum imposition on the manicurist and customer.
There is therefore a need for a robust source capture ventilation system in a manicure table, employing table geometry to create high efficiency in debris, fume and odor removal while supplying fresh air back into the space in an energy efficient manner. There is a further need for a robust source capture ventilation system in a manicure table, employing table geometry to create high efficiency in debris and odor removal that provides a modular implementation such that the necessary equipment is not a single custom bespoke installation and can be used universally. There is still a further need for a robust source capture ventilation system in a manicure table, employing table geometry to create high efficiency in debris and odor removal that collects the particulate debris while venting the harmful fumes outside the work area while also bringing in fresh outdoor make-up air.
In accordance with the present invention, a modular manicure ventilation station is provided that employs the station geometry to create high efficiency debris and VOC removal and simultaneous delivery of fresh, preconditioned make-up air. The station may be of pre-existing or typical design in which it is formed of one or more substantially vertical support pedestals and a substantially horizontal manicure work surface that positioned above the pedestals. An integrated air cleaning system operates on air flowing in a flow path having a slot inlet substantially surrounding the entire work surface on all sides. The slot inlet is positioned above a plenum that forms the space beneath the work surface to channel airflow into a manifold that runs along one side of the table and is in communication with the plenum beneath the work surface. An air duct having an inlet end and a discharge end is connected to the manifold where the inlet end communicates with the plenum and manifold leads laterally into the pedestal to a fan or other suitable collection device outside the work area.
It should be appreciated that while a manicure workstation is described, the teachings herein can apply to any workstation wherein VOC and other toxic fumes are generated such as for example soldering workstations, chemical workstations. Accordingly, the term workstation is meant to encompass any type workstation and is not meant to be limited to manicure or salon type environments.
In one embodiment, as the table exhausts a volume of air, code requires that make-up air (not recirculated air) be provided to the space to maintain air pressure balance in the space. In this arrangement a return duct for makeup air is run concentric with the exhaust duct in a manner that facilitates heat transfer from the conditioned room air to the incoming make up air. This allows the make-up air to be brought into temperature equilibrium using the energy from the exhaust air as they exchange heat through the common duct walls or heat exchange plate.
A particle collector bag may be positioned in the airflow path. The collector may be in the slot inlets at the work surface. Further the, collector may be positioned at any location suitable and easily serviceable for cleaning and the like.
The flow path is contoured with relative cross-sectional areas to establish, in use, relatively high air flow velocity through the duct to produce a high rate of debris removal from the work surface and to establish relatively low air flow velocity through the particle collector bag and filter bed to produce high removal rate of particles and odors in these elements.
The manifold at the end opposite the air duct may be plugged to prevent air leakage. Similarly the manifold plug may be removed to allow the connection to another workstation such that a plurality of such workstations can be connected together in series to a single airflow fan source. The various components of the present vacuum system fit into a space positioned outside the work area in a hidden manner such that the overall work station remains neat and uncluttered and the system is sufficiently powerful that fumes and nail dust created at the working area where the nail procedure is being carried out on the customer are effectively removed and yet the present vacuum system is located in an area outside the work space so that it is quiet and does not disturb the surrounding area.
Accordingly it is an object of the present invention to provide a robust cleaning system in a manicure table, employing table geometry to create high efficiency in debris and odor removal. It is a further object of the present invention to provide a robust cleaning system in a manicure table, employing table geometry to create high efficiency in debris and odor removal that provides a modular implementation such that the necessary equipment is not a single custom bespoke installation and can be used universally. It is a further object of the present invention to provide a robust cleaning system in a manicure table, employing table geometry to create high efficiency in debris and odor removal that collects the particulate debris while venting the harmful fumes outside the work area.
In the drawings which illustrate the best mode presently contemplated for carrying out the present invention:
Now referring to the drawings, a modular manicure station is shown and generally illustrated in the figures. As can be seen at
It should be appreciated that while a manicure workstation is described, the teachings herein can apply to any workstation wherein VOC and other toxic fumes are generated such as for example soldering workstations, chemical workstations. Accordingly, the term workstation is meant to encompass any type workstation and is not meant to be limited to manicure or salon type environments.
The base 12 may work in conjunction with an end panel 16 such that the base 12 is at one end of the manicure station 10 while an additional support end panel 16, leg or legs is provided at the opposing end of the manicure station 10, thereby supporting the work surface 14 therebetween. A space 18 is provided beneath the work surface 14 to allow a person seated at the manicure station 10 to position their knees therebeneath such that their hands will rest comfortably on the upper surface of the work surface 14 for the manicure procedure. The base or pedestal 12 may include compartments 20, shelves or drawers therein to allow storage of the technician's belongings, tools and supplies as well as providing space to display manicure products and other salon products that may be offered for sale.
In a preferred embodiment, the modular manicure station 10 is provided with an upper work surface 14 that is configured to create a high efficiency debris and odor removal system. As will be described in further detail below, the upper work surface 14 includes an integrated air cleaning system that operates on air flowing in a flow path having an inlet 24 within the upper work surface 14. More preferably, the upper work surface 14 has a slot inlet 24 that surrounds the periphery of the work area 26 along all of its sides. Alternately the upper work surface may have a grated inlet 25 that forms the entire work area. Beneath the inlet slot 24 or grate 25 may be provided a damper or baffle 27 to control and/or balance the airflow volume and velocity at the inlet.
Turning now to
A particle collector bag or filter 23 may be positioned in the airflow path. The collector may be in the slot inlets 24 at the work area 26. Further the, particle collector 23a may be positioned at any location suitable and easily serviceable for cleaning and the like. Similarly, the bag or filter may include filtration media that is intended to serve as a means from scrubbing the various evaporated solvent fumes and other airborne VOC from the airflow prior to the discharge of the air to the exterior of the work space.
The flow path, illustrated at
As depicted at
In one embodiment, as the manicure station 10 exhausts a volume of air, code requires that make-up air be provided to the space to maintain air pressure balance in the space. In this arrangement a return air duct 135 for makeup air is run concentric with the exhaust duct 34 in a manner that facilitates heat transfer from the conditioned room air to the incoming make up air. There can be seen a return manifold 133 adjacent the exhaust manifold 32 such that they share a common side. Preferably this side is configured and arranged to facilitate heat transfer via a heat transfer plate 136 that allows energy to be captured from the conditioned air being exhausted and transferred to the incoming makeup air. One skilled in the art can appreciated that this process may be a heating or cooling of the incoming make up air as the environmental conditions require. This allows the make-up air to be brought into temperature equilibrium using the energy from the exhaust air as they exchange heat through the common duct walls or heat exchange plate. Alternately the heat exchange bay be done using a remote heat exchange unit 135. The make-up air is then discharged into the space via a make-up air diffuser 124 positioned on the make-up air manifold 133.
It can therefore be seen that the present invention provides a robust cleaning and ventilation system in a manicure table, employing table geometry to create high efficiency in debris and odor removal while providing a conditioned make-up air return that completes the full ventilation process. It can be further seen that the present invention provides a robust cleaning and ventilation system in a manicure table, employing table geometry to create high efficiency in debris and odor removal that includes a modular implementation such that the necessary equipment is not a single custom bespoke installation and can be used universally. For these reasons, the instant invention is believed to represent a significant advancement in the art, which has substantial commercial merit.
While there is shown and described herein certain specific structure embodying the invention, it will be manifest to those skilled in the art that various modifications and rearrangements of the parts may be made without departing from the spirit and scope of the underlying inventive concept and that the same is not limited to the particular forms herein shown and described except insofar as indicated by the scope of the appended claims.
This application is related to and claims priority from earlier filed U.S. Provisional Patent Application No. 62/310,071, filed Mar. 18, 2016.
Number | Date | Country | |
---|---|---|---|
62310071 | Mar 2016 | US |