JP2017047376A - Test device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a test device which can easily select a filter device.SOLUTION: A test device 10 is a test device for a specific filter device. The test device 10 comprises: a filter 20 for the test device comprising a filter part 21 for the test device which filters test water, and a cylindrical filter body 22 for the test device which accommodates the filter part 21 for the test device; and a water supply unit 40 which supplies water to the filter 20 for the test device. A linear velocity of the filter part 21 for the test device is larger than a linear velocity of the filter part of the filter, a space velocity of the filter part 21 for the test device is larger than a space velocity of the filter part of the filter, and a magnification ratio of the space velocity of the filter part 21 for the test device to the space velocity of the filter part of the filter is larger than a magnification ratio of the linear velocity of the filter part 21 for the test device to the linear velocity of the filter part of the filter.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a test apparatus used for a selection test of a filtration apparatus that removes iron and manganese contained in water.

  In order to use raw water such as well water as domestic water or industrial water, a filtration device capable of removing iron and manganese that removes iron and manganese contained in the raw water by filtering the raw water with a filter medium is known. (For example, refer to Patent Document 1). In such a filtering device, sodium hypochlorite is injected into the raw water, the iron contained in the raw water is agglomerated, and the iron is easily collected by the filter medium.

  Since the filtration device has a different filtration capacity for each model, a filtration device having the ability to reduce iron or manganese in raw water to a concentration that can be used as domestic water or industrial water is selected according to the nature of the raw water.

JP 2009-148696 A

  As described above, the selection of the filtration device has the following problems. That is, when colloidal silicon dioxide is contained in the raw water, the agglomeration of iron may be inhibited when the raw water is exposed to air for a long time.

  For this reason, when the raw water is transported to a place away from the raw water collection place and the filtration device selection test is performed, the amount of iron collected will be different even if the same filtration device is used. The filtration device cannot be selected.

  For this reason, it is also conceivable that the filtration device is transported to a raw water collection place and a selection test is performed at the collection place. However, if the filtration device is transported to the raw water collection site, the cost increases, and if the filtration device is not suitable, the filtration device is returned, another filtration device is transported, and the test is performed again. Necessary.

  In addition, when the flow rate of raw water used as domestic water or industrial water is large, a large-sized filtration device is required, and the transportation cost is further increased.

  An object of this invention is to provide the test apparatus which can select a filtration apparatus easily.

  As one aspect of the present invention, a test apparatus is a test apparatus for a filtration apparatus having a filtration section, and is a tubular apparatus that houses the test apparatus filtration section that filters test water, and the test apparatus filtration section. A test device filter having a test device filter body, and a water supply device for supplying water to the test device filter, wherein the linear velocity of the test device filtration section is higher than the linear velocity of the filtration section. The space velocity of the filtration unit for the test device is larger than the space velocity of the filtration unit, and the magnification of the space velocity of the filtration unit for the test device with respect to the space velocity of the filtration unit is the linear velocity of the filtration unit. Is larger than the magnification of the linear velocity of the filter for the test apparatus.

  The present invention can provide a test apparatus capable of easily selecting a filtration apparatus.

1 is a side view showing a test apparatus according to an embodiment of the present invention. The side view which shows the state by which the filter main body of the filter for test devices of the test device was decomposed | disassembled. The graph which shows the processed iron density | concentration with respect to the amount of treated water of the filter for the test apparatus, and the filter of the filter apparatus corresponding to the test apparatus. The side view which shows the state by which the filter for the said test equipment was connected in series by two. The graph which shows the process iron density | concentration with respect to the amount of process waters of the filter for test apparatuses of the filtration apparatus shown in Table 3, and the test apparatus shown in Table 4.

  A test apparatus 10 according to an embodiment of the present invention will be described with reference to FIGS. FIG. 1 is a side view showing the test apparatus 10. The test apparatus 10 is a test apparatus used for a test for determining whether or not a specific filtering apparatus can be used.

  This filtering device is configured to remove iron and manganese contained in the raw water by filtering raw water such as well water. This filtration device has, for example, a filter having a filtration unit, a pump for feeding raw water such as well water to the filter, and a chemical pump for injecting sodium hypochlorite into the raw water on the primary side of the filter. ing. The filter has a filter part and a filter body that houses the filter part. The filtration unit is configured, for example, by accommodating a filtering material in a filter.

  The filter of this filter device has a cylindrical shape with a height of 1025 mm and an inner diameter of 281 mm, and 30 L (liter) of a filtering material is accommodated therein. The filter part is formed by this filter medium.

  The test apparatus 10 is configured so that the filtering ability is slightly inferior to the above-described specific filtering apparatus. As shown in FIG. 1, the test apparatus 10 includes a test apparatus filter 20 having a test apparatus filter 21, a water supply apparatus 40 that can feed raw water to the test apparatus filter 20, and a test apparatus filter 20. It has the support 60 which supports, and the cup 60 which stores the treated water filtered with the filter 20 for test devices.

  The test device filter 20 is smaller than the filter of the filter device described above. The test apparatus filter 20 includes a test apparatus filter section 21 and a test apparatus filter body 22 that houses the test apparatus filter section 21.

  The test device filtration unit 21 is formed to collect iron and manganese in the test water. The test device filtration unit 21 is configured by accommodating the filter medium 21 a in the test device filter body 22. The filter medium 21a is, for example, the same as the filter medium used in the above-described specific filtering device. The filter medium 21a has a fine grain shape. The filter medium 21a is accommodated in, for example, a bag so that the filter medium 21a can be transported. The bag is broken when the test apparatus 10 is assembled, and is stored in the test apparatus filter 20.

  The linear velocity LV of the test device filtration unit 21 is larger than the linear velocity LV of the filtration unit of the specific filtration device described above. Further, the space velocity SV of the test device filtration unit 21 is larger than the space velocity SV of the filtration unit of the above-described filtration device. Moreover, the magnification of the space velocity SV of the test device filtration unit 21 with respect to the space velocity SV of the filtration unit of the filtration device described above is the line of the test device filtration unit 21 with respect to the linear velocity LV of the filtration unit of the specific filtration device described above. It is larger than the magnification of the speed LV.

Here, the linear velocity LV is a flow rate that flows per unit area of the filter medium. The cross-sectional area of the filter medium 21a accommodated in the filter body 22 for the test apparatus is S (m ² ), that is, the cross-sectional area defined by the inner peripheral surface of the filter body 22 for the test apparatus is S. Assuming that the flow rate of the test water sent to the filter 20 is Q (m ³ / _hr ), the linear velocity LV is LV = Q / S.

The space velocity SV is a flow rate that flows per unit volume of the filter medium. When the unit volume of the filter medium 21a accommodated in the filter main body 22 for the test apparatus is V (m ³ ), the space velocity SV is SV = Q / S.

  In the present embodiment, the linear velocity LV of the test device filtration unit 21 is 2.4 times the linear velocity LV of the filter of the specific filtration device described above. In addition, the space velocity SV of the test device filter 20 is four times the space velocity SV of the filter of the specific filter device described above.

  As described above, the test apparatus 10 has a filtration capacity slightly inferior to the above-described filtration apparatus by setting the linear velocity LV to 2.4 times that of the filtration apparatus and the space velocity SV to 4 times that of the filtration apparatus. Will have.

  The test device filter main body 22 is formed in a cylindrical shape, and is formed so that the test device filter 21 can be accommodated therein. FIG. 2 is a side view showing a state in which the filter body 22 for test apparatus is disassembled. As shown in FIG. 2, the test apparatus filter main body 22 is formed so that the test apparatus filter section 21, that is, the filter medium 21 a is accommodated therein and can be taken out. Specifically, the tester filter main body 22 is formed to be split into two in the axial direction, for example. In addition, the test device filter main body 22 is supplied to the primary side of the test device filter main body 22 along the direction intersecting the stacking direction of the test device filter unit 21 so that test water described later is fed. Is formed.

  Specifically, the test device filter main body 22 includes a first portion 23 that houses the test device filtration portion 21, a second portion 24 to which the water supply device 40 is connected, and a first portion 23. A coupling mechanism 25 that couples the second portion 24 is provided.

  The first portion 23 includes a cylindrical first main body portion 26, a filter 28 provided at one end portion of the first main body portion 26, and a first valve device 29 connected to one end of the first main body portion 26. have.

  The first main body portion 26 is formed in a cylindrical shape so as to accommodate the test device filtration portion 21 therein. The first main body 26 is formed of a transparent member, for example. The ratio of the axial length of the first main body portion 26 to the inner diameter is larger than the ratio of the axial length of the filtering portion to the inner diameter of the filter main body of the specific filtering device described above. That is, the 1st main-body part 26 is formed elongate with respect to the filter of the above-mentioned filtration apparatus.

  The filter 28 is formed so that the test device filtration unit 21 can be placed and the test water can pass therethrough. Specifically, the filter 28 is formed so that the filter medium 21a does not pass and the raw water can pass. The filter 28 is, for example, a wire mesh finer than the particle diameter of the filter medium 21a.

  The first valve device 29 is an open / close valve, and is configured to be manually openable / closable, for example.

  The second part 24 includes a second main body 30, a second valve device 31 provided in the second main body 30, and a third valve device 32.

  The second main body 30 is formed on the primary side of the second main body 30 so that test water is fed along a direction intersecting the axial direction of the first main body 26. For example, a T-shaped joint is used for the second main body 30.

  The second main body 30 has three ports. Specifically, the first main body 30 includes a first port 30a and a second port 30b facing each other, and a third port 30c.

  The first port 30 a is connected to the opening of the first main body 26 by the connecting mechanism 25.

  The second valve device 31 is connected to the second port 30b. The second valve device 31 is an exhaust valve device.

  The third valve device 32 is connected to the third port 30c. The third valve device 32 is an open / close valve, and is configured to be manually switchable between open and closed, for example.

  The coupling mechanism 25 includes a coupling portion provided in the opening of the first main body portion 26 and a coupled portion provided in the first port 30a of the second main body portion 30 and connectable to the coupling portion. It is configured to be manually connectable to the connecting portion and the connected portion.

  For the coupling mechanism 25, for example, a union joint is used. When the first main body portion 26 and the second main body portion 30 are connected by the connecting mechanism 25, the inside of the first main body portion 26 and the inside of the second main body portion 30 communicate with each other.

  The water feeding device 40 is formed so that raw water can be fed. Moreover, the water supply apparatus 40 is comprised so that manual operation is possible, for example. The water feeding device 40 includes, for example, a syringe 41 and a piston 42. A male screw is formed at the discharge port of the syringe 41.

  The water feeding device 40 is connected to the primary side of the third valve device 32. In the present embodiment, the water supply device 40 is connected to the primary side of the third valve device 32 via, for example, a pipe member 43. One end of the pipe member 43 is fixed to the primary side of the third valve device 32.

  The tube member 43 has flexibility, for example. The other end of the pipe member 43 is formed so that the water feeding device 40 can be fixed. The other end of the pipe member 43 is formed with a female screw that can be screwed with the male screw of the syringe 41 of the water feeding device 40.

  The support device 50 includes a gantry 51 on which the cup 60 can be placed, a support shaft 52 fixed to the gantry 51, and a holding portion 53 that is provided on the support shaft 52 and holds the filter body 22 for the test apparatus. ing.

  The gantry 51 has, for example, a flat upper surface. The gantry 51 has a through hole 56 formed therein. The through hole 56 passes through the gantry 51.

  One end of the support shaft 52 is formed so that it can be inserted through the through hole 56. A bearing surface and a male screw are formed at one end of the support shaft 52. The support shaft 52 is fixed to the gantry 51 by screwing the nut into the support shaft 52 that protrudes from the back surface of the gantry 51 through the through hole 56.

  The holding unit 53 includes, for example, a clamp 54 that can hold the test device filter main body 22 and a muff 55 that fixes the clamp 54 to the support shaft 52. A pair of holding units 53 are used, for example. The clamps 54 are fixed to the support shaft 52 so as to be separated from each other.

  Table 1 below shows the relationship between the linear velocity LV, the space velocity SV, and the treated water iron concentration with respect to the flow rate Q to be processed in the test device filter 20 configured as described above. The flow rate here is a flow rate of test water in which sodium hypochlorite, which is a chemical solution, is injected into raw water. Table 2 below shows the relationship between the linear velocity LV, the space velocity SV, and the treated water iron concentration with respect to the flow rate Q processed by the filter of the specific filtration device described above. The flow rate referred to here is the flow rate of the raw water in which sodium hypochlorite, which is a chemical solution, is injected into the raw water.

  A flow rate of 30 ml / min flowing into the test device filter 20 corresponds to a treatment flow rate of 6.25 L / min of the filter of the filter device. The flow rate of 60 ml / min flowing into the test device filter 20 corresponds to 12.5 l / min flowing into the filter of the filter device. The flow rate of 120 ml / min flowing into the test device filter 20 corresponds to 25 l / min flowing into the filter of the filter device. The flow rate of 192 ml / min flowing into the test device filter 20 corresponds to 40 l / min flowing into the filter of the filter device.

  Moreover, FIG. 3 is a graph which shows the process iron density | concentration with respect to the process water amount of the filter 20 for test devices, and the filter of the above-mentioned specific filter apparatus. Here, the treated iron concentration is the concentration of iron in the treated water using the filtered test water as treated water.

  As shown in Tables 1 and 2, the linear velocity LV of the test device filter 20 is 2.4 times the linear velocity LV of the filter of the above-described filter device, and the space velocity SV of the test device filter 20 is. Is four times the space velocity SV of the filter of the above-described filtration apparatus. Further, as shown in Tables 1 and 2 and FIG. 3, it can be seen that the processing capability of the test device filter 20 is slightly inferior to the processing capability of the filter of the above-described filtration device.

  Next, an example of the assembly procedure of the test apparatus 10 will be described.

  First, the support shaft 52 is fixed to the gantry 51. Specifically, one end of the support shaft 52 is inserted into the through hole 56 from the surface side of the gantry 51. The support shaft 52 is fixed to the gantry 51 by screwing a nut into a male screw at one end of the support shaft 52 protruding from the back surface of the gantry 51.

  Next, the holding portion 53 is fixed to the support shaft 52. Specifically, the holding portion 53 is fixed to the support shaft 52 by the muff 55.

  Next, the first portion 23 of the test device filter 20 is held by the clamps 54 of the holding portions 53 so that the first valve device 29 is located on the lower side in the gravity direction.

  Next, the bag in which the filter medium 21 a is accommodated is broken, and the filter medium 21 a is accommodated from the opening of the first main body portion 26. For example, a funnel may be used for accommodating the filter medium 21a. Since the accommodated filter medium 21 a is blocked by the filter 28, it is held in the first main body portion 26. By accommodating the filter medium 21a in the first main body portion 26, the filter medium 21a is laminated, and the filter section 21 for a test apparatus is formed.

  Next, the second portion 24 is connected to the first portion 23 by the connecting mechanism 25.

  Next, the cup 60 is disposed below the first valve device 29. Next, the filter medium 21a is washed. As a cleaning operation, tap water is supplied to the test device filter 20 by the water supply device 40, and the filter medium 21a is cleaned with the tap water.

  The assembly operation of the test apparatus 10 is completed through the above steps.

  Next, an example of a test using the test apparatus 10 will be described. First, test water is prepared by injecting a chemical into raw water. Next, the water supply device 40 is filled with test water. Next, the valve devices 29 and 32 are opened. Next, the water feeding device 40 is connected to the pipe member 35.

  Next, the water supply device 40 supplies the test water having a flow rate corresponding to the flow rate to be processed by the above-described filtration device to the test device filter 20. The operator operates the piston 42 so as to push the piston 42 in a preset time in order to push out a flow rate corresponding to the flow rate of the raw water processed by the filtration device.

  When operating the piston 42, it is preferable to operate the water supply device 40 at a position higher than the test device filter 20. The pushed test water flows into the second main body 30 from the third port 30 c of the second main body 30 through the pipe member 35.

  Depending on the operator's operation of the piston 42, a state where the test water flows vigorously and a state where the flow momentum is small can occur. This is because, as described above, the operator operates the piston 42 so as to push the piston 42 within a preset time, and the piston 42 pushing speed from when the piston 42 is pushed to when it is pushed. This is because variations may occur.

  On the secondary side of the third port 30c, when the momentum of the flow of the test water is strong, the inflow of the test water collides with the inner peripheral surface of the second main body 30 and scatters. The scattered test water pours onto the filter medium 21 a in the first main body portion 26.

  When the momentum of the flow of the test water is small and the test water does not collide with the inner surface of the second main body 30 on the secondary side of the third port 30c, the test water is filtered by the filter medium 21a of the second main body 30. It spreads until it reaches, and falls on the filter medium 21a.

  The test water becomes treated water in which iron and manganese are collected by the filter medium 21a by passing through the test device filtration unit 21. The treated water filtered by the test device filtration unit 21 is discharged into the cup 60 through the first valve device 29.

  Next, the treated water in the cup 60 is collected, and the iron concentration and manganese concentration in the treated water are measured. As a result of the measurement, when the iron concentration and the manganese concentration are reduced to a concentration at which the treated water can be used, it is determined that the above-described specific filtering device has a sufficient filtering ability to filter the raw water.

  That is, the filtration capacity of the test apparatus filter 20 is set to be slightly inferior to the filtration capacity of the filter of the above-described filtration apparatus. For this reason, if it is judged that the filtration capability by the filter 20 for test devices is enough, it can be judged that the above-mentioned filtration device also has sufficient filtration capability.

  Here, the usable concentration is a value determined by the usage of the treated water. For example, in the case where treated water is used as domestic water, the iron concentration and manganese concentration in the treated water are concentrations that can be used as domestic water. When treated water is used as industrial water, the iron concentration and manganese concentration in the treated water are concentrations that can be used as industrial water.

  As a result of the measurement, if the iron concentration and the manganese concentration exceed the usable concentration, it is determined that the filtration device has insufficient filtration capacity.

  When the test is completed, the test apparatus 10 is disassembled by, for example, the reverse procedure of the assembly work. The filter medium 21a taken out from the first main body 26 can be reused, for example, a predetermined number of times by washing with tap water. The predetermined number of times is the number of times that the filter medium 21a maintains the ability to collect iron and manganese.

  In the test apparatus 10 configured as described above, the linear velocity LV of the test device filtration unit 21 is made larger than the linear velocity LV of the filtration unit of the above-described filtration device, and the space of the test device filtration unit 21 of the test device 10 is increased. The linear velocity LV of the test device filtration unit 21 of the test device filter 20 with respect to the linear velocity LV of the filtration device of the above filtration device is set higher than the space velocity SV of the filtration unit of the above filtration device. By increasing the magnification of the space velocity SV of the test device filtration portion 21 of the test device filter 20 with respect to the space velocity SV of the filtration portion of the filter of the above-described filtration device, the filter portion for the test device The variation in the flow velocity in the horizontal plane of the test water passing through 21 can be reduced. In other words, the difference between the flow rate of the test water flowing through the central portion of the cross-sectional area of the first portion 23 and the flow rate of the test water flowing near the peripheral surface of the first portion 23 can be reduced. Further, by reducing the cross-sectional area of the first portion 23, the test water can uniformly pour onto the filter medium 21a.

  For this reason, since the filter part 21 for test devices, ie, the filter medium 21a, can be used efficiently, the amount of the filter medium 21a can be reduced. Since the amount of the filter medium 21a can be reduced, the test device filter 20 can be downsized.

  When a test filter that is downsized while maintaining the linear velocity and space velocity of the filtration unit of the filtration device described above is created, the flow of the test water in the test filter is that of the actual filtration device. Although the flow is the same as that of the filter, it also includes a filter medium that is not actually used, so there is a limit to downsizing.

  However, since the filter for test apparatus 20 can be further downsized by simply using the filter medium 21a rather than simply downsizing the above-described filter apparatus, the test apparatus 10 can be easily transported.

  Further, by connecting a plurality of test device filters 20 in series, a filtration device different from the above-described filtration device can be reproduced. In other words, a plurality of test device filters 20 can be connected in series. FIG. 4 shows, as an example, a side surface of two test device filters 20 connected in series. As shown in FIG. 4, the first valve device 29 of the primary side test apparatus 10 and the third valve device 32 of the secondary side test apparatus 10 are connected by, for example, a pipe member 70.

  When it is determined that the filtration capacity of the test device filter 20 is insufficient, a test can be performed by connecting a plurality of test device filters 20 in series. If it is determined that the filtration capacity of the plurality of test device filters 20 in series is sufficient, it can be determined that the filtration device reproduced by the plurality of test device filters 20 is an appropriate filter device.

  In this way, the test apparatus can be easily transported, and a plurality of filter apparatuses can be tested by connecting a plurality of test apparatus filters 20, so that the filter apparatus can be easily selected.

Moreover, by supplying the test water into the test device filter 20 from the direction intersecting the stacking direction of the filter media 21a as in the present embodiment, the test water is supplied evenly to the filter media 21a. Therefore, the filter medium 21a can be used more effectively. For this reason, the filter 20 for test devices can be further reduced in size. Moreover, in this embodiment, as an example, the filter for test devices whose filtration capability is a little inferior to the filter of the above-mentioned specific filter device. 20 is used. This is for the purpose of enhancing safety when selecting a filtration device. That is, when it is determined that the test apparatus 10 has sufficient processing capacity, the filtering apparatus has more processing capacity, and thus the safety of selecting the filtering apparatus is increased.

  Moreover, since the potential energy of the test water with respect to the test device filtration unit 21 can be used by supplying water from a high position to the test device filtration unit 21, the force required to operate the piston 42 is reduced. be able to.

  Further, since the water feeding device 40 can be manually operated, the test can be performed even in a place where there is no power source.

  Moreover, the filter 20 for test devices can adjust the filtration capacity of the filter part 21 for test devices by using the filter main body 22 for test devices in common, and adjusting the quantity of the filter medium 21a. As described above, the test apparatus 10 can be a test apparatus for a plurality of filtration devices only by adjusting the amount of the filter medium 21a.

  The present invention is not limited to this embodiment. As an example, the water supply device 40 includes a syringe 41 and a piston 42. The operator operates the piston 42. As another example, a device that can automatically operate the piston 42 may be used. Alternatively, a water supply device that can automatically supply test water may be used.

  Table 3 below is a table showing the linear velocity LV and space velocity SV with respect to the treatment flow rate and the treatment iron concentration of a filtration device different from the specific filtration device described above. The filter of the filtration device shown in Table 3 has a cylindrical shape with a height of 12113 mm and an inner diameter of 550 mm, and 150 L (liter) of a filtering material is accommodated therein. The filter part is formed by this filter medium. Table 4 below is a table showing the linear velocity LV and space velocity SV with respect to the treatment flow rate of the filter of the test apparatus for the filtration device shown in Table 3.

  The flow rate of 60 ml / min flowing into the test device filter shown in Table 4 corresponds to 50 l / min flowing into the filter of the filter device shown in Table 3. A flow rate of 90 ml / min flowing into the test device filter shown in Table 4 corresponds to 75 l / min flowing into the filter of the filter device shown in Table 3. The flow rate of 120 ml / min flowing into the test device filter shown in Table 4 corresponds to 100 l / min flowing into the filter of the filter device shown in Table 3.

  FIG. 5 is a graph showing the treated iron concentration with respect to the treated water amount of the filter of the filtration device shown in Table 3 and the test device shown in Table 4.

  As shown in Tables 3 and 4, the linear velocity LV of the filtration unit of the test machine shown in Table 4 is 2.3 times the linear velocity LV of the filtration unit of the filter shown in Table 3, and the test shown in Table 4 The space velocity SV of the filtration part of the machine is five times the space velocity SV of the filter shown in Table 3. In addition, the test filtration apparatus shown in Table 4 is configured to have an equivalent filtration capacity with respect to the filtration apparatus.

  Thus, also in other test machines, the linear velocity LV of the filtration unit of the test machine is made larger than the linear velocity LV of the filtration unit of the filtration device, and the space velocity SV of the filtration unit of the test device is set to the filtration unit of the filtration device. Of the filtration part of the filter of the above-described filtration device is larger than the space velocity SV of the filter unit and the magnification of the linear velocity LV of the filtration unit of the test device filter 20 with respect to the linear velocity LV of the filtration unit of the filtration device. By increasing the magnification of the space velocity SV of the filtration unit of the test machine with respect to the space velocity SV, as shown in FIG. 5, it is possible to reduce the size of the test machine while having a filtration capability equivalent to that of the filtration device.

  The present invention is not limited to the above-described embodiments as they are, and can be embodied by modifying the constituent elements without departing from the scope of the invention in the implementation stage. Various inventions can be formed by appropriately combining a plurality of constituent elements disclosed in the above-described embodiments. For example, you may delete some components from all the components shown by embodiment mentioned above.

  DESCRIPTION OF SYMBOLS 10 ... Test device, 20 ... Test device filter, 21 ... Test device filter, 21a ... Filter material, 22 ... Filter body, 40 ... Water supply device, 41 ... Syringe, 42 ... Piston, 50 ... Supporter, 60 ... Cup.

Claims (4)

A test device for a filtration device having a filtration part,
A filter for a test apparatus that includes a filter section for a test apparatus that filters test water, and a tubular filter apparatus for a test apparatus that accommodates the filter section for the test apparatus;
A water supply device for supplying water to the test device filter;
Comprising
The linear velocity of the filtration unit for the test apparatus is larger than the linear velocity of the filtration unit, the spatial velocity of the filtration unit for the test device is larger than the spatial velocity of the filtration unit, and the spatial velocity of the filtration unit The test apparatus, wherein the magnification of the space velocity of the test device filtration unit is larger than the magnification of the linear velocity of the test device filtration unit with respect to the linear velocity of the filtration unit. The test apparatus according to claim 1, wherein a plurality of the test apparatus filters are configured to be connectable in series. The test apparatus according to claim 1, further comprising an opening through which the test water flows in a peripheral wall of the filter for the test apparatus. The test apparatus according to claim 1, wherein the water supply device includes a syringe and a piston.