TR201809557T4 - Air conditioner. - Google Patents

Abstract

Wind noise is suppressed by limiting a vortex flow distortion. At a front end portion of at least one of a stabilizer (32) and a rear guide (20), the first different level portions (28a to 28c) and each of which are reduced in the axial direction towards a central portion (M) of a fan (10); The second different level portions 28d and 28e, in which the height of one increases in the axial direction towards the central portion M of the fan 10, are formed to be aligned in the axial direction. At a predetermined length in the axial direction, the height variation of at least one of the first different level portions 28a to 28c is equal to a predetermined first value which is smaller than the height variation of each of the second different level portions 28d and 28e.

Description

DESCRIPTION INLET FILTER CONNECTION BACKGROUND OF THE INVENTION Invention Field Embodiments of the invention are inlet strainer connectors.

Description of Related Art Water harvesting systems are typically found in factories, cities, irrigation systems, and a river, lake. endpoints, such as power generation facilities located near salt water sources or It is used to supply water to the users. End users like this system type water well. can use it as an alternative to opening it or purchasing water from a municipality. Moreover, use of these systems, water from municipal supply and/or pumps such as remote locations in remote locations where electrical power is not available to operate can be determined by the location of the end user. These water collection systems are suitable for different conditions. It has the feature of adapting and presenting water effectively and economically.

These water collection systems typically deliver water to the end user adjacent to the water source. an inlet pipe arranged to carry water from a submerged location at its source uses. An inlet pipe is immersed in a water source, and the end of the inlet pipe is usually It is connected to an input filter connection that contains several filtering elements. Filtering elements of water pollution and the entry of a certain size of aquatic living things. prevents it from entering the pipe.

A common inlet strainer connection is usually a cap at one end and a pipe at the other. Includes large cylindrical filters with connection. Wide inlet strainer connections A typical construction for such as flat plates, cones, or cambers on the distal ends of the sieve cylinder. It is a flanged tee with hard caps. Individual components of connections are often combined originates.

The material used to manufacture the individual components is usually stainless steel. However, material of choice in the presence of certain aquatic animals such as zebra mussels is a copper-nickel alloy. Copper nickel alloys are more expensive than stainless steel since only the strainer part is made of copper-nickel and the rest of the connection It is preferable to provide a hybrid connection made of stainless steel.

US 6036850 A describes an inlet strainer connection with the rationale features of claim 1 and especially users, zebra mussels, zebra mussels and eggs infiltration into drinking water systems with inlet pipes located in surface waters. A filtration for zebra mussels consisting of a unit designed to provide explains the system. The filtration system consists of a folded-in micron filter, a middle cable. It consists of several filters including a frame and a non-metallic strainer.

Traditionally, hybrid coupling produces a copper-nickel cylindrical strainer and it is made by not being able to bolt it to the rest of the stainless steel components. Regarding the hybrid connection There are two possible problems. First, the copper-nickel material is as much as the stainless steel material. In high loading situations, the cylindrical strainer is important because it is not strong. support is required. Supporting can increase production cost and complexity. must be designed to transfer via bolts. Second, the cylindrical strainer is separated into two separate seals and seals to prevent metal contact, thus preventing galvanic corrosion. Bolt to stainless steel components using insulating sleeves. this appendix corrosion protection measures can also increase production cost and complexity.

Thus, there is a need for new and improved hybrid strainer connections.

BRIEF DESCRIPTION OF THE INVENTION According to claim 1, an input element; a filter support element connected to the inlet element. an inlet filter connection comprising; a strainer element connected to the strainer support is explained, where the strainer support element and the strainer element are made of different materials; several strainer panels (40) of the strainer element, the strainer support element and the strainer Strainer to prevent direct surface contact between the different materials of the element. a snap connection between the support element and the strainer element and a Strainer retained by strainer support element using corrosion protection element characterized by the element

The inlet element and/or the strainer support element may be made of stainless steel and the strainer element can be made of copper-nickel.

connecting a strainer support member according to claim 13 to an inlet member; and one an input filter that includes binding the filter element to the filter support element explains the method of creating the connection. Filter support element and filter element are different can be made of materials.

In one embodiment, an input filter connection includes an input element; to an input element includes a connecting support structure, wherein the support structure includes multiple peripheral supports; and of the support structure from a first end of the support structure to a second end of the support structure. many flats connected to circumferential supports that run in a zig-zag pattern along its circumference. at least; and several attached to the support structure for filtering the fluid flow to the inlet element. contains the filter element.

BRIEF DESCRIPTION OF THE FIGURES Thus, the way in which the above-mentioned features of the invention can be understood in more detail, A more specific description of the invention briefly summarized above, some in the accompanying figures may be cited by reference to the embodiments shown. However, the invention is equally effective in other The accompanying figures represent typical embodiments of the present invention, as and therefore should not be regarded as limiting its scope. should not be forgotten.

Figure 1 shows an inlet filter connection according to one embodiment.

Figures 2A and 28 show a support structure according to one embodiment.

DETAILED DESCRIPTION Figure 1 shows an inlet filter connection 100 according to one embodiment. Input filter connection (100) in the form of an input element or a central, flanged t-piece (10) a body shown in the form of a cylindrical lattice structure (20) the strainer support element with a cover shown in the form of a circular plate structure (30). and a filter element shown in the form of a curved filter panel (40). includes. The right side of the inlet strainer connector (100) is the lattice structure (20) at the foundation and the t- The strainer removed to show its connection to the part (10) and the plate structure (30) panels (40). Left side of inlet strainer connector (100), apparently with the strainer panels (40) attached to the outer surface of the concealed opposite lattice structure (20). is displayed.

The inlet strainer connection (100) is one or more strainers with many advantages. It uses a separate filter support element that supports the element. Support a separate filter Using the element, the filter elements significantly remove the input filter structure. can be easily changed without having to Also, the filter support element filter Significantly stronger than the material used to form the elements and/or a more cost-effective material. The strainer support element is also high loading as well as supporting one or more filter elements can provide a rigid base structure that can withstand loads. So the filter elements important benefits to the inlet strainer connection (100) such as preventing some aquatic life provides but does not require as much support strength as the remaining components of the link. can be made from many other materials.

Components of the inlet strainer connector 100 may be made of different materials or the same can be made of material. Components of metallic materials, non-metallic can be made of materials and composite materials. filter element, filter one or more stronger than the materials used to make the elements can be made of material. Components of the connection (100) of the inlet strainer add additional corrosion It can be made of different materials that do not require precautionary measures.

In one embodiment, the tee 10, the cage structure 20, and/or the plate structure 30 can be made of stainless steel material (such as 304 or 316 grade stainless steel) and The strainer panels 40 may be made of a copper-nickel material. stainless steel cage structure (20) and inlet made of different materials such as copper-nickel strainer panels (40). Appropriate corrosion protection measures when connecting the components of the strainer connection (100) can be used. Corrosion protection measures inlet strainer in different materials to avoid direct surface contact between the components of the connection (100) can be used. In one example, one or more of the adjacent surfaces of different material components more gasket types and/or washer type elements can be used. In another example. here To create Bolted connections with connection components from different materials described one or more of them to isolate the bolt/nut elements used for Insulation type sleeve can also be used.

T-piece (10) to support inlet strainer connection (100) when immersed in water supply and/or connect a flowline to provide a fluid connection to an end user and a cylindrical lower part (13). A cylindrical upper part (15) of the T-piece (10) to support lattice structures (20), plate structures (30), and strainer panels (40). can be provided. The lattice structures (20) are attached to the opposite ends of the upper part (15) of the tee (10). can be welded in a cantilever fashion and the plate structures (30) are opposing the lattice structures (20). can be welded to the ends. Other fastening mechanisms such as bolting inlet strainer may be used to interconnect the components of the connection 100.

Although shown as T-piece (10), the body of the inlet strainer connector (100) may include other configurations as well. In one embodiment, only the lattice of the stem connection it may be in the form of an L-shaped piece for supporting the structure 20 . A In the embodiment, the t-piece (10) is placed on top of the upper (13) horizontally or vertically. It may only include the lower part (13) to support an inserted cage structure (20).

Other configurations and shapes of the hull are in accordance with the embodiments described here. can be used.

The cylindrical lattice structure (20) includes many peripheral support elements (22) (such as ring elements). a plurality of bars (21) (or similar longitudinal support or support element). Additional bars referred to as supporting elements (23), can be provided along the inner and/or outer diameter of the cage structure (20). Supporting elements (23) examples, internal support available with the embodiments described here U.S. describing spiral ties It is disclosed in patent 7,950,527 . In one arrangement, The supporting elements (23) have a plurality of elements extending from one end of the cage structure (20) to the other. May contain spiral bar. In one embodiment, one end of the at least two supporting elements 23 can be attached to the t-piece (10) in substantially the same position. Supporting elements (23) It extends towards the plate structure 30, forming an angle between the two elements 23.

The support elements (23) should have the same contour as the drain panels (40). adjustable and since the elements (23) extend from the first end to a second end of the elements (23). the strainer may contact the panels (40). The second end of the supporting members (23) is the plate can be attached to the structure (30). The elements (23) are placed from one end of the lattice structure (20) to the other. can create a zig-zag pattern. Machining angles between supporting elements (23)

Claims (1)

REQUESTS . An input filter connector 100 comprising: an input element (10); a strainer support member (20) coupled to the inlet member; a strainer member connected to a strainer support member, wherein the strainer support member and the strainer member are made of different materials; The feature is a plurality of strainer panels (40) that are connected together to form a sleeve that is retained using a snap-fit connection around the strainer support member, and a corrosion located between the strainer support and the strainer member to prevent direct contact between the strainer support and the different materials of the strainer member. It is characterized by containing an element of protection. It is a connection according to claim 1, characterized in that the strainer support element is made of stainless steel and the strainer element is made of copper-nickel. Connection according to claim 1, characterized in that it also includes a cover element that is connected to a distal end of the strainer support element. It is a connection according to claim 1, characterized in that the strainer element is in the form of a sleeve that slides onto the strainer support element. It is a connection according to claim 1, characterized in that the inlet element is in the form of a flanged t-piece (10) and the strainer support element is in the form of a cage structure (20). Connection according to claim 1, characterized in that the strainer support element includes many more circumferential spiral or flat bar elements (21, 624). It is a connection according to claim 6, characterized in that the opposite ends of the bars (624) are connected to the outermost circumferential supports at different longitudinal positions. It is a connection according to claim 6, characterized in that the bars (624) do not touch at least one intermediate peripheral support located between the outermost peripheral supports. The connection according to claim 6, characterized in that the bars (624) are in contact with at least one intermediate peripheral support located between the outermost peripheral supports. It is a connection according to claim 6, characterized in that the bars (624) are located in a groove of at least one intermediate peripheral support located between the outermost peripheral supports. The connection according to claim 6, characterized in that the bars (624) extend to at least one intermediate peripheral support located between the outermost peripheral supports. A connection according to claim 6, characterized in that the bars are fixed to at least one intermediate peripheral support between the outermost peripheral supports with a clamp element. A method for forming an inlet filter connector (100) according to one of the preceding claims, comprising: connecting a filter support element to an input element; and attaching a strainer member to the strainer support, said strainer element in the form of a sleeve that slides onto the strainer support element to form a tight fit with the sleeve or bolted to the strainer support, wherein the strainer support and the strainer element are made of different materials; and provides a corrosion protection material between the strainer support element and the strainer element. The method according to claim 13, characterized in that the strainer element comprises several strainer panels and also includes connecting the strainer panels around the strainer support element in order to connect the strainer element to the strainer support element. It is a method according to claim 14, characterized in that the strainer panels are connected to each other to form a tight-fitting sleeve with the strainer support element or the strainer panels are connected to the strainer support element by using bolted connections. 16. The method according to claim 13, characterized in that the strainer support element is made of stainless steel and the strainer element is made of copper-nickel. Method according to claim 13, characterized in that the inlet element is in the form of a flanged t-piece (10) 5 and the strainer support element is in the form of a cage structure (20). 18. The method according to claim 13, characterized in that the strainer support element comprises a plurality of circumferential supports (22) and one or more helical 10 or flat bar elements attached to the circumferential supports (22).