CN110500471B - Horizontal ball water separator capable of sending out and receiving balls simultaneously - Google Patents

Abstract

The invention provides a horizontal ball-receiving-while-sending water separator, which comprises an outer cylinder, wherein a ball-receiving opening, a water outlet, a ball-sending opening and a water inlet are arranged on the side wall of the outer cylinder; the water inlet and the water outlet are both connected with a water inlet and outlet control valve, the water inlet and outlet control valve comprises an inner cylinder arranged in an outer cylinder, a partition plate for dividing the inner cavity of the inner cylinder into a first inner cavity and a second inner cavity which are mutually independent is arranged in the inner cylinder, two first through holes which correspond to the ball collecting port and the water outlet respectively are arranged on the side wall of the inner cylinder of the first inner cavity, and a ball water separation filter screen is arranged in the first inner cavity; two second ports corresponding to the ball service port and the water inlet are arranged on the side wall of the inner cylinder of the second inner cavity, and a ball water separation filter screen is arranged in the second inner cavity. Compared with the prior art, the water separator for receiving and sending balls simultaneously can realize synchronous ball sending and ball receiving, prevent the cleaning balls from being detained on the ball receiving net of the ball catcher, effectively improve the ball receiving rate, and has simple and reliable structure and low processing difficulty, and is suitable for cleaning by various cleaning machines.

Description

Horizontal ball water separator capable of sending out and receiving balls simultaneously

Technical Field

The invention relates to the field of rubber ball cleaning, in particular to a horizontal type ball-receiving-while-sending water separator.

Background

When the air conditioner unit or the condenser unit is cleaned, rubber balls are usually adopted for cleaning, the rubber balls need to be received and sent during cleaning, and a ball water separator is needed to be adopted for separating the rubber balls from water during ball receiving and sending, so that the rubber balls are recycled for cleaning. At present, the common ball water separators in the market are all of the type of first-release-later-release type, the ball water separators are used for recycling the rubber balls after all the rubber balls are released, the rubber balls are easy to be retained on the ball collecting net of the ball collecting device, and the ball collecting rate is low.

Disclosure of Invention

Aiming at the problems, the invention provides the horizontal type ball-sending and receiving water separator which can send and receive balls simultaneously, effectively improves ball receiving rate, has extremely low power, simple and reliable structure and low processing difficulty, and is suitable for end cover type cleaning machines, double-return pipeline type cleaning machines and single-return pipeline type cleaning machines.

The invention adopts the technical scheme that:

The horizontal ball-receiving water separator is characterized by comprising an outer barrel, wherein a ball-receiving port and a water outlet are formed in one side wall of the outer barrel, and a ball-serving port and a water inlet are formed in the other side wall of the outer barrel; the water inlet and the water outlet are connected with a water inlet and outlet control valve for controlling the on-off of the water inlet and the water outlet, the water inlet and outlet control valve comprises an inner cylinder arranged in an outer cylinder, a partition plate for dividing the inner cavity of the inner cylinder into a first inner cavity and a second inner cavity which are mutually independent is arranged in the inner cylinder, two first through holes which are respectively corresponding to the ball receiving port and the water outlet are arranged on the inner cylinder side wall of the first inner cavity, a ball-water separation filter screen for preventing the rubber ball from entering the first through holes which are respectively corresponding to the water outlet is arranged in the first inner cavity, two second through holes which are respectively corresponding to the ball sending port and the water inlet are arranged on the inner cylinder side wall of the second inner cavity, and a rotary driver for driving the inner cylinder to rotate in the outer cylinder so that the two first through holes are corresponding to the ball sending port and the water inlet and the two second through holes are corresponding to the ball receiving port and the water outlet is also connected.

Preferably, the outer cylinder and the inner cylinder are coaxial, and two ends of the outer cylinder are embedded into sliding bearings to form a revolute pair with two ends of the inner cylinder; a gap is reserved between the inner wall of the outer cylinder and the outer wall of the inner cylinder, a connecting ring is embedded into the ball collecting port, the water outlet, the ball delivering port and the water inlet of the outer cylinder, one end of the connecting ring is a plane, the other end of the connecting ring is a saddle port surface, the saddle port surface is tightly attached to the outer surface of the inner cylinder, and the connecting ring is used for communicating the ball collecting port, the water outlet, the ball delivering port and the water inlet on the outer cylinder with four ports on the inner cylinder respectively.

More preferably, the periphery of the saddle port is provided with a sealing ring, the sealing ring is tightly attached to the inner wall of the outer cylinder, and the leakage quantity is controlled to be very small.

Preferably, the axes of the ball receiving opening and the water outlet on one side wall of the outer cylinder are positioned on the same radial plane of the outer cylinder; the axes of the two first through holes on the side wall of the inner cylinder of the first inner cavity are positioned on the same radial surface of the inner cylinder; the axes of the ball service port and the water inlet which are positioned on the other side wall of the outer barrel are positioned on the same radial plane of the outer barrel; the axes of the two second ports on the side wall of the inner cylinder of the second inner cavity are positioned on the same radial surface of the inner cylinder.

Preferably, the axes of the water outlet and the water inlet are on the same straight line; the axes of a first port and a second port are in the same straight line; the axes of the ball service port and the ball receiving port are positioned on the same straight line; the axes of the first and second ports are on the same straight line.

Preferably, the outer cylinder is horizontally arranged or has an included angle smaller than or equal to 90 degrees with the horizontal plane.

Preferably, the partition is fixedly arranged in the inner cylinder.

Preferably, one end of the outer cylinder forms a sight glass opening, a sight glass is arranged in the sight glass opening, and one end of the baffle plate close to the sight glass opening is provided with a sealing strip which is used for being attached to the sight glass.

Preferably, the rotary actuator is an electric actuator, a pneumatic actuator or a hydraulic actuator.

Compared with the prior art, the invention has the beneficial effects that: the invention provides a horizontal ball-receiving-while-sending water separator, wherein during ball receiving, rubber balls and water flow enter a first inner cavity from a ball receiving port, and the water flow flows out from a water outlet; during ball serving, water flows into the second inner cavity from the water inlet to drive the rubber ball to flow out from the ball serving opening, the first inner cavity and the second inner cavity are mutually independent, ball serving and ball collecting can be achieved, ball collecting rate is effectively improved, power is extremely low, the structure is simple and reliable, machining difficulty is low, and the ball serving device is suitable for end cover type cleaning machines, double-return-stroke pipeline type cleaning machines and single-return-stroke pipeline type cleaning machines to clean.

Drawings

FIG. 1 is a schematic diagram I of a horizontal ball-receiving-while-sending water separator provided by the invention;

FIG. 2 is a schematic diagram II of a horizontal ball-receiving-while-sending water separator provided by the invention;

FIG. 3 is a cross-sectional view of a horizontal ball-receiving-while-sending water separator provided by the invention;

FIG. 4 is a schematic view of an inner barrel of a horizontal ball-receiving-while-sending water separator provided by the invention;

FIG. 5 is a schematic view of a connecting ring in a horizontal ball-receiving-while-sending water separator according to the present invention;

FIG. 6 is a schematic view of a seal ring in a horizontal ball-receiving-while-sending water separator provided by the invention;

FIG. 7 is a schematic view of a sealing strip in a horizontal ball-receiving-while-sending water separator provided by the invention;

FIG. 8 is a schematic view of a horizontal ball-receiving-while-sending water separator applied to an end cover type cleaning machine;

FIG. 9 is a schematic diagram of a horizontal ball-receiving-while-sending water separator applied to a double-return pipeline type cleaning machine;

Fig. 10 is a schematic diagram of a horizontal ball-receiving-while-sending water separator applied to a single-return pipeline type cleaning machine.

Detailed Description

The preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Fig. 1 to 7 are schematic views showing a preferred embodiment of a horizontal ball-receiving-while-sending water separator according to the present invention. As shown in fig. 1 to 7, the horizontal ball-receiving-while-sending water separator comprises an outer cylinder 10, wherein a ball-receiving opening 11 and a water outlet 12 are arranged on one side wall of the outer cylinder 10, and a ball-sending opening 13 and a water inlet 14 are arranged on the other side wall of the outer cylinder; the water inlet and the water outlet are both connected with a water inlet and outlet control valve 20 for controlling the on-off of the water inlet and the water outlet, the water inlet and outlet control valve 20 comprises an inner cylinder 21 arranged in the outer cylinder, a partition 22 for dividing the inner cavity of the inner cylinder into a first inner cavity 2101 and a second inner cavity 2102 which are mutually independent is arranged in the inner cylinder 21, two first through holes 211 which are respectively corresponding to a ball receiving port and the water outlet are arranged on the inner cylinder side wall of the first inner cavity, a ball water separation filter screen 213 for preventing a rubber ball from entering the first through holes which are corresponding to the water outlet is arranged in the first inner cavity, two second through holes 212 which are respectively corresponding to a ball sending port and the water inlet are arranged on the inner cylinder side wall of the second inner cavity, a ball water separation filter screen 213 for preventing the rubber ball from entering the second through holes which are corresponding to the water inlet is arranged in the second inner cavity, and a rotary driver 23 for driving the inner cylinder to rotate in the outer cylinder so that the two first through holes are corresponding to the ball sending port and the water inlet and the two second through holes are corresponding to the ball receiving port and the water outlet, and when ball receiving is carried out, so that the rubber ball and water flows out from the ball receiving port 11, the water flow from the first through holes 211 and the other inner cavity 21012; during ball serving, water flows into the second inner cavity 2102 from the water inlet 14 and the other second port 212 to drive the rubber ball to flow out from the second port 212 and the ball serving port 13, and the first inner cavity 2101 and the second inner cavity 2102 are mutually independent, so that ball serving and ball receiving can be realized, ball receiving rate is effectively improved, power is extremely low, structure is simple and reliable, and processing difficulty is low; after the ball receiving and delivering is finished, the inner barrel 21 can be driven to rotate by the inner barrel rotary driver 23, so that the two first through holes 211 correspond to the water inlet 14 and the ball delivering hole 13 respectively, and the two second through holes 212 correspond to the water outlet 12 and the ball receiving hole 11 respectively, so that the next ball receiving and delivering action can be conveniently performed. The outer cylinder 10 may be placed horizontally so that the central axis of the outer cylinder is flush with the horizontal plane, or the outer cylinder 10 may be placed obliquely so that the angle α between the central axis of the outer cylinder 10 and the horizontal plane is 90 degrees or less. The inner cylinder rotation driver 23 can be an electric actuator, the starting or stopping of the electric actuator can be controlled by a PLC or a singlechip of a controller, and a pneumatic actuator or a hydraulic actuator can also be used.

The outer cylinder 10 and the inner cylinder 21 are coaxial, and the sliding bearings 15 are embedded at two ends of the outer cylinder 10 to form a revolute pair with two ends of the inner cylinder, so that the inner cylinder driver 23 can conveniently drive the inner cylinder 21 to slide in the outer cylinder 10.

As shown in fig. 6 and 7, in order to make the inner cylinder 21 rotate smoothly in the outer cylinder 10, a gap is left between the inner wall of the outer cylinder and the outer wall of the inner cylinder, the ball receiving port 11, the water outlet 12, the ball service port 13 and the water inlet 14 of the outer cylinder 10 are embedded into the connecting ring 16, one end of the connecting ring 16 is a plane, the other end is a saddle surface, the saddle surface is tightly attached to the outer surface of the inner cylinder, and the connecting ring communicates the ball receiving port, the water outlet, the ball service port and the water inlet on the outer cylinder with four through holes on the inner cylinder respectively, so that the rotation of the inner cylinder 21 is not affected, and the sealing function is also achieved, so that the liquid is prevented from flowing out, and the ball service cavity and the ball receiving cavity are prevented from being in water. The periphery of the saddle port is provided with a sealing ring 17, the sealing ring 17 is tightly attached to the inner wall of the outer cylinder, the leakage quantity is controlled to be very small, and the first inner cavity 2101 and the second inner cavity 2102 are prevented from being in water connection. The material of the connecting ring 16, the seal ring 17 and the slide bearing is not limited, and ultra-high molecular weight polyethylene or nylon is preferably used.

The partition 22 in the inner barrel 20 may be fixedly disposed in the inner barrel, such as by welding, or movably disposed in the inner barrel, such as by plugging and clamping. The partition 22 can divide the interior cavity of the inner barrel 20 evenly into a first interior cavity 2101 and a second interior cavity 2102.

For convenient processing and manufacturing, the axes of the ball receiving port 11 and the water outlet 12 which are positioned on one side wall of the outer cylinder 10 are positioned on the same radial plane of the outer cylinder 10; the axes of the ball service port 13 and the water inlet 14 which are positioned on the other side wall of the outer barrel 10 are positioned on the same radial plane of the outer barrel; namely, the ball receiving port 11 and the water outlet 12 are arranged in layers on one radial plane, and the ball serving port 13 and the water inlet 14 are arranged in layers on the other plane; correspondingly, the axes of the two first through openings 211 on the inner barrel side wall of the first inner cavity 2101 are positioned on the same radial surface of the inner barrel 20; the axes of the two second ports 212 on the inner barrel sidewall of the second inner cavity 2102 lie on the same radial plane of the inner barrel 20, i.e., the two first ports 211 are layered on one radial plane and the two second ports 212 are layered on the other radial plane.

As a most preferred embodiment, as shown in fig. 3 and 4, the axes of the water outlet 12 and the water inlet 14 are on the same straight line, and the water outlet 12 and the water inlet 14 are symmetrically arranged; the axes of a first port 211 and a second port 212 are in the same straight line; the axes of the ball service opening 13 and the ball receiving opening 11 are positioned on the same straight line, and the ball service opening 13 and the ball receiving opening 11 are symmetrically arranged; the axes of the other first port 211 and the other second port 212 are on the same straight line, namely, the axes of the four ports on the outer barrel 10 are on the same radial surface, the ports on the two side walls on the outer barrel 10 are symmetrically arranged, meanwhile, the axes of the four ports on the inner barrel 21 are also on the same radial surface, and the first ports 211 and the second ports 212 on the two side walls of the inner barrel are symmetrically arranged, so that the two first ports 211 correspond to the ball receiving port 11 and the water outlet 12 respectively, the two second ports 212 correspond to the ball sending port 13 and the water inlet 14 respectively, and ball receiving and sending actions can be carried out; when the inner cylinder rotary driver 23 drives the inner cylinder 21 to rotate 90 degrees, the four through holes on the outer cylinder 10 do not correspond to the four through holes on the inner cylinder 21, and when the inner cylinder rotary driver 23 drives the inner cylinder 21 to rotate 180 degrees, the two first through holes 211 respectively correspond to the ball service port 13 and the water inlet 14, and the two second through holes 212 respectively correspond to the ball receiving port 11 and the water outlet 12, so that ball receiving and ball service actions can be continuously and simultaneously carried out. In addition, as a preferred embodiment, the diameters of the four ports on the outer cylinder 10 are the same as the diameters of the four ports on the inner cylinder 21.

In order to facilitate observation of the ball collecting and dispensing state and addition or removal of the rubber ball, one end of the outer barrel 10 is provided with a sight glass opening 18, and a sight glass is arranged in the sight glass opening; the inner tube 10 one end is sealed, and the other end is opened, and open one end and sight glass mouth 18 intercommunication, conveniently add the ball and get the ball, be close to sight glass mouth's baffle one end and be equipped with be used for laminating the sealing strip 19 on the sight glass to prevent the phenomenon that liquid leakage appears in the inner tube rotation in-process.

The horizontal ball water separator can be used in an end cap washer 100, as shown in FIG. 8; may also be used in a dual-return tunnel washer 200, as shown in FIG. 9; it can also be applied to a single-pass ducted washer 300, as shown in fig. 10, to wash a condenser, evaporator, or air conditioning unit.

The horizontal ball-receiving water separator comprises the following specific working processes: the inner cylinder rotary driver 23 drives the inner cylinder 21 to rotate, when the inner cylinder 21 is at 0 degree, two first through holes 212 on the inner cylinder 21 correspond to the ball service port 13 and the water inlet 14, and two second through holes 212 correspond to the ball receiving port 11 and the water outlet 12; the ball serving and ball receiving are performed simultaneously, water flows into the second inner cavity 2102 from the water inlet 14 and the second port 212, and the rubber ball is driven to flow out from the second port 212 and the ball serving port 12; the rubber ball and water flow enter the first inner cavity 2101 from the ball receiving port 11 and the first through port 211, the rubber ball stays in the first inner cavity 2101, and the water flow flows out from the first through port 211 and the water outlet 12; after the ball receiving and ball serving are finished, the inner cylinder rotary driver 23 drives the inner cylinder 21 to rotate, the inner cylinder 21 rotates by 90 degrees, four through holes on the inner cylinder 21 are not corresponding to four holes on the outer cylinder 10, and a sight glass opening can be opened to add rubber balls; when the inner barrel rotary driver drives the inner barrel 21 to rotate 180 degrees, two first through holes 211 in the inner barrel 21 correspond to the ball service port 13 and the water inlet 14 respectively, and two second through holes 212 exchange positions with the ball service port 11 and the water outlet 12 respectively, namely, a first inner cavity 2101 in the inner barrel 21 and a second inner cavity 2102, and a rubber ball which stays when the ball is originally received is used as a rubber ball when the ball is delivered next time, so that the ball is received and delivered next time is facilitated.

In summary, the technical solution of the present invention can fully and effectively achieve the above-mentioned objects, and the structural and functional principles of the present invention have been fully verified in the embodiments, so as to achieve the intended effects and purposes, and various changes or modifications may be made to the embodiments of the present invention without departing from the principles and spirit of the present invention. Accordingly, this invention includes all modifications encompassed within the scope of the invention as described in the claims and any equivalent thereof as would be within the scope of the invention as expressed in the claims.

Claims (9)

1. The horizontal ball-receiving water separator is characterized by comprising an outer barrel, wherein a ball-receiving port and a water outlet are formed in one side wall of the outer barrel, and a ball-serving port and a water inlet are formed in the other side wall of the outer barrel; the water inlet and the water outlet are connected with a water inlet and outlet control valve for controlling the on-off of the water inlet and the water outlet, the water inlet and outlet control valve comprises an inner cylinder arranged in an outer cylinder, a partition plate for dividing the inner cavity of the inner cylinder into a first inner cavity and a second inner cavity which are mutually independent is arranged in the inner cylinder, two first through holes which are respectively corresponding to the ball receiving port and the water outlet are arranged on the inner cylinder side wall of the first inner cavity, a ball-water separation filter screen for preventing the rubber ball from entering the first through holes which are respectively corresponding to the water outlet is arranged in the first inner cavity, two second through holes which are respectively corresponding to the ball sending port and the water inlet are arranged on the inner cylinder side wall of the second inner cavity, and an inner cylinder rotary driver for driving the inner cylinder to rotate in the outer cylinder so that the two first through holes are corresponding to the ball sending port and the water inlet and the two second through holes are corresponding to the ball receiving port and the water outlet is also connected.

2. The horizontal ball-and-play water separator as defined in claim 1 wherein: the outer cylinder and the inner cylinder are coaxial, and two ends of the outer cylinder are embedded into sliding bearings to form a revolute pair with two ends of the inner cylinder; a gap is reserved between the inner wall of the outer cylinder and the outer wall of the inner cylinder, a connecting ring is embedded into the ball collecting port, the water outlet, the ball delivering port and the water inlet of the outer cylinder, one end of the connecting ring is a plane, the other end of the connecting ring is a saddle port surface, the saddle port surface is tightly attached to the outer surface of the inner cylinder, and the connecting ring is used for communicating the ball collecting port, the water outlet, the ball delivering port and the water inlet on the outer cylinder with four ports on the inner cylinder respectively.

3. The horizontal ball-and-play water separator as defined in claim 2 wherein: and a sealing ring is arranged on the periphery of the saddle mouth and is clung to the inner wall of the outer cylinder.

4. The horizontal ball-and-play water separator as defined in claim 1 wherein: the axes of the ball receiving opening and the water outlet on one side wall of the outer cylinder are positioned on the same radial plane of the outer cylinder; the axes of the two first through holes on the side wall of the inner cylinder of the first inner cavity are positioned on the same radial surface of the inner cylinder; the axes of the ball service port and the water inlet which are positioned on the other side wall of the outer barrel are positioned on the same radial plane of the outer barrel; the axes of the two second ports on the side wall of the inner cylinder of the second inner cavity are positioned on the same radial surface of the inner cylinder.

5. The horizontal ball-and-play water separator as defined in claim 1 wherein: the axes of the water outlet and the water inlet are positioned on the same straight line; the axes of a first port and a second port are in the same straight line; the axes of the ball service port and the ball receiving port are positioned on the same straight line; the axes of the first and second ports are on the same straight line.

6. The horizontal ball-and-play water separator as defined in claim 1 wherein: the outer cylinder is horizontally arranged or has an included angle smaller than or equal to 90 degrees with the horizontal plane.

7. The horizontal ball-and-play water separator as defined in claim 1 wherein: the baffle is fixedly arranged in the inner cylinder.

8. The horizontal ball-and-play water separator as defined in claim 1 wherein: one end of the outer cylinder forms a sight glass opening, a sight glass is arranged in the sight glass opening, and one end of the baffle plate close to the sight glass opening is provided with a sealing strip which is used for being attached to the sight glass.

9. The horizontal ball-and-play water separator as defined in claim 1 wherein: the rotary driver is an electric actuator, a pneumatic actuator or a hydraulic actuator.