CN203442218U - Continuous fluid processing device - Google Patents

Abstract

The utility model discloses a continuous fluid processing device. The continuous fluid processing device comprises a valve assembly, a transmission device and N reaction containers and is characterized in that the reaction containers are fixed to the periphery of the valve assembly, and the valve assembly comprises a fixed runner part, a feed runner part, a discharge runner part and a runner switching part. According to the continuous fluid processing device, the reaction containers are fixed to the ground, and the valve assembly is composed of the fixed runner part, the feed runner part, the discharge runner part and the runner switching part. In the use process, the aim of continuous fluid processing is achieved by only rotating the runner switching part, and the whole device has the advantages of being small in investment, low in manufacturing difficulty, capable of effectively reducing the running cost and the like.

Description

A kind of continuous fluid treatment device

Technical field

The utility model relates to fluid treatment field, particularly a kind of continuous fluid treatment device.

Background technique

Existing continuous fluid treatment device, its basic structure is if the publication number Chinese utility model patent < < that is CN1849167A is for carrying out as shown in the device > > of chemistry or physical treatment, it as shown in Figure 7, it mainly comprises: one has the fixed frame of turntable, this turntable is arranged in frame, thereby it can rotate around central axis, on this turntable, there are a plurality of reaction vessels, be provided with a valve assembly, this valve assembly comprises the rotatable valve member of the plate-like of a relatively described central axis arranged concentric and a stationary valve member, this stationary valve member and rotatable valve member positioned opposite are also connected in frame, each valve member all has aperture, described aperture becomes toward each other with the ordinal shift changing, between rotatable valve member and described reaction vessel and between stationary valve member and supply/discharge pipe, be provided with link, also be provided with a motor, dividing movement for described rotary valve parts, described motor is connected on described rotary valve parts by transmission device.

Above-mentioned continuous fluid treatment device is positioned over reaction vessel on turntable, by the dividing movement of rotatable valve member and reaction vessel, realize the object of continuous fluid charging, and it is well-known, compared with large equipment in the situation that, inertial force is very large, needs very large kinetic energy could realize accurately and passs on, and this just means that the manufacture difficulty of equipment is high, invests greatly, operating cost is also very high simultaneously, has greatly limited the using scope of continuous fluid treatment device.

Model utility content

The purpose of this utility model be to provide a kind of invest little, manufacture difficulty is low and can effectively reduce the continuous fluid treatment device of operating cost.

For achieving the above object, the technological scheme that the utility model proposes is: a kind of continuous fluid treatment device, comprises valve assembly, transmission device, a N reaction vessel; It is characterized in that, described reaction vessel is fixed at around valve assembly; Described valve assembly comprises stationary flowpath parts, charging runner parts, discharging runner parts and runner converting member;

On described stationary flowpath parts, be evenly equipped with N to straightthrough port, every pair of straightthrough port comprises a charging straightthrough port and a discharging straightthrough port, and the upper end of charging straightthrough port of every pair of described straightthrough port and the material feeding mouth of reaction vessel, the upper end of discharging straightthrough port and the discharge port of reaction vessel are connected;

Described charging runner parts are provided with M feed pipe; Described discharging runner parts are provided with M discharge pipe;

Described runner converting member is located between charging runner parts and discharging runner parts, and can, around the rotation of valve assembly central axis, between described charging runner parts and runner converting member, runner converting member and discharging runner parts, be tightly connected;

Described charging runner parts and runner converting member surface of contact are provided with M annular charging runner, and annular charging runner is connected one by one with feed pipe; Described discharging runner parts and runner converting member surface of contact are provided with M annular discharging runner, and annular discharging runner is connected one by one with discharge pipe;

Described stationary flowpath parts and runner converting member surface of contact are provided with M to intermediate flow channel, every pair of intermediate flow channel comprises a charging intermediate flow channel and a discharging intermediate flow channel, every pair of intermediate flow channel at least connects pair of straight port, and charging intermediate flow channel and charging straightthrough port, discharging intermediate flow channel is connected with discharging straightthrough port; In described runner converting member, be evenly equipped with M convection cell passage, every convection cell passage comprises a feed fluid passage and a discharging fluid passage;

In runner converting member rotary course, one end of the feed fluid passage of every convection cell passage is connected with annular discharging runner with one end of annular charging runner, discharging fluid passage; The other end of the other end of feed fluid passage, discharging fluid passage can be connected with any pair of straight port by intermediate flow channel, and described stationary flowpath parts and runner converting member are tightly connected;

Described transmission device is connected with runner converting member, and makes runner converting member do dividing movement by the tilt fixing of 360/N;

Described N >=2; M >=2; N >=M.

Further, described annular charging runner is located on charging runner parts, also can be located on runner converting member, or be located on charging runner parts and runner converting member.

Further, described annular discharging runner is located on discharging runner parts, also can be located on runner converting member, or be located on discharging runner parts and runner converting member.

Further, described intermediate flow channel is located on stationary flowpath parts, also can be located on runner converting member, or be located on stationary flowpath parts and runner converting member.

Further, between described stationary flowpath parts and runner converting member, charging runner parts and runner converting member, runner converting member and discharging runner parts, be tightly connected and can be tightly connected as the mode that hold down gag compresses by crossing drive fit, also can be by seal groove being set on charging runner parts, discharging runner parts or runner converting member, seal groove is provided with seal ring realization and is tightly connected, and described seal ring material is EPDM, teflon, fluorine rubber etc.

Further, described hold down gag adopts oil hydraulic cylinder hold down gag or pneumatic cylinder hold down gag.

Further, described valve assembly is provided with a fixed plate, and described fixed plate, for valve assembly is fixed on the ground, plays a supportive role simultaneously.

Adopt technique scheme, continuous fluid treatment device described in the utility model is by reaction vessel being fixed on the ground, and forms valve assembly by stationary flowpath parts, charging runner parts, discharging runner parts and runner converting member; In using process, only need eddy channel converting member, can realize the object that continuous fluid is processed; Whole device have investment little, manufacture difficulty is low and can effectively reduce the advantages such as operating cost.

Accompanying drawing explanation

Fig. 1 is continuous fluid treatment device structural representation described in the utility model;

Fig. 2 is valve assembly schematic diagram described in the utility model;

Fig. 3 is stationary flowpath block diagram described in the utility model;

Fig. 4 is charging runner block diagram described in the utility model;

Fig. 5 is discharging runner block diagram described in the utility model;

Fig. 6 is runner converting member schematic diagram described in the utility model;

Fig. 7 is continuous fluid treatment device structural representation in prior art;

Embodiment

Below in conjunction with the drawings and specific embodiments, the utility model is described further.

As shown in Fig. 1-6, a kind of continuous fluid treatment device, comprise valve assembly 2, transmission device (not shown), 4 reaction vessels 1, reaction vessel 1 is fixed at around valve assembly 2, transmission device is connected with runner converting member 6, and make runner converting member 6 around valve assembly 2 write axis 21, by the tilt fixing of 90 °, do dividing movement, valve assembly 2 comprises stationary flowpath parts 3, charging runner parts 4, discharging runner parts 5 and runner converting member 6;

Wherein: on described stationary flowpath parts, be evenly equipped with 4 pairs of straightthrough ports 31, every pair of straightthrough port comprises a charging straightthrough port 311 and a discharging straightthrough port 312, and the upper end of the charging straightthrough port 311 of every pair of straightthrough port 31 is connected with the upper end of the material feeding mouth 101 of reaction vessel 1, discharging straightthrough port 312 and the discharge port 102 of reaction vessel 1;

Charging runner parts 4 are provided with 4 feed pipes 41; Discharging runner parts 5 are provided with 4 discharge pipes 51;

Runner converting member 6 is located between charging runner parts 4 and discharging runner parts 5, and can be around valve assembly 2 central axis 21 rotations, and charging runner parts 4 and runner converting member 6, runner converting member 6 and 5 of discharging runner parts are tightly connected;

Charging runner parts 4 are provided with 4 annular charging runners 7 with runner converting member 6 surface of contact, and annular charging runner 7 is connected one by one with feed pipe 41; Discharging runner parts 5 are provided with 4 annular discharging runners 8 with runner converting member 6 surface of contact, and annular discharging runner 8 is connected one by one with discharge pipe 51;

Stationary flowpath parts 3 are provided with 4 pairs of intermediate flow channel 9 with runner converting member 6 surface of contact, every pair of intermediate flow channel 9 comprises a charging intermediate flow channel 91 and a discharging intermediate flow channel 92, every pair of intermediate flow channel 9 at least connects pair of straight port 31, and charging intermediate flow channel 91 and charging straightthrough port 311, discharging intermediate flow channel 92 is connected with discharging straightthrough port 312; In runner converting member 6, be evenly equipped with 4 convection cell passages, every convection cell passage comprises a feed fluid passage 61 and a discharging fluid passage 61;

In runner converting member 6 rotary courses, one end of the feed fluid passage 61 of every convection cell passage is connected with annular discharging runner 8 with one end of annular charging runner 7, discharging fluid passage 62; The other end of the other end of feed fluid passage 61, discharging fluid passage 62 can be connected with any pair of straight port 31 by intermediate flow channel, described stationary flowpath parts 3 and runner converting member 6 seal by hold down gag 10, and hold down gag 10 adopts oil hydraulic cylinder hold down gag or pneumatic cylinder hold down gag.

As shown in Fig. 4,6, annular charging runner 7 forms by being located at the annular charging runner parts 71 on charging runner parts 4 and the annular charging runner parts 72 of being located on runner converting member 6; As required, annular charging runner 7 also can be located at separately on charging runner parts 4 or runner converting member 6.

As shown in Figure 5, annular discharging runner 8 is located on discharging runner parts 5, as required, annular discharging runner parts 8 also can be located on runner converting member 6, or also can adopt annular charging runner parts 7 to be located at like that on discharging runner parts 5 and runner converting member 6.

As shown in Figure 6, intermediate flow channel 9 is located on runner converting member 6, and as required, intermediate flow channel also can be located on stationary flowpath parts 3 or be located on stationary flowpath parts 3 and runner converting member 6.

As described in Figure 1, described valve assembly 2 is provided with a fixed plate 11, and described fixed plate 11, for valve assembly 2 being fixed on the ground, plays a supportive role simultaneously.

Further, described charging runner parts 4 and runner converting member 6, runner converting member 6 and 5 of discharging runner parts are tightly connected and are tightly connected as the mode that hold down gag compresses by crossing drive fit, also can be by seal groove being set on charging runner parts 4, discharging runner parts 5 or runner converting member 6, seal groove is provided with seal ring realization and is tightly connected, and described seal ring material is EPDM, teflon, fluorine rubber etc.6 of fixed connecting part 3 and runner converting members can adopt the mode that seal groove and seal ring be set to realize and be tightly connected.

During concrete use, take this equipment application is example with ion exchange, by adding ion exchange resin 1 li of reaction vessel, 4 feed pipes connect respectively feed liquid, water, eluent, regenerated liquid, and every kind of liquid is realized circulation feeding and discharging by feed pipe-annular charging runner-feed fluid passage-charging intermediate flow channel-charging straightthrough port-reaction vessel-discharging straightthrough port-discharging intermediate flow channel-discharging fluid passage-annular discharging runner-discharge pipe successively; By transmission device, driving runner converting member within the set time, to realize horizontal rotary again turn 90 degrees, and then cause that feed fluid passage is connected with lower a pair of straightthrough port with discharging fluid passage, the step of the continuous realization absorption of realization in reaction vessel, washing, wash-out, regeneration, reaches the object of continuous ionic exchange.

It should be noted that, the present embodiment has only been expressed design of the present utility model with the form of 4 feed pipes and 4 reaction vessels, as required, also a plurality of feed pipes can be set, as be arranged to 5 feed pipes and realize the forms such as charging-water inlet-secondary water inlet-regeneration-regeneration washing-charging; Meanwhile, also can as required a plurality of reaction vessels be set, different feed liquids can connect the reaction vessel of arbitrary number, and can adopt series connection charging between reaction vessel, also can adopt the form chargings such as in parallel.

In addition, continuous fluid treatment device described in the utility model can also be for contact or the reaction of other fluid.Those skilled in the art can carry out various modifications to the utility model after reading present patent application in the situation that not departing from spirit and scope of the present utility model.

Claims (10)

1. a continuous fluid treatment device, comprises valve assembly, transmission device, a N reaction vessel;

It is characterized in that, described reaction vessel is fixed at around valve assembly; Described valve assembly comprises stationary flowpath parts, charging runner parts, discharging runner parts and runner converting member;

On described stationary flowpath parts, be evenly equipped with N to straightthrough port, every pair of straightthrough port comprises a charging straightthrough port and a discharging straightthrough port, and the upper end of charging straightthrough port of every pair of described straightthrough port and the material feeding mouth of reaction vessel, the upper end of discharging straightthrough port and the discharge port of reaction vessel are connected;

Described charging runner parts are provided with M feed pipe; Described discharging runner parts are provided with M discharge pipe;

Described runner converting member is located between charging runner parts and discharging runner parts, and can, around the rotation of valve assembly central axis, between described charging runner parts and runner converting member, runner converting member and discharging runner parts, be tightly connected;

Described charging runner parts and runner converting member surface of contact are provided with M annular charging runner, and annular charging runner is connected one by one with feed pipe; Described discharging runner parts and runner converting member surface of contact are provided with M annular discharging runner, and annular discharging runner is connected one by one with discharge pipe;

Described stationary flowpath parts and runner converting member surface of contact are provided with M to intermediate flow channel, every pair of intermediate flow channel comprises a charging intermediate flow channel and a discharging intermediate flow channel, every pair of intermediate flow channel at least connects pair of straight port, and charging intermediate flow channel and charging straightthrough port, discharging intermediate flow channel is connected with discharging straightthrough port; In described runner converting member, be evenly equipped with M convection cell passage, every convection cell passage comprises a feed fluid passage and a discharging fluid passage;

In runner converting member rotary course, one end of the feed fluid passage of every convection cell passage is connected with annular discharging runner with one end of annular charging runner, discharging fluid passage; The other end of the other end of feed fluid passage, discharging fluid passage can be connected with any pair of straight port by intermediate flow channel, and described stationary flowpath parts and runner converting member are tightly connected;

Described transmission device is connected with runner converting member, and makes runner converting member do dividing movement by the tilt fixing of 360/N;

Described N >=2; M >=2; N >=M.

2. a kind of continuous fluid treatment device according to claim 1, is characterized in that, described annular charging runner is located on charging runner parts, runner converting member or charging runner parts and runner converting member.

3. a kind of continuous fluid treatment device according to claim 1, is characterized in that, described annular discharging runner is located on discharging runner parts, runner converting member or on discharging runner parts and runner converting member.

4. a kind of continuous fluid treatment device according to claim 1, is characterized in that, described intermediate flow channel is located on stationary flowpath parts, runner converting member or stationary flowpath parts and runner converting member.

5. a kind of continuous fluid treatment device according to claim 1, it is characterized in that, between described stationary flowpath parts and runner converting member, charging runner parts and runner converting member, runner converting member and discharging runner parts, be tightly connected as being tightly connected by crossing friction tight mode.

6. a kind of continuous fluid treatment device according to claim 5, is characterized in that, described tension fitted seal is connected to and adopts hold down gag press seal to connect.

7. a kind of continuous fluid treatment device according to claim 6, is characterized in that, described hold down gag is oil hydraulic cylinder hold down gag or pneumatic cylinder hold down gag.

8. a kind of continuous fluid treatment device according to claim 1, it is characterized in that, between described stationary flowpath parts and runner converting member, charging runner parts and runner converting member, runner converting member and discharging runner parts, be tightly connected as on stationary flowpath parts, charging runner parts, runner converting member or discharging runner parts, seal groove being set, seal groove is provided with seal ring realization and is tightly connected.

9. a kind of continuous fluid treatment device according to claim 8, is characterized in that, described seal ring material is EPDM, teflon or fluorine rubber.

10. a kind of continuous fluid treatment device according to claim 1, is characterized in that, described valve assembly is provided with a fixed plate, and described fixed plate, for valve assembly is fixed on the ground, plays a supportive role simultaneously.

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